United States Office ot
Environmental Protection Radiation Programs December 1987
Agency Washington, B.C. 20460
Radiation
£EPA Low-Level and NARM
Radioactive Wastes
Model Documentation
PRESTO-EPA-BRC
Methodology and Users Manual
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40 CFR Part 193 EPA 520/1-87-027
Environmental Radiation Standards (RAE 8706/1-5)
for Management and Land Disposal
of Low-Level Radioactive Wastes
PRESTO-EPA-BRC: A Low-Level Radioactive Waste Environmental
Transport and Risk Assessment Code
METHODOLOGY AND USERS MANUAL
Developed by
Vern Rogers
Cheng Hung
December 1987
Prepared for
U.S. Environmental Protection Agency
Office of Radiation Programs
Washington, DC 20460
Cheng Hung, Project Officer
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DISCLAIMER
The report was prepared as an account of work sponsored by an agency
of the United States Government. Neither the United States Government nor
any agency thereof, nor any of their employees, contractors, subcontractors,
or their employees, makes any warranty, express or implied, nor assumes any
legal liability or responsibility for any third party's use of the results
of such use of any information, apparatus, product or process disclosed in
this report, nor represents that its use by such third party would not
infringe privately owned rights.
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PREFACE
This PREbTO-EPA-BRC model documentation provides background
"information on the mathematical modeling used to generate the
basic data for the Environmental Impact Statement (EIS) wnich is
used to support EPA's rulemaking for generally applicable
environmental standards for the management and disposal of
low-level radioactive wastes (LLW). This model was used to
assess the cumulative population health effects (including fatal
cancer deaths and serious genetic effects) to the general
population residing in the downstream regional water basin as a
result of the disposal of LLW in an unregulated sanitary
landfill. The model is considered a member of the PRESTO-EPA
family of models. This model is modified from the PRESTO-EPA-POP
model primarily on the addition of the radionuclide transport
pathways in the biosphere including (1) workers' and visitors'
dust exposures, (2) population exposures from incinerator
releases, (3) workers' and visitors' gamma exposure, and (4)
onsite farming. Since the mathematical formulations of the
radionuclide transport pathways in the geo- and biospheres are
basically identical to those used in the PRESTO-EPA-POP model and
the mathematical formulation of organ dosimetries are also
covered in the PRESTO-EPA-POP model documentation, the detailed
PRESTO-EPA-BKC mathematical formulation is discussed only in the
area of Diosphere transports which are added for this moael.
in
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Interested readers should also refer to the PRESTO-EPA-POP model
documentation reports for further details.
Interested persons may apply this model, using appropriate
and applicable input data, for assessing the cumulative
population health effects resulting from the disposal of BRC
wastes using an unregulated sanitary landfill method.
IV
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TABLE OF CONTENTS
Page
LIST OF FIGURES iv
LIST OF TABLES v
EXECUTIVE SUMMARY vi
1 INTRODUCTION 1-1
1.1 Background on LLW Classified as BRC 1-1
1.2 Outline of Documentation and Users Manual 1-3
2 MODEL FOR PRESTO-EPA-BRC 2-1
3 MODIFICATIONS REQUIRED FOR PRESTO-EPA-BRC 3-1
3.1 Dust Exposures 3-1
3.1.1 Worker and Site Visitor Dust Exposure .... 3-2
3.1.2 Population Dust Exposure from Mechanical
Disturbances 3-4
3.1.3 Population Exposures from Incinerator
Releases 3-4
3.1.4 Population Exposure from Natural Resuspension 3-6
3.2 Worker and Site Visitor Gamma Exposure 3-6
3.3 Nuclide Dependent Leach Fractions 3-8
3.4 On-Site Farming 3-9
3.5 Material Balance Adjustments 3-10
4 INPUT TO PRESTO-EPA-BRC 4-1
4.1 Site Specific and Radionuclide Data 4-1
4.2 Namelist Data 4-15
4.3 Data for the Infiltration Subroutine 4-22
4.4 Dosimetric and Health Effects Data 4-22
5 OUTPUT OF PRESTO-EPA-BRC 5-1
5.1 Replication of Input Data 5-1
5.2 Radionuclide Summary Tables 5-1
5.3 INFIL Input/Output 5-2
5.4 Initial Unit Response Calculations 5-3
V
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TABLE OF CONTENTS
(Continued)
Page
5.5 Annual Summaries for Intermediate Simulation Years . 5-3
5.6 Radionuclide Concentration Tables 5-3
5.7 Radionuclide Exposure Rates 5-3
5.8 DARTAB Control Information 5-4
5.9 DARTAB Dose Tables 5-4
5.10 DARTAB Fatal Cancer Risk Tables 5-4
5.11 Radioactivity Released to the Regional Basin and
Health Effects 5-5
6 SAMPLE PROBLEM 6-1
6.1 Problem Definition 6-1
6.2 Results 6-9
6.3 Job Control Language 6-19
REFERENCES R-l
APPENDIX A - PRESTO-EPA-BRC LISTING A-l
APPENDIX B - SAMPLE PROBLEM OUTPUT B-l
VI
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LIST OF FIGURES
Figure No. Pa9e
6-1 PRESTO-EPA-BRC JCL 6-20
Vll
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LIST OF TABLES
Table No. Page
1-1 PRESTO-EPA Code Family 1-2
4-1 Description of PRESTO-EPA-BRC Environmental and Nuclide
Input 4-3
4-2 Description of Namelist Input for Subroutine DARTAB . . . 4-16
4-3 Input Data for Subroutine INFIL 4-23
6-1 Surface Soil Data 6-2
6-2 Atmospheric Data 6-3
6-3 Foodchain Parameters 6-5
6-4 Radionuclide Specific Foodchain Data 6-6
6-5 Inventory 6-7
6-6 Radionuclide Specific Data 6-8
6-7 Radionuclide Specific Dose Parameters 6-10
6-8 Organ Weighting Factors 6-11
6-9 INFIL Input Data for the Sample Problem 6-12
6-10 Maximum Day Lengths for Sample Problem 6-13
6-11 Daily Temperatures in Degrees Celsius 6-14
6-12 Hourly Rainfall Read in as Month, Day, Rainfall Per Hour
and Hour and Given in 0.1 mm/hr 6-15
6-13 Summary of Results for Sample Case 6-18
Vlll
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EXECUTIVE SUMMARY
The U.S. Environmental Protection Agency (EPA) is responsible for
developing a generally applicable standard for the land disposal of
low-level radioactive waste (LLW). The standard will support the U.S.
Nuclear Regulatory Commission and the U.S. Department of Energy in develop-
ing a national radioactive waste management system. Technical support for
the standard includes an estimation of the environmental impacts from the
disposal of LLW in a wide variety of facilities ranging from a standard
sanitary landfill to a deep geologic repository.
As an aid in developing the standard, a family of computer codes,
entitled PRESTO-EPA-POP, PRESTO-EPA-DEEP, PRESTO-EPA-CPG, PRESTO-EPA-BRC
and PATHRAE-EPA has been developed under EPA direction. The PRESTO-EPA-POP
code was the first code developed and served as the basis for the other
codes in the PRESTO-EPA family. The EPA uses the PRESTO-EPA code family to
compare the potential health impacts of a broad number of LLW disposal
alternatives to evaluate and support its decisions for the LLW standard.
This report documents the PRESTO-EPA-BRC computer code which estimates
collective population health effects resulting from disposal of LLW which
is "below regulatory concern" (BRC). The PRESTO-EPA-BRC code was
implemented by Rogers and Associates Engineering Corporation from the
earlier PRESTO-EPA-POP Code. The PRESTO-EPA-POP computer code was
developed under EPA direction to estimate possible health effects from
low-level radioactive waste buried in shallow trenches. The PRESTO-EPA-BRC
code considers exposures from BRC waste occurring during the operating
period of the disposal facility as well as the long term exposures resulting
from the disposal of the waste. Both individual and population exposures
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arising from inhalation of radioactive materials introduced into the
atmosphere by mechanical disturbance, incineration and meteorological
effects are considered together with direct gamma exposure from BRC waste.
Exposure events are considered during site operations and post-closure
activities such as on-site farming and residency.
The Environmental Protection Agency wishes to warn potential users
that, like any complex computer code, the PRESTO-EPA codes can be misused.
Misuse could consist of using the code to examine a site where one or more
critical modeling assumptions are invalid, or where values for significant
input parameters are chosen that do not accurately reflect variables such
as radionuclide inventory, site meteorology, surface and subsurface
hydrology and geology-, and future population demographics. Certain release
and transport scenarios, such as major changes in meteorology or mining of
the trench contents, are not considered in the PRESTO-EPA-BRC model and
code. Significant changes to the existing code and the input data would be
required to consider such scenarios. The PRESTO-EPA codes were developed
to assess and compare alternative methods for managing and disposing of
LLW at generic sites for general scenarios. The codes were not developed
to analyze specific sites.
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1. INTRODUCTION
1.1 BACKGROUND ON LLU CLASSIFIED AS BRC
The U.S. Environmental Protection Agency (EPA) is developing a
comprehensive environmental protection standard for the disposal of
low-level radioactive waste (LLW) and wastes which are "below regulatory
concern" (BRC). The EPA has evaluated LLW radiation exposures and risks to
the general population and to critical population groups using the
PRESTO-EPA family codes (EPA87a through EPA87g). These codes and
documents provide the technical support for the development of the
standard.
Table 1-1 provides a brief description of each of the EPA codes.
These codes, and how the EPA uses them, have been described in detail
(Hu83, Ga84). Information on obtaining complete documentation and users'
manuals for the PRESTO-EPA family of codes (EPA87a through EPA879) is
available from the EPA.
The evaluation of population exposures and risks from disposed BRC
waste considers exposures occuring during the operating period of the
disposal facility as well as offsite exposures to populations following
site closure. For example, workers at a sanitary landfill (SLF) are not
radiation workers; hence, worker doses must be considered in evaluating
general population annual dose commitments. In addition, the general
public has access to many facilities appropriate for BRC waste disposal.
Since the original PRESTO-EPA family of computer codes for assessing
population dose commitments and risks did not consider exposure mechanisms
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TABLE 1-1
PRESTO-EPA CODE FAMILY
PRESTO-EPA Code
Purpose
PRESTO-EPA-POP
PRESTO-EPA-DEEP
PRESTO-EPA-CPG
PRESTO-EPA-BRC
PATHRAE-EPA
Estimates cumulative population health effects to local
and regional basin populations from land disposal of LLW
by shallow methods; long-term analyses are modeled
(generally 10,000 years).
Estimates cumulative population health effects to local
and regional basin populations from land disposal of LLW
by deep methods.
Estimates maximum annual whole-body dose to a critical
population group from land disposal of LLW by shallow or
deep methods; dose in maximum year is determined.
Estimates cumulative population health effects to local
and regional basin populations from less restrictive
disposal of BRC wastes by sanitary landfill and
incineration methods.
Estimates annual whole-body doses to a critical
population group from less restrictive disposal of BRC
wastes by sanitary landfill and incineration methods.
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associated with BRC disposal, it was necessary to develop and document new
computer programs to accomplish this function.
Under EPA direction, Rogers and Associates Engineering Corporation has
modified the PRESTO-EPA-POP code by modifying exposure pathways. The
resulting computer code, PRESTO-EPA-BRC, described in this document, more
accurately assesses the cumulative population exposures which could result
from unregulated disposal of BRC waste. Radiation exposure rates to which
the critical population group might be exposed are evaluated by the
PATHRAE-EPA code (EPA87f).
1.2 OUTLINE OF DOCUMENTATION AND USERS MANUAL
The purposes of this Users Manual are to describe the modifications
made to PRESTO-EPA-POP in producing the PRESTO-EPA-BRC code given in
Chapter 2, to explain the usage of the code in Chapter 3, and to document a
typical sample run in Chapter 4. A source listing of the PRESTO-EPA-BRC
code is given in Appendix A and a complete output from the sample run is
presented in Appendix B.
The complete results of the BRC analyses are presented in the
Background Information Document and Economic Impact Analysis supporting
the development of EPA's generally applicable standards for the land
disposal of LLW (EPA87h, EPA87i).
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2. MODEL FOR PRESTO-EPA-BRC
The computer code PRESTO-EPA-BRC is a modification of the PRESTO-EPA-
POP code prepared to calculate collective population health effects
resulting from disposal of radioactive waste which is "below regulatory
concern" (BRC). Details of the PRESTO-EPA model development and methodology
are given in appropriate EPA documents (EPA87a). A major purpose of this
document is to indicate how the original PRESTO-EPA model and code were
modified to assess the radiation doses and risks associated with the less
restrictive disposal of BRC wastes.
The major modifications to PRESTO-EPA-POP made in generating
PRESTO-EPA-BRC involve adding the ability to calculate and accumulate
exposures during the disposal facility operations. Since PRESTO-EPA-POP is
oriented to post-closure events, all operations impacts are evaluated in
the first year of the simulation and are accumulated in existing code
variables for input to the DARTAB subroutines.
Modifications incorporated into PRESTO-EPA-BRC include:
• Worker and site visitor dust inhalation during operations.
• Population dust inhalation from mechanical disturbances
during operations.
t Population inhalation of incinerator releases during ope rat ions.
t Worker and site visitor gamma exposure during operations.
• Nuclide-dependent leach fractions.
• Changes in the method for considering the on-site farming
option.
0 Adjustments to material balance calculations.
These modifications are discussed in detail in Chapter 3.
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3. MODIFICATIONS REQUIRED FOR PRESTO-EPA-BRC
This chapter details the modifications that were required to adapt the
PRESTO-EPA-POP methodology and the computer code for the assessment of BRC
wastes.
3.1 DUST EXPOSURES
When calculating exposures to non-radiation workers at typical municipal
waste disposal facilities, such as sanitary landfills and municipal dumps,
it is necessary to consider the disposal facility workers and members of
the general public who visit the facility as non-radiation workers.
Members of the general public who frequent the facility include those who
themselves dispose of waste and refuse at the facility and unauthorized
persons who are potential scavengers. Both workers and visitors to the
site will be exposed to varying levels of atmospheric dust and direct gamma
radiation, depending on their particular location (characterized by
relative levels of dust and gamma radiation) and time spent at each
location. Account is made of these factors in determining dust exposures.
Dust exposures to the population occur through four mechanisms: worker
and site visitor dust exposure during operations, population dust exposure
from mechanical disturbances during operations, population exposure from
incineration releases during operations, and population exposure from
natural resuspension. These exposure mechanisms are described below.
3-1
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3.1.1 Worker and Site Visitor Dust Exposure
Worker and site visitor dust exposures are assumed to be constant from
year to year during operations. Thus, the cumulative dust exposure over
the operational life of the facility can be determined by multiplying the
annual exposure rate by the operational life of the facility. In
PRESTO-EPA-BRC this cumulative exposure is calculated and added to other
exposures not related to operations in the first year after operations,
which is the first year of the code simulation.
The effective atmospheric concentration for worker and site visitor
dust exposure over the period of operations is calculated by the expression
YS02 - 0.001 D1R RR FTMECH FACTIM POPDST/POP (3-1)
where
D1R = the waste concentration in the trench (Ci/kg)
FTMECH = the fraction of time that site operations are active
RR = the average dust loading to which workers or visitors
are exposed on site (g/m^)
FACTIM = the operating life of the facility (yr)
POP = the total population of the simulation (persons)
POPDST = the average worker and site visitor population (persons)
The factor 0.001 accounts for units conversions (10~3 kg per gram). The
factors 0.001, D1R, and RR represent the average concentration to which
workers and visitors are exposed during the time they spend on site.
Multiplication by FACTIM effectively integrates the annual dust exposure
rates during operations as noted above.
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The ratio POPDST/POP anticipates the fact that all cumulative effective
individual exposures are multiplied by POP (the total population of the
simulation) later in the code to determine the collective population
exposures. When that multiplication occurs, the factor POP properly cancels
from this contribution to the collective population exposure. Thus, the
variable YS02 represents the cumulative collective air concentration for
workers and site visitors.
If worker breathing rates are different from that of the population
at large, proper account can be made of the difference if the user adjusts
FTMECH by multiplying by the ratio of the worker breathing rate to the
general population breathing rate.
The variable POPDST is equal to the number of equivalent full-time,
full -exposure (dust) workers. Its magnitude is determined by the user
outside of PRESTO-EPA-BRC using the relative dust loadings for each worker
population by the expression:
POPDST = ]T WPi fD1 fti (3-2)
where
WP-j = the worker and site visitor population at the ith
location (person)
= the fraction of maximum dust concentration at the ith
location (g/m^)
f^i = the fraction of a 40 hr work week spent by WPi at the
ith location
n = the number of locations considered
The worker and site visitor collective nuclide concentration in air is then
added to ATCON(I), the nuclide-specific total collective air concentrations
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accumulated over population and time. The array ATCON(I) after appropriate
preparation is passed to the DARTAB subroutine for calculations of
collective doses and risks resulting from exposure to contaminated air.
3.1.2 Population Dust Exposure from Mechanical Disturbances
The effective atmospheric concentration for population dust exposure
resulting from mechanical disturburances during operations is calculated
during the first year of the simulation by the expression:
YS02A = D1R FACTIM RMECH EXPOS FTWIND (3-3)
where the product of EXPOS and FTWIND is the Gaussian plume atmospheric
concentration per unit source strength. It effectively accomplishes the
transport and dispersion of contaminants from the point of disturbance
(ground level) to the exposed population, in a manner identical to that of
PRESTO-EPA-POP. The variables EXPOS and FTWIND are input to PRESTO-EPA-BRC.
The variable RMECH is the rate of dust suspension from mechanical disturb-
ances (kg/sec) and other variables are as earlier defined.
The population dust exposure resulting from operations is added to
ATCON(I) in a manner identical to that described above for workers and
visitor dust exposures.
3.1.3 Population Exposures from Incinerator Releases
The effective atmospheric concentration for population exposure
resulting from incinerator releases during operations is calculated in the
first year of the simulation according to the relation:
YS02B = D1R FACTIM RINC CHIQ2 FTWIND2 FVOLAT(I) (3-4)
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where
RING = the incineration rate (kg/sec)
FVOLAT(I) = the nuclide-specific volatility factor
The product of CHIQ2 and FTWND2 is the Gaussian plume atmospheric concentra-
tion per unit source strength. It effectively accomplishes the transport
and dispersion of the contaminant from the elevated incinerator stack to
the exposed population, which is input to PRESTO-BRC. The variable CHIQ2
includes the effects of both buoyancy and momentum in accounting for plume
rise. Other variables are as earlier defined.
The variable RING is essentially a flag available to the user to acti-
vate or disallow onsite incineration. If the user inputs a non-positive
value of RING, then no incineration is allowed. If the user, however,
specifies a positive value for RING, the PRESTO-EPA-BRC code calculates the
correct value for the incineration rate. All waste is assumed to be
incinerated and the annual incineration rate is found from the expression:
RING = (3.17E-5) TAREA (TDEPTH-OVER) DENCON/FACTIM (3-5)
where
TAREA = the total trench area (m2)
TDEPTH = the total trench depth (m)
OVER = the depth of cover material over waste (m)
DENCON = the density of the waste, (g/cm3)
The number 3.17E-5 adjusts the product to maintain consistent units. The
numerator in Equation (3-5) represents the total waste incinerated over the
operational life of the facility. Division by FACTIM makes RING equal to
3-5
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the annual incineration rate, assumed to be constant over the operating
life of the facility.
3.1.4 Population Exposure from Natural Resuspension
The population exposure resulting from natural resuspension is
calculated during operations in an identical manner as contained in
PRESTO-EPA-POP after operations. As with other dust exposures during
operations, this exposure is accumulated over the operational life of the
facility and added to ATCON(I) in the first year of the simulation. Trans-
port and dispersion from the site is effectively accomplished when the
calculated release rate from the site is multiplied by EXPOS and FTWIND
(similar to the treatment described above for mechanical disturbances).
3.2 WORKER AND SITE VISITOR GAMMA EXPOSURE
As noted earlier, disposal facility workers and site visitors must be
considered non-radiation workers in determining the risks resulting from
BRC disposal of any LLW. In calculating exposures resulting from direct
gamma radiation, the maximum expected gamma radiation level is used as a
basis for calculating gamma doses to workers and visitors in PRESTO-EPA-BRC.
In the implementation, the gamma radiation levels are expressed as a
fraction of the maximum expected gamma radiation level to which workers or
visitors would be exposed during the time they spend on site. Depending on
their relative locations, the workers and visitors are exposed to gamma
radiation which is proportional to that fraction. The equivalent fulltime,
full-exposure population is used to represent population exposure to
workers and visitors from gamma radiation.
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The cumulative worker and site visitor gamma exposure is calculated
in the first year of the simulation in a manner similar to that described
for PRESTO-EPA-POP (EPA85a). This methodology calculates gamma exposures
to an individual standing on a contaminated infinite plane. In the first
year of a PRESTO-EPA-BRC simulation, however, a departure from the
PRESTO-EPA-POP methodology accounts for exposures to the workers and site
visitors. This occurs by modifying the parameter FGAM in PRESTO-EPA-POP by
factors to account for the population being exposed during operations, the
cumulative effect over the operating period and the fact that the nuclides
have not decayed during each year of exposure. The modified FGAM is
denoted by FGIM.
In the first year of the PRESTO-EPA-BRC simulation FGIM is defined by
the equation:
FGIM = FGAM FACTIM POPG/DECOP(I) (3-6)
where
POPG = equivalent, full-time, full-exposure (gamma) population
DECOP(I) = an adjustment to the inventory to account for constant
delivery rate and decay during operations (discussed in
Section 3.5).
The variable POPG is calculated as follows by the user outside PRESTO-EPA-BRC
and provided as input:
N
POPG = £ WPi fGi ftl- (3-7)
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where
WP-j = the worker and site visitor population at the ith location
fgj = the fraction of the maximum exposure rate at the ith location
fti = the fraction of a 40 hour work week spent by WP-j at the
ith location
N = the number of locations considered
In PRESTO-EPA-BRC the coefficient FGIM replaces the 'coefficient FGAM
(in PRESTO-EPA-POP) to calculate the gamma exposure only for the first year
of the simulation. Thus, in the first year, the accumulated gamma exposure
represents gamma exposures to workers and site visitors. In subsequent
years, the gamma exposure is calculated as in PRESTO-EPA-POP, with the
coefficient FGAM being used. Thus, subsequent additions to the accumulated
gamma exposure represents exposure of a single individual for one year to
radioactive concentrations accumulated on the ground surface.
3.3 NUCLIDE DEPENDENT LEACH FRACTIONS
The uncertainties associated with the leaching properties of the BRC
waste in either a sanitary landfill on a municipal dump makes nuclide-
dependent leaching very desirable. PRESTO-EPA-POP only accommodates nuclide
dependence in the equilibrium and solubility leach options (LEAOPT = 1, 2,
3, or 4). A single waste-form dependent leach fraction is used for all
nuclides in the case of the leach fraction option (LEAOPT = 5). PRESTO-EPA-
BRC modifications allow the use of nuclide dependent leach fractions input
and stored in the XKD(2,I) array. These array elements, which normally
contain the nuclide specific waste form distribution coefficients, are
interpreted as release fractions when a release factor, RELFAC, less than
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zero is input. For RELFAC values equal to or greater than zero the
original interpretation and usage hold.
3.4 ON-SITE FARMING
PRESTO-EPA-BRC also allows population dust exposures from post-closure
activities such as on-site farming. In order to calculate non-zero
population exposures resulting from dust inhalation due to on-site farming
operations, the following three conditions must be met concurrently:
• It is not the first year after operations (first year of the
simulation).
• The current time in the simulation is greater than or equal
to IRRES1 (first year of mechanical resuspension) but less
than or equal to IRRES2 (last year of mechanical
resuspension).
• The input value for dust concentration on-site (RR) must be
less than zero.
Only when these conditions are simultaneously satisfied are the atmospheric
concentrations (YS02C) of nuclides from post-closure mechanical disturbance
represented by the expression:
YS02C = CS(I) RMECH FTMECH EXPOS FTWIND (3-8)
where
CS(I) = the surface concentration of the nuclide I, Ci/kg
RMECH = the rate of dust suspension by mechanical activities,
kg/sec
FTMECH = the fraction of a year during which on-site operations
are conducted
Under all other circumstances exposures resulting from on-site farming
equal zero by definition.
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PRESTO-EPA-BRC will calculate exposures resulting from consumptions of
vegetation grown on-site and from natural biointrusion in a manner identical
to that described in PRESTO-EPA-CPG (EPA85d).
3.5 MATERIAL BALANCE ADJUSTMENTS
The nuclide losses during operations can greatly influence the
available inventory the first year after closure. Appropriate corrections
identical to those used in PRESTO-EPA-CPG are made to the inventory through
the expressions:
(3-9)
DECOP(I) = ((EXP(DECAY(I)) - 1.0)/DECAY(I)) (1.- EXP(-DECAY(I) FACTIM) /
(DECAY(I) FACTIM)
where
DECAY(I) = the decay constant of nuclide I (yr-1)
The factor (EXP(DECAY(I))-1.0)/DECAY(I) accounts for radioactive decay
during the first (and subsequent) year(s) after operations cease. The
remaining expression accounts for both a constant delivery rate of waste
and radioactive decay during operations.
Multiplication of the nuclide inventory by DECOP(I) converts the total
inventory delivered to the site to the average inventory remaining in the
site over the first year following the conclusion of operations.
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4. INPUT TO PRESTO-EPA-BRC
There are four sets of input data for PRESTO-EPA-BRC analysis. They
are: (1) site specific and radionuclide data used to calculate nuclide
concentrations by the environmental transport section of the code, (2) name-
list format data for DARTAB calculations of tabular output, (3) hydrogeologic
and meteorologic data for subroutine INFIL, and (4) dosimetric and health
effects data used by the DARTAB submodel. Preparation of the first three
data sets will be explained in the following sections. The fourth data set
was created by the program RADRISK (Du80). This data file contains
reference dosimetric information and is not usually modified for a specific
run. The RADRISK reference (Du80) should be consulted for information on
changing the data in this file.
These four input data sets are grouped into three separate disk files,
each assigned a unique FORTRAN input unit number. The data sets are
organized as follows:
t Data sets (1) and (2) form one file with input unit 5.
• Data set (3) is assigned input unit 4.
• Data set (4) is assigned to unit 25.
4.1 SITE SPECIFIC AND RADIONUCLIDE DATA
These data are used in the transport section of PRESTO-EPA-BRC. The
data describe physical and hydrogeological characteristics of the facility
and site, meteorological data for atmospheric dispersion and deposition,
data for the biological pathways and the radionuclide characteristics and
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inventories. This data set also contains disposal technology and exposure
scenario data, allowing for detailed site and exposure scenario descriptions.
It is read in standard FORTRAN formatted style by subroutine SOURCE.
Table 4-1 presents a description of the input variables, format and card
sequence for this data set.
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TABLE 4-1
DESCRIPTION OF PRESTO-EPA-BRC ENVIRONMENTAL AND NUCLIDE INPUT
Card Variable (Input Format)
Description
CARD 1 Run Identification (20A4)
TITLE
- Identifies the run. Up to 80 characters
are allowed.
CARD 2 Location and Site Description (20A4)
LOCATE
- Location of the disposal site. Up to 80
characters are allowed.
CARD 3 Time, Nuclides, and Farming Control Parameters (1615)
MAXYR
NONCLD
LEAOPT
NYR1, NYR2
IOPVWV
IOPSAT
- The number of years for which the simula-
tion will run.
- The number of radionuclides which are used
in the simulation. Must be 40 or less.
- The leaching option. Radionuclides will be
removed from trench in different manners
depending on the value of LEAOPT. Must be
one of the following calculation methods.
(Option -1 through 5.)
Option Leach Calculation Method
1 Total contact, distribution coeffi-
cient
2 Immersed fracton, distribution co-
efficient
3 Total contact, solubility
4 Immersed fraction, solubility
5 Release fraction (may be nuclide
dependent
- Beginning and ending years of trench cap
failure. Both values must be less than or
equal to MAXYR. NYR2 must be greater than
or equal to NYR1.
- Option for direct farming in the waste.
=-1 no on-site farming
= 0 on-site farming
- Not used.
4-3
-------�
TABLE 4-1
(Continued)
Card Variable (Input Format)
Description
IPRT1, IPRT2,
IDELT
IRRES1, IRRES2
LIND
- Control parameters. An annual summary
table will be produced for each year that
is a multiple of IDELT and falls between
the range of IPRT1 and IPRT2.
- Beginning and ending year for the mechani-
cal suspension of contaminated soil into
atmosphere. Used in the farming scenario.
- Option parameter passed to DARTAB to cal-
culate health effects. If LIND = 0 then
DARTAB computes concentrations and rates
for maximally exposed individuals. If
LIND = 1 then general population concen-
trations are computed.
IAVG1, IAVG2
- Beginning and ending years for
nuclide concentration values.
averaging
CARD 4 External Exposures and Time Duration Parameters (515)
IVAP
IBSMT
IAQSTF
IXTS
- Set IVAP = 1 to determine external gamma
exposure to workers and scavengers during
operations period. Otherwise, set IVAP = 0.
- The beginning year for the basement correc-
tion factor for surface gamma exposure
calculations made by DARTAB. If IBSMT = 0
correction factor is calculated beginning
in that year. If IBSMT = -1 then no
correction is calculated.
- Control parameter for aquifer to stream
flow. A blank field defaults to calcula-
tions under the assumption that the flow
takes place, otherwise the field should
contain a nonzero integer.
- Control parameter to extend global assess-
ment for an additional 9000 years beyond
the local impact analysis period (MAXYR).
A blank field defaults to the extended
analysis. A nonzero integer stops the
global impact simulation at the end of the
local assessment period.
4-4
-------�
TABLE 4-1
(Continued)
Card Variable (Input Format)
Description
IRST
INTYR(I),
1=1,3
- Number of years of restricted site use
after site closure.
- Intermediate years in the local simulation
period for which dose and risk output is
desired. Up to three times allowed.
CARD 5 Water Infiltration and Use (8F10.0)
PCT1, PCT2
WWATL
WWATA
WWATH
SWATL
SWATA
SWATH
- The fraction of the waste cap that is
assumed to fail by some artificial means
between the years NYR1 and NYR2. Failure
of the cap constitutes total removal of all
cap, of OVER Thickness, for PCT1 of the
trench area in NYR1 and for PCT2 of the
trench area in NYR2. Between NYR1 and NYR2
a linear interpolation between pairs (NYR1,
PCT1 and NYR2) calculates the amount of the
trench area that is totally bare. Even if
PCT1 and PCT2 are set at zero, the trench
cap may ultimately fail through erosion;
see function CAP and subroutine ERORF.
- Fraction of irrigation water supplied by
contaminated water from well (1.0 if all
water comes from well, 0.0 if none).
- Fraction of animal drinking water supplied
by contaminated water from well (1.0 if all
water comes from well, 0.0 if none).
- Fraction of human drinking water supplied
by contaminated water from well (1.0 if all
water comes from well, 0.0 if none).
- Fraction of irrigation water supplied by
contaminated water from stream (1.0 if all
water comes from stream, 0.0 if none).
- Fraction of animal drinking water supplied
by contaminated water from stream (1.0 is
all water comes from stream, 0.0 if none).
- Fraction of human drinking water supplied
by contaminated water from stream (1.0 if
all water comes from stream, 0.0 if none).
4-5
-------�
TABLE 4-1
(Continued)
Card
CARDS
6-12
Variable (Input Format) Description
Comments and References (20A4)
- These cards are available for comments and
references pertaining to data set. Up to
80 characters allowed in each of six cards.
CARD 13 LLW Site Characteristics (9F10.0)
TAREA
TDEPTH
OVER
PORT
DENCON
- The total combined radioactive waste surface
area for the facility being simulated (m^).
Must be nonzero.
- Nominal depth (m) of operating trench in
the shallow disposal scenario. Includes
cover thickness.
- Thickness of trench overburden (m).
must be equal to YGMAX of INFIL.
This
RELFAC
CPRJ
SINFL
- Porosity of material within trench. Must
be nonzero.
- Mean density of the waste materials in the
trench (g/crrr). For incineration must be
the average density of the ash and residue
placed in the trench.
- The annual release fraction of the total
trench inventory of each radionuclide if
LEAOPT = 5. For radionucl ide-specific
release rates enter RELFAC = -1.
- Complement to one for the fraction of
underground water flowing to the stream
(0.0 means 100 percent to the regional
basin river).
- Annual infiltration rate for the noncap
portions of the site and for local farm-
land (m/yr).
CARD 14 Groundwater Saturation (2F10.0)
SSAT
RESAT
- Fraction of water saturation in the ground
formation beneath the buried waste. If
SSAT = 0 or if left blank, the fraction of
saturation is calculated internally by the
code.
- Fraction of residual saturation.
4-6
-------�
TABLE 4-1
(Continued)
Card Variable (Input Format) Description
CARD 15 Site Operations and Haste Containers (6F10.0)
PERMT - Trench permeability (m/yr).
FACTIM - Number of years of active operation of the
waste site.
TMN - Number of years of active maintenance after
site closure. No nuclide migration is
initiated during the maintenance period,
although radioactive decay takes place.
CFT1 - Number of years before waste containers
begin failing.
DCFT - Number of years after CFT1 that containers
fail completely. At time CFT1+DCFT all
containers have failed.
FGAM - Dimensionless factor characterizing the
intensity and duration of gamma exposure
from the basement scenario.
CARD 16 Transport Parameters (2F5.0, 7F10.0)
DTRAQ - The distance from the bottom of the trench
to the nominal depth of the aquifer. DTRAQ
+ TDEPTH should equal the aquifer depth
below the surface (m).
DWS - Distance between the well and stream for
basin effects calculations (m).
DWELL - Distance from the trench to the well used
for irrigation and drinking. Must be
nonzero (m).
GWV - Velocity of the groundwater in the aquifer.
Must be nonzero (m/yr).
AQTHK - Thickness of the aquifer at the location of
the well (m). This is used to calculate
the volume of water in which the available
radionucl ides are diluted. Must be nonzero.
AQDISP - Dispersion angle of the pol lutant plume in the
aquifer (radians). Used with AQTHK to calcu-
late dilution volume. Must be in radians.
4-7
-------�
TABLE 4-1
(Continued)
Card Variable (Input Format) Description
PORA - Aquifer porosity.
PORV - Sub-trench porosity.
PERMV - Sub-trench permeability (m/yr).
CARD 17 Atmospheric Parameters (7F10.0)
H - Atmospheric source height of radionuclides
(m). One meter is chosen because most re-
suspension rate measurements are expressed
for that height.
VG - Settling velocity of contaminated soil
particles due to gravity (m/s).
U - Annual average wind speed (m/s) in the di-
rection of interest. For population calcul-
ations this is the wind speed toward the
population centroid. Must be nonzero.
VD - Deposition velocity (m/s). Nominal generic
value is 0.01 m/s.
XG - Distance (m) from source (trench) to
population or individual of interest. If
XG is less than PD, the adjacent farming
option will be triggered.
HLID - Height of the inversion layer or lid (m).
ROUGH - Hosker's roughness parameter (m).
CARD 18 Atmospheric Parameters (7F10.0)
FTWIND - Fraction of the time the wind blows toward
the population or individual of interest.
CHIQ - The user-specified atmospheric dispersion
parameter for the population of interest
which may be calculated by an external
atmospheric dispersion code (s/m^). A
nonzero value will override any calculation
of atmospheric dispersion performed within
code.
RE1, RE2, RES - Factors (including algebraic signs) used in
the resuspension rate equation.
4-8
-------�
TABLE 4-1
(Continued)
Card Variable (Input Format)
Description
RR
FTMECH
- Has one of two usages:
RR<0: enables dust exposure to onsite farmer.
Onsite farmer dust exposure calculation uses
RMECH rather than RR. The absolute value of
RR is used to calculate worker and site visi-
tor dust exposures during operations (g/nr).
- Fraction of a year when operations are active.
Used in conjunction with RR and RMECH.
CARD 19 Exposure Factors (6F10.0)
FTWIND2
CHIQ2
RMECH
RINC
POPG
POPDST
- Fraction of the time wind blows toward the
population of interest when incineration is
considered.
- Downwind atmospheric concentration per unit
release rate for the population of interest
when incineration is considered (s/nr).
Dust resuspension
tions (kg/s).
rate for onsite opera-
Total waste incineration rate (kg/s). A
non-positive entry suppresses the incinera-
tion calculation.
Number of equi valent ful 1 -time, ful 1 -exposure
onsite workers and site visitors exposed to
gamma.
Number of equivalent ful 1 -time, ful 1 -exposure
onsite workers and site visitors exposed to
dust.
CARD 20 Atmospheric Stability (215)
IT
IS
- Indicator variable for the type of atmos-
pheric stability class formation. Suggested
formation is Pasquill-Gifford, IT = 1.
- Stability category indicator. Values of
1 to 6 correspond to stability categories
of A-F. A single value represents the most
common stability category from nearest
meteorology station to site of interest.
4-9
-------�
TABLE 4-1
(Continued)
Card Variable (Input Format) Description
CARD 21 Precipitation Parameters (6F10.0)
RAINF - The rainfall factor (R/yr).
ERODF - The soil-erodibi1ity factor has units of
tons/acre-R, where R = RAINF given above.
STPLNG - The slope steepness-length factor.
COVER - The crop management factor.
CONTRL - The erosion control practices factor.
SEDELR - The sediment delivery ratio. This ratio is
intended to apply to fouling of waterways
from construction activity.
CARD 22 Soil and Surface Water (5F10.0)
PORS - Porosity of the surface soil. Must be
nonzero.
BDENS - Bulk density of the soil (g/cm3). Must be
nonzero.
STFLOW - Annual flow rate of the nearest stream
(m3/yr). Must be nonzero.
EXTENT - The cross slope extent of the surface
region contaminated by operational spillage
(m). Must be nonzero.
ADEPTH - The active depth of soil in the surface-
contaminated region. Used for the calcula-
tion of radionuclide concentration in both
surface soil and surface water. Must be
nonzero.
CARD 23 Surface Hater Runoff (2F10.0)
PD - Distance from the trench to nearest stream
(m). Must be nonzero. If PD is greater
than XG, the adjacent farming option will
be triggered.
RUNOFF - Fraction of the annual precipitation that
runs off.
4-10
-------�
TABLE 4-1
(Continued)
Card Variable (Input Format) Description
CARD 24 Agricultural Data (7F10.0)
Yl, Y2 - Agricultural productivity for pasture grass
and other consumed vegetation respectively
(kg/m2).
PP - Surface density of soil (kg/m2). Assumes a
15 cm plow depth. For farming scenario,
this value should be in agreement with the
value of BDENS, CARD 20. Must be nonzero.
XAMBWE - The weathering removal decay constant for
atmospheric deposition onto foodcrops
(hr-1).
TA - Not used.
TE1, TE2 - Period of time that pasture grass or crops
and leafy vegetables, respectively, are
exposed to contaminated air during each
growing season (hr).
CARD 25 Agricultural Delay Times and Fractions (8F10.0)
TH1 - TH6 - These six variables represent the delay
time between harvest and consumption by
animal or man of pasture grass, stored
feed, leafy vegetables for maximum
individual doses, produce for maximum
individual doses; and leafy vegetables and
produce for general population exposures,
respectively (hr).
FP - Fraction of each year that animals graze on
pasture grass.
FS - Fraction of an animal's daily feed that is
fresh grass for the period of time animals
are in pasture.
CARD 26 Animal Feed Data (7F10.0)
QFC - The amount of feed consumed daily by cattle
(kg).
QFG - The amount of feed consumed daily by dairy
goats (kg).
4-11
-------�
TABLE 4-1
(Conti nued)
Card Variable (Input Format) _ Description __
TF1, TF2 - The transport time (hr) from animal feed
into milk and into the receptor human for
the maximum individual and the general
population exposures, respectively.
TS - Length of time between slaughter of animals
and human consumption of the resultant meat
(hr).
ABSH - The absolute humidity of the atmosphere
(g/m3). Used for specific activity food-
chain calculations for tritium concentra-
tions in foodstuffs. Must be nonzero.
P14 - The fractional equilibrium ration for C-14.
CARD 27 Plant Root Parameters (2F10.0)
XRTM - Maximum root depth for on-site farming
scenario (m).
RTGR - Root growth rate constant
CARD 28 Irrigation Water Data (6F10.0)
TW - Not used.
FI - Fraction of the year that crops are irrigated.
WIRATE - Irrigation rate (L/m2-hr). Application time
is set equivalent to the number of frost-
free days for the area.
QCW, QGW, QBW - Values for the amount of water (L/d) con-
sumed by milk cows, milk goats, and beef
cattle, respectively.
CARD 29 Human Food Uptake (8F10.0)
ULEAFY - The human uptake of leafy vegetables (kg/yr).
UPROD - The human uptake of produce (kg/yr).
UCMILK - The human uptake of cow milk (L/yr).
UGMILK - The human uptake of goat milk (L/yr).
UMEAT - The human uptake of meat (kg/yr).
4-12
-------�
TABLE 4-1
(Continued)
Card Variable (Input Format)
Description
UWAT
UAIR
POP
- The human uptake of drinking water (L/yr).
- The inhalation rate (m-^/yr).
- Local Population.
CARD SET Repeat this set of three cards for each nuclidel
30, 31, 32+
CARD 30 Nuclide Specific Data (A8, Tl, 8A1, 2X, 7F10.0)
NUCLID(I) - The name of the radionuclide used in the
code. Must be left justified and with no
embedded blanks and with a hyphen separating
the alphameric for the element and the
numeric for the isotope. The names used
must agree with the conventions used in
RADRISK and DARTAB.
NUCL(I,K), K=l,8 - Do not enter data for these variables as
the data are read from NUCLID(I) - (see
format statement).
TRAM(I)
SOAM(I)
STAM(I)
ATAM(I)
DECAY(I)
SOL(I)
The amount of each radionuclide found in the
trench at the beginning of the simulation
(Ci).
The amount of spillage onto the surface
that exists at the beginning of the
simulation (fraction of initial
inventory).
The amount of radioactivity placed into the
stream nearest the site at the beginning of
the simulation (Ci).
The amount of radioactivity of each radio-
nuclide placed into the air directly above
the trench at the beginning of the simula-
tion (Ci).
The radiological decay constant (yr'1). The
constant is equal to 0.6931 divided by the
radiological half-life in years.
The solubility of the radionuclide stored
in the trench (mg/1). SOL is used only if
LEAOPT = 5.
4-13
-------�
TABLE 4-1
(Continued)
Card Variable (Input Format) Description
CON(I) - Conversion factor for global health effects
(health effects/Ci released).
CARD 31 Nuclide Transport Parameters (A8, 2X, 5F10.0)
NU - Radionuclide name (same as on Card 30).
XKD(1,I) - Surface Kd of radionuclide I (ml/g).
XKD(2,I) - Waste Kd of radionuclide I (ml/g). If
RELFAC = -1, this is the nuclide release
fraction.
XKD(3,I) - Vertical zone Kd of radionuclide I (ml/g).
XKD(4,I) - Aquifer Kd of radionuclide I (ml/g).
FVOLAT(I) - Volatility factor for incineration.
CARD 32 Agricultural Data for Nuclides (A8, 2X, 7F10.0)
NC - Radionuclide name (same as Card 30).
RA(I) - Radionuclide retention fraction for air.
RW(I) - Radionuclide retention fraction for
irrigation.
BV(I) - Radionuclide soil-to-plant uptake factor
for vegetative parts.
BR(I) - Radionuclide soil-to-plant uptake factor
for grain.
FMC(I) - Radionuclide forage-to-milk transfer factor
for cows.
FMG(I) - Radionuclide forage-to-milk transfer factor
for goats.
FF(I) - Radionuclide forage-to-beef transfer factor.
4-14
-------�
4.2 NAMELIST DATA
This DARTAB input provides the user options for processing the
exposure data, dosimetric data, and tabulations of output. The first data
card is a title card. The remaining data are read using the FORTRAN
NAMELIST format. The data must be in special format in order to be read
with NAMELIST. The data are grouped in NAMELIST groups. The first
character in each data record to be read must be a blank and the first
record of each group must have an "&" symbol as its second character
followed by the NAMELIST group name. The name cannot contain embedded
blanks and must be followed by a comma. The data items then follow,
separated by commas.
The order of data items in a NAMELIST group is not important, but
arrays that refer to nuclides should have the constants in the same order
as the data in Table 4-2. The end of a NAMELIST group is designated by &END.
An example of this type of input can be seen in Appendix B. Table 4-2
lists the NAMELIST group names and the variables in each group.
The data described in this section are read from logical unit number 5
and must follow directly after the data described in Table 4-1. Table 4-2
describes the Namelist variables utilized by the subroutine DARTAB.
4-15
-------�
TABLE 4-2
DESCRIPTION OF NAMELIST INPUT FOR SUBROUTINE DARTAB
Namelist
Group
INPUT
Variable
ILOC
JLOC
PLOC
AGEX
ILET
Description
Direction index of the exposure array to
use for individual tables.
Distance index of the exposure array to use
for individual tables.
ILOC, JLOC. These are the directions of
the exposure array that is used to locate
an individual for which a dose or risk table
is printed. AIRDOS-EPA, the code for which
DARTAB was originally written, supplied a
two-dimensional exposure array to DARTAB.
PRESTO-EPA-BRC, however, supplies only a
mean exposure value for each of air con-
centration, ground surface concentration,
collective inhalation rate and collective
ingestion rate, for only one location.
These values are the first entry of the
array; hence, both indices should be
specified as 1.
Percent of
location
individual
total risks to use
for the exposure
tables.
in choosing
array for
This variable is an indirect indicator of
the location. Because PRESTO-EPA-BRC does
not provide a two-dimensional exposure
array to DARTAB, PLOC should be set to 100
or omitted.
Average human life expectancy
(Default value = 70.7565 years).
in years
Array dimensioned to 2. ILET = 1 indicates
combined high and low LET tables. ILET = 2
indicates separate tables. ILET(l) refers
to dose rate tables. ILET(2) refers to
health risk tables.
4-16
-------�
TABLE 4-2
(Continued)
Name!1st
Group
Variable
DTABLE
RTABLE
FTABLE
Description
For LLW disposal site simulations with a
mixture of nuclides set ILET = 1,1 for a com-
bined LET table for both dose and risk
tables. For the intrusion scenario, where
external exposures are of greater impor-
tance the user may wish to set ILET = 2,2.
These parameters indicate which tables are
to be output for dose rates, health risks,
and risk equivalents. Each is dimensioned
by 7 corresponding to table type shown
below.
Type
1-a
2-b
3-c
4-d
5-e
6-f
Column
Organs or
Cancers
Organs or
Cancers
Organs or
Cancers
Nuclides
Organs or
Cancers
Nuclides
Row
Nuclides
Nuclides
Nuclides
Pathways
Pathways
Pathways
Label
Individual
Pathways
External &
Internal
All Pathways
Organs or
Cancers
Nuclides
Summed over
7-g
Organs or
Cancers
Organs or
Cancers
Pathways Summed over
Nuclides
Table output control parameters
0 = no tables of this type
1 = table for selected individual
2 = table for mean individual
3 = table for collective group
4 = all three of the above
4-17
-------�
TABLE 4-2
(Continued)
Namel 1st
Group
Variable
Description
OUTPUT
GSCFAC
ORGAN NORGN
ORGN
TIME
QFACTOR HLET
LLET
CANCER NCANC
CANC
RELABS
GENETIC GENEFF
GEN
NGEN
GRFAC
REPPER
Logical variable which indicates whether
dose factors are output. If .TRUE, then
one page output of dose factors for each
nuclide.
Ground surface correction factor. Accounts
for roughness. '
Number of human organs exposed.
Alphanumeric double precision names of
organs. There are NORGN entries.
Time associated with dose commitment (yr).
There are NORGN entries.
Relative biological effectiveness factor
to use for high-LET dose rates to convert
absorbed dose to dose equivalent (rem).
There are NORGN entries.
Same as HLET but for low-LET dose rates.
There are NORGN entries.
Number of cancers to be considered.
Alphanumeric double precision cancer names.
Flag denoting absolute (=1) or relative (=2)
risk model used for each cancer.
Logical variable indicates output of
genetic effects. If GENEFF = .TRUE, then
genetic effects are output. If GENEFF =
.FALSE, then genetic effects are not output.
Alphanumeric double precision names of the
organs to be considered for genetic effects.
Number of human organs exposed.
Risk conversion factors (genetic effects
per rad per million births). GRFAC(l) cor-
responds to low-LET doses. GRFAC(2) corre-
sponds to high-LET doses. There are NGEN
entries.
Replacement rate for the population.
4-18
-------�
TABLE 4-2
(Continued)
Name!1st
Group
Variable
GLLET
RNUCLD
GNLET
NONCLD
NUCLID
PSIZE
RESP
GIABS
Description
Relative biological effectiveness factor
used for low-LET genetic doses to convert
absorbed dose to dose equivalent (rem).
There are NGEN entries.
Same as GLLET but for high-LET. There are
NGEN entries.
Number of radionucl ides.
This number must be equivalent to the same
variable used in transport portion of code,
Card 3, but always less than or equal to 40.
Alphanumeric double precision radionuclide
names.
Must be written without embedded blanks.
Must be listed here in same order as in
transport section of input, cards 26+.
Each name must be set within apostrophes.
Activity median aerodynamic diameter asso-
ciated with each radionuclide (10~6 m).
There are NONCLD entries.
Respiratory clearance class associated with
each radionuclide. A respiratory clearance
class of either day ('D'), week ('W'), year
('Y'), gas ('*'), or not used (' ') must be
entered for each nuclide in the trench.
There are NONCLD entries. More extensive
lists are given in Sullivan, et al.
(Su81).
GI absorption factors.
The absorption factor for each of the four
segments of the GI tract for each nuclide
must be entered. The DARTAB code expects
a value for each segment (stomach, small
intestine, upper large intestine and lower
large intestine). However, most metabolic
models assume that materials are absorbed
only in the small intestine (Su81).
Therefore, input zero values for all GI
4-19
-------�
TABLE 4-2
(Continued)
Namelist
Group
LOGTAB
Variable
NTLOC
RNLOC
OGLOC
PTLOC
FALOC
HLLOC
ORGANF
LTABLE
NORGB
ORGB
Description
segments except the small intestine.
are four entries for each nuclide.
There
Number of location tables to be output.
Since PRESTO-EPA-POP does not provide a
location array of environmental concentra-
tions to DARTAB, NTLOC must be set to zero.
Radionuclide used for table. SUM results
in the sum of all nuclides, WORKLEVL results
in working level calculations, WLSUM results
in total risk for all nuclides.
Organ or cancer to use for table. SUM
results in sum of all cancers.
Pathway used. This variable specifies the
pathway to use in printing the location
table. Values of 1 to 7 will result in
ingestion, inhalation, air immersion,
ground surface exposures, internal expo-
sures (sum of ingestion and inhalation),
external exposures (sum of air immersion
and ground surface exposures), and total,
respectively.
Factor to be printed
0 = both high- and low-LET
1 = only combined LET table
2 = all three tables.
Factor to be printed
= 0 both high- and low-LET
= 1 only combined LET table
= 2 all three tables.
Indicates selected individual (LTABLE=1),
mean individual (LTABLE=2), or collective
group (LTABLE=3).
Number of organ dose weights to use to
combine dose rates.
The organs to be used.
4-20
-------�
TABLE 4-2
(Continued)
Namelist
Group Variable Description
ORGDAT Organ dose weighting factors.
IPATH Exposure pathway affected (1 = ingestion;
2 = inhalation;3 = air immersion; 4 = ground
surface; 5 = all pathways).
The Internation Commission on Radiological
Protection has recently suggested the use
of a risk equivalent which provides a
stochastic weighting of radiosensitivity of
various organs in the body for exposure to
whole body radiation.
4-21
-------�
4.3 DATA FOR THE INFILTRATION SUBROUTINE
The input data to the infiltration subroutine (INFIL) are read from
input unit 4. The infiltration data are of four types: hydrologic and
trench description characteristics; maximum day length in hours by month;
daily mean temperatures by month; and hourly precipitation for nonzero
precipitation events. The last card in the data set must have "99" in the
first two columns. Table 4-3 gives a complete description of the data and
card locations for this data file.
4.4 DOSIMETRIC AND HEALTH EFFECTS DATA
This data set is read in an unformatted form from input unit 25. This
data file is on a magnetic tape which contains reference dosimetric
information about many radionuclides and was created by the program RADRISK.
This data set is very extensive and is usually not modified for a specific
run. For a more detailed description see the RADRISK manual (Du80).
4-22
-------�
TABLE 4-3
INPUT DATA FOR SUBROUTINE INFIL
Card Variable (Input Format) Description
CARD 1 Trench Cap Characteristics (10F7.3)
TWT - The width of the trench cap (m).
SLOP - The average slope of trench cover (m/m).
EPS6 - The component of porosity for gravity water
of trench cap (unitless).
EPSP - The component of porosity for pellicular
water of trench cap (unitless).
XKI - The permeability of trench cover (m/hr).
YGMAX - The thickness of the trench cap (m). This
must be equal to OVER.
XDE - The equivalent upward diffusivity (m2/hr).
XKE - The equivalent upward hydraulic conduc-
tivity (m/hr).
YPI - The initial pellicular water deficit of the
trench cap (m).
YGI - The initial gravity water deficit of the
trench cap (m).
CARD 2 Day Length Data (12F5.1)
DTH(IM) - The maximum day length for month IM (hr).
There are 12 values; one for each month
from January to December.
CARDS Temperature Data (2X, 12F6.2)
3-33
TMP(IM) - The mean daily temperatures (°C). Each
card has 12 values, one for each month.
There are 31 cards of this type, one for
each day of the month.
CARD Precipitation Data (12, IX, 12, IX, 24F3.0)
34+
MO - Month number.
IDA - Day number of month MO.
4-23
-------�
TABLE 4-3
(Continued)
Card Variable (Input Format)
Description
P(MO,IDA)
LAST CARD End of File (12)
IAMP
- Amount of precipitation that fell in this
hour (0.1 mm/hr). There are 24 values on
each card, one for each hour of the day.
Include only days with a nonzero amount of
precipitation, and the first day of each
month.
Must equal 99, which designates the end of
the data set.
4-24
-------�
5. OUTPUT OF PRESTO-EPA-BRC
The output of PRESTO-EPA-BRC is designed to be self-explanatory and
contains descriptive comments, definitions, and intermediate and final
tabulations. It is assumed that the output may be analyzed by users
unfamiliar to PRESTO-EPA-BRC structure.
The PRESTO-EPA-BRC output is organized into eleven sections, each
described below. A complete PRESTO-EPA-BRC output listing is given in
Appendix B in conjunction with the sample problem of Chapter 6.
5.1 REPLICATION OF INPUT DATA
The first section of the PRESTO-EPA-BRC output is a replication of the
user supplied input data files (1) and (2) as read in. This provides the
user with a record of the input data set used for later result identifica-
tion and analysis.
PRESTO-EPA-BRC also organizes this input data to allow for easy
interpretation. A summary of the input data files (1) and (2) is printed
according to data type and transport subsystem. These descriptive
summaries are output in sentence format to increase their ease of review.
5.2 RADIONUCLIDE SUMMARY TABLES
A set of four tables under the heading "Nuclide Information" summarizes
the radionuclide data used for the transport calculations. First, an
inventory table specifies the initial inventory in the trench, on the soil
5-1
-------�
surface, in the stream, and in the air. Also included with this table are
the decay constants and the user-supplied solubility constant. The second
radionuclide table summarizes the chemical distribution coefficients for
the surface soil, the trench contents, the vertical soil column, and the
aquifer. The third radionuclide table summarizes seven radionuclide-
specific food chain parameters used by the FOOD, IRRIG, HUMEX, CV, and COV
subroutines. The fourth table presents the atomic mass numbers used in the
calculations, as extracted from the user supplied radionuclide names.
These atomic mass numbers are output in tabular form as a convenience for
the user.
5.3 INFIL INPUT/OUTPUT
The third output section of PRESTO-EPA-BRC consists of the input data
and results for the subroutine INFIL. The input to subroutine INFIL is
presented first and consists of: infiltration control; monthly averages
for hours of sunshine; daily average temperatures; hourly rainfall amounts;
and specific trench characteristics (snowmelt coefficients, trench cover
thickness, width, cover slope, porosity, and permeability).
With these input data, subroutine INFIL calculates and outputs several
data items. The most important of these is the annual infiltration and
annual precipitation. Annual evaporation, runoff and cap infiltration are
also calculated and output.
5-2
-------�
5.4 INITIAL UNIT RESPONSE CALCULATIONS
This output section presents the results of the nuclide-specific
annual transport calculations which will be used by the bookkeeping
submodels for each simulation year. They also include the amount of soil
lost and the atmospheric radionuclide concentration per unit release rate
ratio, as calculated at the waste site.
5.5 ANNUAL SUMMARIES FOR INTERMEDIATE SIMULATION YEARS
Input control parameters determine the years for which intermediate
results are printed. For these years, a number of hydrological and
transport variables are output. Included are trench cap status, water
depth in trench, water loss by overflow and drainage from the trench, and
trench radionuclide inventories. Radionuclide concentrations and flux
values are also given for key pathways and regions of interest.
5.6 RADIONUCLIDE CONCENTRATION TABLES
The radionuclide concentration tables present, by radionuclide, the
average concentration over the entire assessment period, the year of
maximum concentration, and the level of the maximum concentration for the
atmosphere, for the well water, and for the stream water.
5.7 RADIONUCLIDE EXPOSURE RATES
Annual population uptakes of radionuclides are next output. The
uptake factors quantify, on a radionuclide specific basis, the annual
5-3
-------�
amount of nuclide uptake by the population group from all potential sources.
For inhalation, it is just the breathing rate. For ingestion, it is the
total nuclide uptake from the consumption of contaminated vegetation, meat,
milk, seafood, and drinking water.
5.8 DARTAB CONTROL INFORMATION
DARTAB control information dealing with run identification data,
summaries of output table control information, lists of organs and cancers
to be considered in the run, dose equivalent factors for low and high LET
radiation, and radionuclide uptake and clearance data are next output.
5.9 DARTAB DOSE TABLES
DARTAB dose tables are next output. These present individual and
collective dose summary rates by low and high LET radiation and organ, by
low and high LET radiation and exposure pathway, and by low and high LET
radiation and radionuclide. Tables involving organ dose summaries also
include the user specified weighting factors.
5.10 DARTAB FATAL CANCER RISK TABLES
PRESTO-EPA-BRC next presents DARTAB fatal cancer risk tables. These
tables include: individual and collective fatal cancer risks, loss of life
by premature death, lifetime fatal cancer risk exposure equivalents, and
genetic risks. Values are summarized by low and high LET radiation and
organ and by low and high LET radiation and pathway. The specific tables
output are subject to the user specified DARTAB control data.
5-4
-------�
5.11 RADIOACTIVITY RELEASED TO THE REGIONAL BASIN AND HEALTH EFFECTS
This output section presents the amount of radionuclides released to
the regional (basin) population for each millenium in a 10,000 year simula-
tion. It also shows the aggregated total release of each radionuclide, the
health conversion factors and the regional basin population health effects
by radionuclide.
5-5
-------�
6. SAMPLE PROBLEM
6.1 PROBLEM DEFINITION
For the sample problem the burial of a unit volume (1 m3) of generated
waste is considered. The waste thickness is two meters. A 0.6 meter cover
is used and the distance from the bottom of the trench to the aquifer is
7.3 meters. Cover failure begins in year 1 at 20 percent and increases
linearly up to a 30 percent maximum and final value at year 200. A 1000
year simulation is performed and annual summaries output every 100 years.
The physical properties of the waste, the subtrench material, and the
aquifer are as follows. The porosity and density of the waste are 0.25 and
0.89 g/cc. For the subtrench material these values are 0.35 and 1.6 g/cc.
The porosity and density of the aquifer formation are 0.39 and 1.6 g/cc.
The subtrench permeability is 2.2 m/yr. The dispersivity in the subtrench
soil and in the aquifer is 0.3 meters (the default value). The aquifer
velocity is 27.8 meters per year and its thickness is 30.5 meters. An
aquifer dispersion angle of 0.3 radian has been assumed.
Half of the livestock water, and all human drinking water are assumed
to come entirely from well water. The percentage of aquifer discharge to
the surface water is 100 percent. The well is 1610 meters downflow from
the facility. The stream has an annual flow of 3.57xl05 m3 and is 100 meters
downslope from the facility. A cross slope spillage of 1003 meters is
assumed. The runoff is 29 percent of the annual precipitation. The water-
shed infiltration rate is 0.43 m/yr. The surface soil data are summarized
in Table 6-1. The atmospheric data used in the sample problem are given in
Table 6-2.
6-1
-------�
TABLE 6-1
SURFACE SOIL DATA
Rainfall Factor 250
Erodability Factor 0.23
Slope Factor 0.27
Cover Factor 0.30
Erosion Control Factor 0.30
Sediment Delivery Factor 1
Cross Slope Extent of Spillage 1003 m
Active Depth For Contamination 0.1 m
6-2
-------�
TABLE 6-2
ATMOSPHERIC DATA
Source Height
Gravitational Fall Velocity
Mean Wind Speed
Deposition Velocity
Source to Receptor Distance
Atmospheric Lid Height
Hosker Roughness Factor
Fraction of Time Wind Blows Toward Population
User Specific X/Q
First Coefficient in Resuspension Equation
Decay Factor in Resuspension Equation
Final Coefficient in Resuspension Equation
Fraction of Year Mechanical Disturbance Occurs
Stability Class Formulation
Stability Class
1 m
0.01 m/sec
2.01 m/sec
0.10 m/sec
1.77xl04 m
300 m
0.01 m
0.484
l.OSxlO-11 s/m3
1x10
-6
-0.15
IxlO'11
0
1 (Pasquill-Gifford)
4 (neutral)
6-3
-------�
Foodchain parameters have been summarized in Table 6-3. The human
consumption of leafy vegetation is 2 kg/yr; produce is 18 kg/yr; cow milk
is 11 L/yr; goat milk is 0 L/yr; and meat is 9 kg/yr. Each person consumes
370 liters of water per year. The inhalation rate is 8000 m3/yr. The
exposed population is 25. Radionuclide specific foodchain data is given in
Table 6-4.
The radionuclide inventory for the waste is given in Table 6-5. In
addition, a surface spillage fraction of 0.01 is assumed for each radio-
nuclide. Decay constants and sets of K
-------�
TABLE 6-3
FOODCHAIN PARAMETERS
Grass Production 0.67 kg/m2yr
Vegetation Production 0.65 kg/m2yr
Surface Density for Soil 240 kg/m2
Weathering Decay Constant 0.0021 hr"1
Period Pasture Exposed During Growing Season 720 hr
Period Crops Exposed During Growing Season 1440 hr
Period Between Harvest Pasture and Ingestion by Animal 0.0 hr
Period Between Stored Feed and Ingestion by Animal 2160 hr
Period Between Harvest Leafy Vegetation and Ingestion 24 hr
by Man
Period Between Harvest Produce and Ingestion by Man 1440 hr
Period Between Harvest Leafy Vegetables and Ingestion 336 hr
by Man for General Population Exposure
Period Between Harvest of Produce and Ingestion by Man 336 hr
for General Population Exposure
Fraction of Year Animal Graze on Pasture 1.0
Fraction of Daily Feed that is Fresh Grass While 0.83
Animals are on Pasture
Amount of Feed Consumed Daily by Cattle 50 kg
Amount of Feed Consumed Daily by Goats 6 kg
Transport Time Feed-Mill-Receptor for Maximum Individual 48 hr
Exposure
Transport Time Feed-Mill-Receptor For General Population 96 hr
Exposure
Time From Slaughter of Meat to Consumption 480 hr
Absolute Humidity of the Atmosphere 9.9 g/m^
Fractional Equilibrium Ratio for Carbon-14 1.0
Fraction of Year Crops are Irrigated 0.40
Irrigation Rate 0.015 L/m2hr
Amount of Water Consumed by Cows 60 L/d
Amount of Water Consumed by Goats 8 L/d
Amount of Water Consumed by Beef Cattle 50 L/d
6-5
-------�
TABLE 6-4
RADIONUCLIDE SPECIFIC FOODCHAIN DATA
o>
Nuclide
H-3
C-14
Cr-51
Mn-54
Fe-55
Co-58
Ni-59
Co-60
Ni-63
Sr-90
Nb-94
Tc-99
Ru-106
Sb-125
1-129
Cs-134
Cs-135
Cs-137
Ce-144
Eu-154
Ra-226
U-234
U-235
Np-237
U-238
Pu-238
Pu-239
Pu-241
Am-241
Pu-242
Am-243
Cm-243
Cm-244
Retention
Fraction
For Air
0.20
0.20
0.20
0.20
0.20
0.20
0.20
0.20
0.20
0.20
0.20
0.20
0.20
0.20
0.20
0.20
0.20
0.20
0.20
0.20
0.20
0.20
0.20
0.20
0.20
0.20
0.20
0.20
0.20
0.20
0.20
0.20
0.20
Retention
Fraction For
Irrigation
0.25
0.25
0.25
0.25
0.25
0.25
0.25
0.25
0.25
0.25
0.25
0.25
0.25
0.25
0.25
0.25
0.25
0.25
0.25
0.25
0.25
0.25
0.25
0.25
0.25
0.25
0.25
0.25
0.25
0.25
0.25
0.25
0.25
Soil-To-Plant
Uptake Factor
(Vegetables)
4.8
5.5
2.5E-4
2.5E-1
4.0E-3
2.0E-2
6.0E-2
2.0E-2
6.0E-2
2.5
2.0E-2
9.5
7.5E-2
2.0E-1
1.0
8.0E-2
8.0E-2
8.0E-2
l.OE-2
2.5E-3
1.5E-4
8.5E-3
8.5E-3
4.3E-3
8.5E-3
4.5E-4
4.5E-4
4.5E-4
5.5E-3
4.5E-4
5.5E-3
8.5E-4
8.5E-4
Soil-To-Plant
Uptake Factor
(Grain)
4.8
5.5
5.0E-2
5.0E-2
l.OE-3
7.0E-3
6.0E-2
7.0E-3
6.0E-2
2.5E-1
5.0E-3
1.5
2.0E-2
3.0E-2
1.0
3.0E-2
3.0E-2
3.0E-2
4.0E-3
2.5E-3
1.5E-3
4.0E-3
4.0E-3
4.3E-3
4.0E-3
4.5E-5
4.5E-5
4.5E-5
2.5E-4
4.5E-5
2.5E-4
1.5E-5
1.5E-5
Forage-To-Milk
Transfer Factor
(Cows)
l.OE-2
1.2E-2
2.2E-3
3.5E-4
2.5E-4
2.0E-3
l.OE-3
2.0E-3
l.OE-3
2.5E-3
2.0E-2
l.OE-2
6.0E-7
l.OE-4
l.OE-2
7.0E-3
7.0E-3
7.0E-3
2.0E-5
2.0E-5
4.5E-4
6.0E-4
6.0E-4
5.0E-6
6.0E-4
l.OE-7
l.OE-7
l.OE-7
4.0E-7
l.OE-7
4.0E-7
2.0E-5
2.0E-5
Forage-To-Milk
Transfer Factor
(Goats)
1.7E-1
l.OE-1
l.OE-3
2.5E-4
1.3E-4
l.OE-3
6.7E-3
l.OE-3
6.7E-3
1.4E-2
2.5E-3
2.5E-2
1.3E-4
1.5E-3
3.0E-1
3.0E-1
3.0E-1
3.0E-1
l.OE-4
2.0E-5
5.0E-6
5.0E-4
5.0E-4
5.0E-6
5.0E-4
1.5E-6
1.5E-6
1.5E-6
0
1.5E-6
0
0
0
Forage-To-Beef
Transfer Factor
1.2E-2
3.1E-2
2.4E-3
4.0E-4
2.0E-2
3.0E-2
6.0E-3
2.0E-2
6.0E-3
3.0E-4
2.5E-1
2.5E-3
2.0E-3
l.OE-3
7.0E-3
2.0E-2
2.0E-2
2.0E-2
7.5E-4
4.8E-3
2.5E-4
2.0E-4
2.0E-4
5.5E-5
2.0E-4
5.0E-7
5.0E-7
5.0E-7
3.5E-6
5.0E-7
3.5E-6
3.5E-6
3.5E-6
-------�
TABLE 6-5
INVENTORY
Nuclide
H-3
C-14
Cr-51
Mn-54
Fe-55
Co-58
Ni-59
Co-60
Ni -63
Sr-90
Nb-94
Tc-99
Ru-106
Sb-125
1-129
Cs-134
Cs-135
Cs-137
Ce-144
Eu-154
U-234
U-235
Np-237
U-238
Pu-238
Pu-239
Pu-240
Pu-241
Am-241
Pu-242
Am-243
Cm-243
Cm-244
Inventory
(Ci)
0.99
0.99
0.99
0.99
0.99
0.99
0.99
0.99
0.99
0.99
0.99
0.99
0.99
0.99
0.99
0.99
0.99
0.99
0.99
0.99
0.99
0.99
0.99
0.99
0.99
0.99
0.99
0.99
0.99
0.99
0.99
0.99
0.99
6-7
-------�
TABLE 6-6
RADIONUCLIDE SPECIFIC DATA
Nuclide
H-3
C-14
Cr-51
Mn-54
Fe-55
Co-58
Ni-59
Co-60
Ni-63
Sr-90
Nb-94
Tc-99
Ru-106
Sb-125
1-129
Cs-134
Cs-135
Cs-137
Ce-144
Eu-154
U-234
U-235
Np-237
U-238
Pu-238
Pu-239
Pu-240
Pu-241
Am-241
Pu-242
Am-243
Cm-243
Cm-244
Decay
Constant
(yr-1)
5.65E-02
1.21E-04
9.14E+00
8.09E-01
2.57E-01
3.55E+00
8.66E-06
1.32E-01
7.53E-03
2.42E-02
3.47E-05
3.25E-06
6.89E-01
2.50E-01
4.08E-08
3.36E-01
2.30E-07
2.31E-02
8.90E-01
4.33E-02
2.83E-06
9.85E-10
3.30E-07
1.55E-10
7.90E-03
2.87E-05
1.06E-04
5.25E-02
1.51E-03
1.83E-06
9.40E-05
2.17E-02
3.94E-02
Surface
Kd
l.OOE-02
l.OOE-02
2.00E+02
1.50E+02
6.00E+03
5.50E+01
1.50E+02
5.50E+01
1.50E+02
1.50E+02
3.50E+02
5.00E-01
2.20E+02
4.50E+01
3.00E+00
l.OOE+03
l.OOE+03
l.OOE+03
1.10E+03
4.00E+03
7.50E+02
7.50E+02
5.00E+00
7.50E+02
3.50E+03
3.50E+03
3.50E+03
3.50E+03
8.00E+04
3.50E+03
8.00E+04
3.30E+03
3.30E+03
Trench
Kd
9.60E-02
9.60E-02
8.90E-04
8.86E-04
8.86E-04
8.86E-04
8.86E-04
8.86E-04
8.86E-04
1.47E-03
6.34E-04
4.86E-02
6.34E-04
8.86E-04
1.29E-02
2.23E-05
2.23E-05
2.23E-05
2.23E-05
2.23E-05
1.49E-05
1.49E-05
8.19E-03
1.49E-05
6.38E-05
6.38E-05
6.38E-05
5.55E-04
5.55E-04
6.38E-05
5.55E-04
6.38E-05
6.38E-05
Vertical
Kd
l.OOE-02
l.OOE-02
2.00E+02
1.50E+02
6.00E+03
5.50E+01
1.50E+02
5.50E+01
1.50E+02
1.50E+02
3.50E+02
5.00E-01
2.20E+02
4.50E+01
3.00E+00
l.OOE+03
l.OOE+03
l.OOE+03
1.10E+03
4.00E+03
7.50E+02
7.50E+02
5.00E+00
7.50E+02
3.50E+03
3.50E+03
3.50E+03
3.50E+03
8.00E+04
3.50E+03
8.00E+04
3.30E+03
3.30E+03
Aquifer
Kd
l.OOE-02
l.OOE-02
2.00E+02
1.50E+02
6.00E+03
5.50E+01
1.50E+02
5.50E+01
1.50E+02
2.00E+01
3.50E+02
5.00E-01
2.20E+02
4.50E+01
5.00E-01
5.00E+02
5.00E+02
5.00E+02
1.10E+03
4.00E+03
7.50E+02
7.50E+02
5.00E+00
7.50E+02
3.50E+03
3.50E+03
3.50E+03
3.50E+03
8.00E+04
3.50E+03
8.00E+04
3.30E+03
3.30E+03
6-8
-------�
The activity median aerodynamic diameter, respiratory clearance class
and gastrointestinal absorption factors for each radionuclide are given in
Table 6-7. For the latter parameter only the small intestine values are
shown. The factors for the other three segments are zero.
The output location table includes the following pathways: ingestion,
inhalation, air immersion, ground surface exposures, internal exposures,
external exposures and total. Only combined high and low LET tables are
output. The organ weighting factors for combined dose rates are given in
Table 6-8. The exposures are summed over all pathways. The input data for
the INFIL subroutine is listed in Tables 6-9 through 6-12. The complete
output for this problem is given in Appendix B. Each printout includes an
exact replica of the corresponding site input data set, and thus the input
data set is not reproduced in this section.
6.2 RESULTS
The output for the sample problem described in Section 6.1 is given in
Appendix B. Chapter 5 of this report discusses each section of the
PRESTO-EPA-BRC output in detail.
A summary of the significant results is given in Table 6-13. From
this summary table, the maximum population whole body doses occur mainly
from contaminated groundwater and well water via the ingestion pathway.
The relatively permeable soils and associated aquifer velocities allow for
6-9
-------�
TABLE 6-7
RADIONUCLIDE SPECIFIC DOSE PARAMETERS
Activity Respiratory Gastrointestinal
Median Aerodynamic Clearance Absorption Factor
Nuclide Diameter (10"" m) Class (small intestine)
H-3 0.0 * (gas) 0.95
C-14 0.0 * (gas) 0.95
Cr-51 1.0 Week 0.10
Mn-54 1.0 Week 0.10
Fe-55 1.0 Week 0.10
Co-58 1.0 Year 0.05
Ni-59 1.0 Week 0.05
Co-60 1.0 Year 0.05
Ni-63 1.0 Week 0.05
Sr-90 1.0 Day 0.01
Nb-94 1.0 Year 0.01
Tc-99 1.0 Week 0.80
Ru-106 1.0 Year 0.05
Sb-125 1.0 Week 0.20
1-129 1.0 Day 0.95
Cs-134 1.0 Day 0.95
Cs-135 1.0 Day 0.95
Cs-137 1.0 Day 0.0003
Ce-144 1.0 Year 0.0001
Eu-154 1.0 Week 0.20
U-234 1.0 Week 0.002
U-235 1.0 Year 0.002
Np-237 1.0 Year 0.001
U-238 1.0 Week 0.002
Pu-238 1.0 Year 0.001
Pu-239 1.0 Year 0.0001
Pu-240 1.0 Year 0.0001
Pu-241 1.0 Year 0.001
Am-241 1.0 Week 0.001
Pu-242 1.0 Year 0.0001
Am-243 1.0 Week 0.001
Cm-243 1.0 Week 0.001
Cm-244 1.0 Week 0.001
6-10
-------�
TABLE 6-8
ORGAN WEIGHTING FACTORS
Organ Factor
Red Marrow 0.1552
Endosteum 0.0035
Thyroid 0.0987
Breast 0.1299
Pulmonary 0.2075
Stomach Wall 0.0840
Intestinal Wall 0.0390
Liver 0.0853
Pancreas 0.0585
Kidneys 0.0248
Other 0.1136
6-11
-------�
TABLE 6-9
INFIL INPUT DATA FOR THE SAMPLE PROBLEM
Trench cap width 30.5 m
Average slope of trench cover 0.01 m/m
Component of porosity for gravity water 0.25
of trench cap
Component of porosity for pellicular water 0.24
of trench cap
Permeability of trench cover 0.02 m/hr
Trench cap thickness 1.2 m
Equivalent upward diffusivity 3.5E-4 m^/hr
Equivalent upward hydraulic conductivity 1.4E-6 m/hr
Initial pellicular water deficit 0.10 m
Initial gravity water deficient 1.2 m
Maximum day lengths Table 6-10
Daily mean temperatures Table 6-11
Hourly precipitation Table 6-12
6-12
-------�
TABLE 6-10
MAXIMUM DAY LENGTHS FOR SAMPLE PROBLEM
Month Hours
January 10.8
February 11.2
March 12.0
April 12.8
May 13.4
June 13.7
July 13.6
August 13.0
September 12.3
October 11.6
November 10.9
December 10.6
6-13
-------�
TABLE 6-11
DAILY TEMPERATURES IN DEGREES CELSIUS
Month
Das
Jan
Feb
Mar
Apr
Jun Jul Aug
Oct
Nov
Dec
-...*•
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
8.88
8.48
7.05
15.27
6.13
8.84
15.54
15.54
15.54
15.54
15.54
15.54
15.54
15.54
15.54
15.54
15.54
8.78
12.54
16.73
15.27
6.46
8.41
5.96
7.04
2.14
-1.54
5.18
7.55
11.00
16.16
10.16
6.81
7.79
13.93
12.14
13.12
6.94
9.23
13.06
8.44
8.13
4.59
7.46
8.97
14.71
19.33
16.27
8.03
10.02
11.90
14.61
8.04
10.49
16.75
12.71
1.94
2.03
3.65
0.00
0.00
0.00
6.00
8.76
12.65
14.35
17.74
16.25
10.90
4.41
7.93
13.33
17.32
18.87
21.13
19.19
19.25
12.33
17.60
17.04
20.02
23.06
23.56
17.91
15.05
13.29
16.55
13.24
6.57
6.58
11.19
16.00
16.25
r
20.92
19.34
20.61
16.68
11.78
12.02
8.20
8.60
12.57
11.21
12.79
15.35
17.93
20.56
20.36
20.93
21.36
16.86
14.26
19.05
20.29
16.27
11.65
13.41
16.35
20.59
18.13
17.02
15.51
15.75
0.00
17.80
19.45
20.04
20.37
11.90
20.78
20.90
21.38
20.27
20.66
21.81
22.07
15.08
25.52
25.06
24.61
23.36
22.95
21.02
22.92
23.55
24.74
23.82
23.58
24.17
24.16
23.39
25.76
27.44
23.84
24.13
25.34
26.79
25.34
23.45
25.40
24.17
23.86
26.07
27.60
25.60
24.10
23.99
23.10
23.70
26.20
26.46
21.95
22.49
25.70
26.07
26.62
24.69
24.83
23.50
24.63
24.98
24.05
25.13
25.97
27.27
0.00
26.30
25.79
27.73
28.48
25.39
22.78
18.01
12.58
21.33
24.66
25.09
25.93
23.91
24.89
24.26
24.17
24.74
25.83
25.59
26.55
27.56
27.67
24.88
25.21
26.21
28.02
29.36
27.35
24.49
25.53
24.50
24.99
25.92
25.28
26.23
23.77
23.78
25.78
25.85
25.12
25.61
24.93
24.71
24.22
25.27
24.69
25.35
24.29
22.87
24.17
25.24
26.62
25.99
27.02
27.62
25.31
18.80
20.31
25.31
20.37
20.49
20.24
21.89
22.43
22.71
18.00
16.67
15.04
15.87
16.54
18.09
19.68
21.19
21.44
24.27
24.12
25.82
25.74
25.48
24.45
23.35
21.76
21.76
21.76
21.76
21.76
21.76
21.76
21.76
21.76
21.76
20.81
0.00
13.96
19.38
20.17
18.79
20.95
22.37
22.63
21.47
22.77
21.45
17.03
19.06
19.10
15.71
12.18
12.97
10.93
12.78
17.31
18.55
18.82
13.71
10.64
8.38
9.97
13.11
11.43
12.19
12.27
14.62
17.46
19.89
19.56
19.56
19.56
19.56
19.56
19.56
19.56
19.56
19.56
19.56
19.56
19.56
19.56
19.56
19.56
19.56
19.56
19.56
15.42
17.86
16.34
16.61
16.83
9.64
12.35
15.29
13.85
19.11
15.48
0.00
19.77
19.15
19.73
19.23
20.96
13.86
11.56
11.70
13.60
8.13
9.71
7.16
0.08
4.30
13.68
13.17
4.78
1.99
2.85
6.18
5.16
4.64
8.33
14.85
17.31
15.14
16.79
18.56
13.72
7.34
5.07
6-14
-------�
TABLE 6-12
HOURLY RAINFALL READ IN AS MONTH, DAY, RAINFALL PER HOUR
AND HOUR AND GIVEN IN 0.1 mm/hr
Month Day 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24
Jan
Jan
Jan
Jan
Jan
Jan
Jan
Jan
Jan
Feb
Feb
Feb
Feb
Feb
Feb
Feb
Feb
Feb
Mar
Mar
Mar
Mar
Apr
Apr
Apr
Apr
Apr
Apr
Apr
Apr
Apr
Apr
May
May
May
May
May
May
1
3
4
13
14
19
20
23
31
1
2
3
9
12
16
17
26
27
1
7
17
24
1
3
5
8
12
17
20
25
26
27
1
17
19
24
27
30
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0. 0.
0. 23.
47. 23.
0. 0.
0. 23.
0. 0.
0. 0.
0. 0.
0. 0.
0. 0.
0. 0.
0. 0.
0. 0.
0. 0.
0. 23.
0. 0.
0. 0.
23. 0.
0. 0.
0. 0.
0. 0.
0. 0.
0. 0.
0. 0.
0. 0.
0. 0.
0. 0.
0. 0.
0. 23.
0. 0.
23. 47.
0. 0.
0. 0.
0. 0.
0. 0.
0. 0.
0. 0.
0. 0.
0.
23.
23.
0.
0.
0.
0.
0.
0.
0.
0.
47.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
93.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
70.
47.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
47.
0.
0.
0.
0.
0.
0.
23.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
47.
0.
0.
0.
0.
0.
0.
0.
47.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
47.
0.
0.
0.
0.
23.
23.
0.
23.
0.
23.
0.
23.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
23.
0.
0.
0.
0.
23.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
47.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
70.
0.
0.
47.
0.
23.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
23.
0.
0.
0.
23.
0.
0.
0.
0.
0.
23.
0.
0.
23.
0.
0.
0.
23.
23.
0.
0.
0.
70.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
47.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
47.
0.
0.
0.
93.
0.
0.
0.
70.
0.
47.
0.
0.
0.
0.
0.
0.
0.
0.
0.
47.
23.
0.
0.
0.
0.
93.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
140.
0.
93.
0.
0.
0.
23.
0.
117.
326.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
23.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
23.
350.
0.
0.
0.
0.
23.
186.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
47.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
-------�
Month
Jun
Jun
Jun
Jun
Jun
Jun
Jun
Jun
Jun
Jun
Jul
Jul
Jul
Jul
Jul
Jul
Jul
Jul
,' Jul
• Jul
Jul
Jul
Jul
Jul
Jul
Aug
Aug
Aug
Aug
Aug
Aug
Aug
Aug
Sep
Sep
Sep
Sep
Sep
Sep
Day
1
3
12
13
16
17
22
26
27
28
1
4
5
7
9
13
14
15
16
19
20
23
24
27
29
1
5
6
7
8
9
12
18
1
10
18
19
21
26
1
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
2
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
3
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
4
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
5
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
6
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
7
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
8
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
9
0.
0.
0.
93.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
10
0.
0.
0.
47.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
c.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
47.
0.
TABLE 6-12
(Continued)
11 12 13
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
23.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
117.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
14
0.
0.
0.
0.
0.
0.
47.
0.
0.
0.
0.
0.
0.
0.
70.
47.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
15
0.
0.
0.
0.
0.
47.
0.
0.
0.
70.
0.
0.
0.
0.
23.
210.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
16
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
70.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
93.
0.
0.
0.
0.
0.
0.
17
0.
0.
0.
0.
0.
0.
0.
0.
70.
0.
0.
0.
0.
0.
0.
0.
0.
23.
23.
280.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
47.
0.
0.
0.
47.
0.
0.
18
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
163.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
a.
23.
23.
0.
0.
0.
0.
0.
0.
19
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
20
0.
0.
163.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
210.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
140.
0.
0.
0.
21
0.
0.
0.
0.
93.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
117.
23.
0.
0.
0.
0.
419.
0.
0.
0.
0.
0.
0.
0.
23.
233.
0.
0.
0.
22
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
93.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
23
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
24
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
-------�
Month
Oct
Oct
Oct
Oct
Oct
Oct
Oct
Nov
Nov
Nov
Nov
Nov
Dec
Dec
Dec
Dec
-------�
TABLE 6-13
SUMMARY OF RESULTS FOR SAMPLE CASE
By Pathway By Nuclide
Results Total Ingestion Inhalation Surface C-14 Tc-99 1-129
Whole Body Equivalent 2.16E-02 2.16E-02 1.84E-11 8.86E-11 8.59E-05 1.02E-04 2.14E-02
Dose Rate
(person rem/yr)
^ Collective Fatal 6.55E-07 6.55E-07 1.45E-15 2.49E-14 2.41E-08 2.87E-08 6.02E-07
00 Cancer Risk
(deaths/yr)
Whole Body Equivalent 2.34E-03 2.34E-03 5.26E-12 8.86E-11 8.59E-05 1.02E-04 2.15E-03
Risk From All
Exposures
(person rem/yr)
-------�
relatively rapid transport of the more mobile radionucl ides to the well.
Iodine-129, carbon-14, and technicium-99 dominate the contributions to the
total dose commitment.
Finally, it should be noted that the sample problem described in
Section 6.1 merely illustrates the application of PRESTO-EPA-BRCT and is not
intended as a basis for arriving at any general conclusions regarding
specific disposal alternatives.
6.3 JOB CONTROL LANGUAGE
The IBM job control language (JCL) used to execute the run is shown in
Figure 6-1. GMWLLWM.BRC is the PRESTO-EPA-BRC source code. GMWLLWM.SAMPLE
is the site/environmental data file. The file, CBNRACS.RADRISK.V4BD, is
the RADRISK data file. The file GMWLLWM.BRIT is the infiltration data file.
6-19
-------�
1. //GMW JOB (,),ROGERS,TIME=(7,0)
2. // EXEC FORTXCLG,GREGION=8000K
3. //FORT.SYSIN DD DSN=GMWLLWM.BRC,DISP=SHB
4. //GO.FT25F001 DD DSN=CBNRACS.RADRISK.V4BD,DISP=SHR
5. //GO.FT04F001 DD DSN=GMWLLWM.BRIT,DISP-SHR
6. //GO.FT26F001 DD UNIT=SYSDA,DSN=&&DATA,DISP=(NEW,DELETE),
7. // SPACE=(TRK,(30,10),RLSE),DCB=(RECFM=FB,LRECL=80,BLKSIZE=3200)
8. //GO/SYSIN DD DSN=GMWLLWM.SAMPLE,DISP=SHR
FIGURE 6-1. PRESTO-EPA-BRC JCL.
6-20
-------�
REFERENCES
Du80 Dunning, D. E., Jr., R. W. Leggett, and M. G. Yalcintas, A
Combined Methodology for Estimating Dose Rates and Health Effects
from Exposures to Radioactive Pollutants, ORNL/TM-7105 (Oak Ridge
National Laboratory, Oak Ridge, Tennessee), 1980.
EPA87a U.S. Environmental Protection Agency, PRESTO-EPA-POP: A Low-Level
Radioactive Waste Environmental Transport and Risk Assessment Code
Volume 1, Methodology Manual, EPA 520/1-87-024-1, Washington, DC,
December 1987.
EPA87b U.S. Environmental Protection Agency, PRESTO-EPA-POP: A Low-Level
Radioactive Waste Environmental Transport and Risk Assessment Code -
Volume 2, User's Manual, EPA 520/1-87-024-2, Washington, DC, December
1987.
EPA87c U.S. Environmental Protection Agency, PRESTO-EPA-DEEP: A Low-Level
Radioactive Waste Environmental Transport and Risk Assessment Code,
Methodology and User's Manual, EPA 520/1-87-025, Washington, DC,
December 1987.
EPA87d U.S. Environmental Protection Agency, PRESTO-EPA-CPG: A Low-Level
Radioactive Waste Environmental Transport and Risk Assessment Code,
Methodology and User's Manual, EPA 520/1-87-026, Washington, DC,
December 1987.
EPA87e U.S. Environmental Protection Agency, PRESTO-EPA-BRC: A Low-Level
Radioactive Waste Environmental Transport and Risk Assessment Code,
Methodology and User's Manual, EPA 520/1-87-027, Washington, DC,
December 1987.
EPA87f U.S. Environmental Protection Agency, PATHRAE-EPA: A Performance
Assessment Code for the Land disposal of Radioactive Wastes,
Methodology and User's Manual, EPA 520/1-87-028, Washington, DC,
December 1987.
EPA87g U.S. Environmental Protection Agency, Accounting Model for
PRESTO-EPA-POP, PRESTO-EPA-DEEP, and PRESTO-EPA-BRC Codes,
Methodology and User's Manual, EPA 520/1-87-029, Washington, DC,
December 1987.
R-l
-------�
EPA87h U.S. Environmental Protection Agency, Low-Level and NARM
Radioactive Wastes: Draft Environmental Impact Statement for
Proposed Rules, Vol. 1, Background Information Document,
EPA 520/1-87-012, 1987.
EPA87"i U.S. Environmental Protection Agency, Low-Level and NARM
Radioactive Wastes: Draft Environmental Impact Statement for
Proposed Rules, Vol. 2, Economic Impact Assessment,
EPA 520/1-87-012-2, 1987.
Ga84 Galpin, F. L., and G. L. Meyer, Overview of EPA's Low-Level
Radioactive Waste Standards Development Program, 1984:
Proceedings of 6th Annual Participants' Information Meeting on
DOE Low-Level Waste Management Program, Denver, Colorado,
September 11-13, 1984, CONF-8409115, Idaho Falls, Idaho.
Hu83 Hung, C. Y., G. L. Meyer, and V. C. Rogers, Use of PRESTO-EPA
Model in Assessing Health Effects from Land Disposal of LLW to
Support EPA's Environmental Standards: U.S. Department of
Energy, Proceedings of 5th Annual Participants' Information
Meeting on DOE Low-Level Waste Management Program, Denver,
Colorado, August 30, 1983, CONF-8308106, Idaho Falls, Idaho.
Su81 Sullivan, R. E., N. S. Nelson, W. H. Ellett, D. E. Dunning, Jr.,
R. W. Leggett, M. G. Yalcintas, and K.F. Eckerman, Estimates of
Health Risk from Exposure to Radioactive Pollutants, Oak Ridge
report, prepared for U.S. EPA, ORNL/TM-7745, 1981.
R-2
-------�
APPENDIX A
PRESTO-EPA-BRC LISTING
-------�
CAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA
CAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA
CAAAAAAAAAAAAAAAAAAAAAA PRESTO BRC AAAAAAAAAAAAAAAAAAAAAAAA
CAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA
CAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA
CAAA
A CODE FOR PREDICTING THE MIGRATION OF RADIOACTIVE UASTE FROM
SHALLOW LAND BURIAL SITES AND THE HEALTH EFFECTS THAT RESULT
FROM THESE LOU LEVEL RADIOACTIVE WASTES.
CAAA
CAAA
CAAA
CAAA
CAAA
CAAA
CAAA
CAAA
CAAA
CAAA
CAAA
CAAA
CAAA
CAAA
CAAA
CAAA
CAAA
CAAA
CAAA
C
C
C
C
CAAA
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
MODIFIED OCTOBER 1985 BY ROGERS ! ASSOC. ENGR. TO ALLOW DOSE
AND HEALTH EFFECT OUTPUT TO BE PRINTED FOR INTERMEDIATE YEARS
DURING THE SIMULATION PERIOD.
THE MAIN PROGRAM ACTS AS A SUPERVISOR FOR THE REST OF THE
CODE. MOST OF THE BOOKEEPING. 'INCLUDING MATERIAL BALANCE,
IS DONE HERE. THE FOLLOWING SUBROUTINES ARE CALLED:
SOURCE, AIRIRM. ERORF. TRENCH, LEACH, VERHOR, SURSOL,
SUSPND, OUT, FOOD, IRRIG, HUMEX, DARTAB, AND QUANC8.
GLOBAL VARIABLES
ADEPIH = AQUIFER DEPTH
AQDISP = AQUIFER DISPERSION ANGLE
AQIHK = AQUIFER THICKNESS
AQVOL = AQUIFER DILUTION FACTOR
AQAM = AMOUNT OF NUCLIDE AT WELL SHE
AQAVG = AVERAGE NUCLIDE CONCENT RATION AT WELL SHE
AQCON = NUCLIDE CONCENTRATION Al WELL SITE
ATAVG = AVEIAGE NUCLIDE CONCENTRATION IN ATMOSPHERE
ATCON = NUCLIDE CONCENTRATION IN ATMOSPHERE DOWNWIND
ATMASS = NUCLIDE MASS NUMBER
ABSERR = ABSOLUTE ERROR IN DDETA CALCULATION
BDENS = BULK DENSITY OF SOIL
CPL1 = NUCLIDE CONCENTRATION IN LEAFY VEGETABLES FOR
M.I.E. BY ATMOSPHERIC DEPOSITION
CPL2 = NUCLIDE CONCENTRATION IN PRODUCE FOR M.I.E.
BY ATMOSPHERIC DEPOSITION
CPL3 = NUCL1HE CONCENTRATION IN LEAFY VEGETABLES AND
PRODUCE FOR G.P.E. BY ATMOSPHERIC DEPOSITION
CS = CONCENTRATION IN SURFACE SOIL
CW = CONCENTRATION IN SURFACE WATER
CWAI = NUCLIDE CONCENTRATION IN WATER
CCMI1 = NUCLIDE CONCENTRATION IN COW'S MILK FOR M.I.E.
BY ATMOSPHERIC DEPOSITION
CCMI2 = NUCLIDE CONCENTRATION IN COW'S HILK FOfi G.P.E.
BY ATMOSPHERIC DEPOSITION
CQMI1 = NUCLIDE CONCENTRATION IN GOAT'S MILK FOR
M.I.E. BY ATMOSPHERIC DEPOSITION
M
RADIANS
M
MAA3
CI/MAA3
CI/MAA3
C1/MAA3
CI/MAA3
CI/MAA3
G/CC
PCI/KG
PCI/KG
PCI/KG
CI/KG
CI/MAA3
PCI/L
PCI/L
PCI/L
A-2
-------�
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
CGMI2 = NUCLIDE CONCENTRATION IN GOAT'S HILK FOR
6.P.E.BY ATMOSPHERIC DEPOSITION PCI/L
COPL1 = NUCLIDE CONCENTRATION IN LEAFY VEGETABLES FOR
H.l.L. BY IRRIGATION PCI/KG
COPL2 = NUCLIDE CONCENTRATION IN PRODUCE FOR M.I.E. BY
IRRIGATION PCI/KG
COPL3 = NUCLIDE CONCENTRATION IN LEAFY VEGETABLES AND
PRODUCE FOR G.P.E. BY IRRIGATION PCI/KG
CGMEAT = NUCLIDE CONCENTRATION IN BEEF MEAT BY
ATMOSPHERIC DEPOSITION PCI/KG
COCMI1 = NUCLIDE CONCENTRATION IN COW'S MILK FOR M.I.E.
BY IRRIGATION PC1/L
COCMI2 = NUCLIDE CONCENTRATION IN COM' MILK FOR G.P.E.
BY IRRIGATION PCI/L
COGHI1 = NUCLIDE CONCENTRATION IN GOAT'S MILK FOR
M.I.E. BY IRRIGATION PCI/L
COGMI2 = NUCLIDE CONCENTRATION IN GOAT'S MILK FOR
M.I.E. BY IRRIGATION PCI/L
COMEAT = NUCLIDE CONC IN BEEF HEAT BY IRRIGATION PCI/KG
DBA = INTERMEDIATE VARIABLE IN DDETA CALC.
DBB = INTERMEDIATE VARIABLE IN DDETA CALC.
DBD = DISPERSION COEtt. IN DDETA CALC.
DBR = RETARDATION FACTOR IN DDETA CALC.
DBAL = LENGTH OF FLOW IN DDETA CALC.
DBAV = GROUNDUATER VELOCITY IN DDETA CALC. M
DBLA = RADIOL. DECAY COEFF. IN DDETA CALC.
DECN = DECAY CORRECTION FACTOR
DDEIA = DECAY-DISPERSION CORRECTION FACTOR
DECAY = RADIOACTIVE DECAY CONSTANT 1/Y
DOVER = ANNUAL THICKNESS OF TRENCH OVER BURDEN ERODED M
DTRAQ = DISTANCE FROM TRENCH TO AQUIFER H
DUELL = DISTANCE FROM TRENCH TO WELL M
DDETA1 = DDETA FOR VERTICAL TRANSPORT
DDETA2 = DDETA FOR HORIZONTAL TRANSPORT
DERATE = ATMOSPHERIC DEPOSITION RATE
EXPOS = NORMALIZED DOWN WIND ATMOSPHERIC EXPOSURE PER
UNIT SOURCE RELEASE
EXTENT = CROSS SLOPE EXTENT OF SPILLAGE M
ERREST =
FIUIND = FRACTION OF TIME WIND BLOWS TOWARD POPULATION
FI = FRACTION OF YEAR CROPS ARE IRRIGATED
GUV = GROUND WATER VELOCITY M/Y
GNDCON = INSOLUBLE SURFACE SPILLAGE GROUND CONCENTRATION
HTIMt = HORIZONTAL OR AQUIFER TRANSPORT TIME Y
IDELT = INCREMENTAL YEAR FOR PRINTING ANNUAL SUMMARIES
INTY8 = INTERMEDIATE YEARS DURING THE SIMULATION FOR Y
UHICH DOSE & HEALTH EFFECT OUTPUT IS DESIRED
IPRT1 = INITIAL YEAR FOR PRINTING ANNUAL SUMMARIES
IPRT2 = FINAL YEAR FOR PRINTING ANNUAL SUMMARIES
ITIME = TOTAL TRANSPORT TIME FROM TRENCH TO WELL Y
IOPSAT = OPTION INDICATOR FOR CALCULATING LENGTH OF
SATURATED ZONE
IOPVUV = OPTION IDICATOR FOR CALCULATING VERTICAL WATER
VELOCITY
LU2 = LOGICAL UNIT FOR OUTPUT
HAXYR = NUMBER OF YEARS IN SIMULATION
NOFUN = MAXIMUM NUMBER OF FUNCTION EVALUATIONS TO
BE USED BY QUANC8
NYEAR = CURRENT YEAR OF SIMULATION
NONCLD = NUMBER OF NUCLIDES IN SIMULATION
A-3
-------�
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c—
c—
c—
NUCL1D = NUCLIDE NAMES
OVER = TRENCH OVER BURDEN 1HICKNESS H
PC = FRACTION OF TRENCH CAP THAT HAS FAILED
PCON1 = AIR CONCENTRATION CI/MAA3
PCON2 = GROUND SURFACE CONCENTRATION CI/MAA2
PCON3 = COLLECTIVE INGESTION RATE PCI.PER
PCON4 = COLLECTIVE INHALATION PCI.PER
PD = DOUNSLtlPE DISTANCE TO STREAM H
POLE = AMOUNT OF NUCLIDE LEAVING BOTTOM OF TRENCH CI
POLO = AMOUNT OF NUCLIDE OVERFLOWING TRENCH CI
POP = POPULATION
PORS = POSOS1TY OF SOIL
PORT = POROSITY OF TRENCH CONTENTS
PERMS = PERMEABILITY OF SOIL M/Y
QING = ANNUAL INTAKE OF RADIONUCLIDE BY INGESTION
OF CONTAMINATED FOOD CONSIDERING ATMOSPHERIC
AND AQUATIC PATHWAYS PCI/Y
QINH = ANNUAL INTAKE OF NUCLIDE BY INHALATION PCI/Y
QFRAC = FRACTION OF INGESTION DUE TO WATER
RELERR = RELATIVE ERROR FOR DDETA INTEGRATION
RESULT = FINAL FORM OF DDETA CORRECTION FACTOR
RESUL1 = FINAL FORM OF VERTICAL DDETA
RESUL2 = FINAL FORM OF HORIZONTAL DDETA
RETARH = HORIZONTAL RETARDATION FACTOR
RETARV = VERTICAL RETARDATION FACTOR
SOAM •> AMOUNT OF SURFACE SPILLAGE CI
SAREA = AREA OF SPILLAGE HAA2
SDEEP = AMOUNT OF SOLUBLE SURFACE COMPONENT GOING TO
TRENCH CI
STAVG = AVERAGE NUCLIDE CONCENTRATION IN STREAM CI/MAA3
STCON = NUCLIDE CONCENTRATION IN STREAM CI/MAA3
SOILOS - ANNUAL SOIL LOSS DUE TO EROSION
SSTREM = AMOUNT SURFACE COMPONENT GOING TO STREAM CI
SIFLOU = STREAM FLOW RATE MAA3/Y
TRAM = AMOUNT OF NUCLIDE IN TRENCH CI
VD = ATMOSPHERIC DEPOSITION VELOCITY M/S
VOLB = VOLUME OF WATER LEAVING TRENCH BOTTOM MAA3
VOLO = VOLUME OF WATER OVERFLOWING TRENCH HAA3
VOLUSD = HYPOTHETICAL VOLUME OF UATER USED FROM WELL HAA3
VIIME = VERTICAL TRANSPORT TIME Y
VHV = VERTICAL MATER VELOCITY (TRENCH TO AQUIFER) M/Y
WIRAIE = IRRIGATION RATE L/HAA2-
XINFL = ANNUAL INFILTRATION RATE M
XKD = CHEMICAL EXCHANGE COEFFICIENT ML/6
XLSAT = LENGTH OF SATURATED ZONE M
YSO = ATMOSPHERIC SOURCE AMOUNT AT SPILLAGE CI
—OTHER VARIABLES ARE DEFINED IN SUBROUTINES WHERE THEY
-ARE USED MOST FREQUENTLY.
DOUBLE PRECISION NUCLID.DBAV.DEAL.DBR.DBA.DBB.DBD.DBLA.
i FCN.RESULT,ABSERR.RELERR;ERREST.FLAG
DOUBLE PRECISION RESUL1,RESUL2.PNU£ '
COMMON/STREAM/DUS ISINEU
COMMON/CNIRL/NONCLD.MAXYR.TITL£(20).LOCAIE(12),NYftl.NYR2,
t PCT1.PCI2.LEAOPT.lOPVWV.IOPSAI,IPRT1.IPRT2.IDELT,IXIS.
t IRRESl.IRRES2.LIND,IAVGl,IAVG2lRR,FTMECHfINTYR<4Jf RAE1085
8 WUAIL,HWATA,WWATH,SWATL.5WAIA.SWATH.IVAPIIBSMT
COMMON/EVAP/PPNfPHIDfP,XIRRfSfXINFL,SINFL,
A-4
-------�
* SMASS.WMASS.UDEEP
COMMON/TRCH/IAREA.IDEPTH.OVER.PORT, RELFAC,BENCON.OLDUAT.FN
COMMON/UAIER/DTRAQ.DyELL.GW^XLSAIfSTFLOH.AQTHK^QDISP,
g PORA.PORV,PERMV,IAQSTF.CPRJ
COhMON/NUC/NUCLID<40),AIhASS(40).TRAH<40).SOAM<40)fATAM<40).
4 AQAM(40.1000).STAh(40).POLO(40)fPOLB(40).CS(40).CW(46).
I SSTREM<40),SDEEP(40).AIRCON<40),YSO<40),SOAVG<40),CON(40)f
& AQCON(40)fSICON(40),ATCON(40).AQAyG(40)lSTAVG(40).DETU(40)f ISINEUL
S ATAVG(40),FMC(40),FHG(40).DECAY(40).XKD(4.40).SOL(40)f
i FF(40).RA{40>,RW(40).BV(40).BR(40>.BERATEUO)'CUAI(40)
COMMOM/LAND/RAINFfERODF.STPLNG.COVER,CONTRL.SEDELR.SOILOS.
S PORS.BDENSjDWET^XTENTjADEPTHjPD,RUNOFF,RESAI,
COMHON/AIR/CHIQ.CHIQ2.DECOP(40).FACTIM.FTWIND.FTUND2.
i FVOLAT(46).H,HLID.IS,IT,POPDST,POPG,RElfRE2rRE3rRINC,
S RMECH,ROUGHfU,yD,OG.XG
COMMON/DOUBLE/BBAU,BBAL,DBD,DBR,DBLA
COMMON/IRRFOO/Yl.Y2,TEl,TE2.1Hl.TH2.TH3,TH4,TH5,TH6,FPfFS,
& ULEAFY,UPROD'uCMILK.OGMILKfUHEAT UWAT.UAIR,
X QFC,QFG.TF1.IF2.TS.CL1(40).CL2(46),CP1<40),CP2(40),
& CCMIl(40)fCCMI2(40),CGMIl(40),CGHI2<40).
2 CMEAt(40).COLl(40).COL2(40).COPl(40).CaP2(40)f
I COCMIl(40),COCHI2<40>,COGMll(40>,COGfil2<40>,
S COMEAT(40)'QING(40),QINH(40),POPf
& CSP<40).CSPT(40).CSPO(40).CSPOT(40)
COHHON/FUNC/XAflBWE.TA,T«.FI.PP.WIRAIE,
& QCUZQGU.QBU.ABSH.P14
COHHON/PASS/PNUC(40),PCON1(46),PCON2(40),PCON3(40),
& PCON4(40).PPOPFLLINO,LDIST
COMMON/PCV/SOCO^(40)
COMMON/ACCMOD/FICAN(40),CCNR(40),POPB(40),GNR<40),
& TFIC,lCCNR,XPOPDfTGNR
C
COMMON/XP/ARGrRES(10000)
EXTERNAL FCN
DIMENSION II1HE(40).DOETA(40).DECN(40) IS1MOD
DIMENSION DDETA3(40),JTIHE(40),DETUS(40),DEUS(40) ISINEUL
DIMENSION QLB(40.10)>TRAP(40)IQLBPIH(40),HE(40).QLBTTH(40)
DIMENSION NUCL(40.8) NUHBER(11),IDIQ(3),BSHT(40),SAUE(40.21) RAE1085
DIMENSION AQMAX(40),STMAX(40).ATMAX(40).MXAQ(40).MXST(40),MXAI(40)
DIMENSION PC1(40).PC2(40)IPC3(40).PC4(46).NPC1(46),NPC2(40>,
i NPC3(40).NPC4(46).BSMTA(40)tCCNRS<40,4).FICANS(40(4). RAE1085
& GNRS(40.4).HEE(40.4),POPDS(40.4).POSS(46.4)1POyS(40,4)F RAE1085
& QBASIN(40,4),RTAS<40,4),TCCNRS(4),TFICS<4),TGNRS(4>, RAE1085
& TPOPDS(4) RAE1085
DIMENSION QHUSB<40),POW(40).POS(40),PLBT(40),OFr(40),RTA(40)
DIMENSION CIOT(40),CINEUI(46)fUDSIXP(40)
DATA LU2/6/
DATA ISU/0/ 1
DATA MINUS/'-'/
DATA NUMBER/'lV2'.'3V4V5'f'6Vr/V8V9VO'r' '/
CALL ERRSET (208,256,-1,1)
IBK=0
RESAT=0.
DO 11 K-1,10
DO 11 1=1.40
11 QLB(I,K)=0.0
DO 10 1=1.40
QDySB(I)=0.
QLfiPXH(I)=0.0
A-5
-------�
QLBTIH(I)=0.0
POU(I)=0.
POS(1)=0.
PL6I(I)=0.
OFI(I)=0.
RTA(I>=0.
AQAVG=0.0
MXAQ(j)=0
MXST(1)=0
MXAKI)=0
PC1(I)=0.
PC2(1)=0.
PC3(I)=0.
PC4(I)=0.
NPC1(I)=0
NPC2(I)=0
NPC3(I)=0
NPC4U)=0
CSP(I)=0.
CSPT(I)=0.
CSPO(I)=0.
CSPOT(I)=0.
SDE£P(I)=0.
DO 10 NN=1,1000
AQAM(I.NN)=0.
10 CONTINUE
DO 770 1-1.40
770 CIOT(I)=0.6
OLDHAT=0.
ABSERR=1.0D-5
C CI01 IS A VARIABLE TO BE USED IN SUB. LEACH
C INTRODUCED FOR OC111 VERSION (HUNG)
RELERR=1.0D-5
C INITIALIZE VARIABLES AND INPUT CONTROL PARAMETER.
C PRINT OUT INITIAL CONDITIONS.
C
CALL SOURCE(NUCLfCFTl,DCFTfEGAM,lRSTfPERMT,RIGRlSSATfXRTM)
PPOP=POP
LDISI=XG
LLIND=LIND
DO 15 I=1.NONCLD RAE1085
15 PNUC(I)=NUCLID(I) RAE1085
C PRJ=PERCENTAGE OF AQUIFER UAIER FLOWING TO STREAM
PRJ=1.-CPRJ
C THE FOLLOWING EXTRACTS THE ATOMIC MASS FROM THE NUCLIDE
C NAME. THE NUCLIDE NAME MUST CONSIST OF ONE OR TWO LETTERS,
C A MINUS SIGN. AND ONE TO THREE DIGITS. NO IMBEDDED
C BLANKS ARE ALLOWED. THE NAME MUST BE LEFT JUSTIFIED.
C
C
WRITE(LU2,5000)
DO 50 I=1,NONCLD
IE
-------�
IF (RING.EQ.0.0) FVOLAX(I) » 0.0
NDASH=2
IF(NUCL(I,NDASH) .EQ. MINUS) GO TO 20
NDASH=3
20 NNUM=NLlASH+l
DO 30 K=1.3
ICHAR=NUCL
-------�
IF(SSAI .01. 1.) SSAI=1.
72 CONTINUE
URIIE(LU2.1005) SSAT.RESAI
1005 FORHATC DEGREE OF SATURATION =
I ' RESIDUAL SATURATION =
IF(SSAT .GI. 0.0 .AND. SSAI .LT.
XLSAT=DTRAQ
URITE(LU2.6200)
DO 100 I=1,NONCLD
RETARV=l.+lBDENSAXKD(3,I))/PORV
IF(SSAT .GT. 0.0 .AND. SSAT .LT.
VIIH£=DlRAQARETARV/VyV
DDE1A1=1.0
IF (V1IME .GT. 1000. .UR. k'TIML
DBAL=DTRAQ
DBD=.3DOAVHV
DBLA=DECAY(I)
,F6.3./,
'.F6.3)
I.) VWV=TINFL/(PORVASSAT)
1.) RETARy=l.+(RETARV-l.)/SSAT
.GI. bO.A.693/DECAY(D) GO TO 70
DBR=RETARV
DBA=VTIME/10.0DO
DBB=»VTIME
CALL QUANGO (FCN. DBA. DBB, ABSERR,RELERR,RESUL1 ,ERREST,NOFUN, FLAG)
DBA=VTIhE
DBB=VTIMEA10.0DO
CALL QUANC8(FCN, DBA. DBB , ABSERR, RELERR,RESUL2,E8REST,NOFUN, FLAG)
8ESULT=RESULH-RESUL2
DDEIA1=>RESULIADEXP(DBALADBRADBLA/DBAV)
IF(DDEIA1 .LT. 1.0) DDE1A1=1.0
70 RETARH=1.+(BDENSAXKD(4FI))/PORA
HTIME=DWELLARE1ARH/GUV
DDETA2=1.0
IF(HTIME .GT. 1000. .OR. HTIME .GT. 50.A.693/DECAY( I) ) GO TO 80
DBAL=DWELL
DBD=.3DOAGWV
DBAV^GUV
DBR=RETARH
DBA=HTIME/10.0DO
DBB=HTIHE
CALL QUANC8(FCN, DBA, DBB, ABSERR,RELERR.RESUL1 .ERREST.NOFUN. FLAG)
DBA=HTIME
DBB=HTIHEA10.0DO
CALL QUANC8(FCN, DBA, DBB, ABSERR,RELERR,RESUL2.ERREST,NOFUN. FLAG)
RESULT=RESUL1+RESUL2
DDETA2=RESULTADEXP(DBALADBRADBLA/DBAV)
IF
-------�
DBB=HSTIME IS1NEW
CALL QUANC8(FCN.DBA.DBB.ABSERR,RELERR,RESUL1,ERRESI,NOFUN,FLAG) ISINEWL
DBA=WSTIME ISINEWL
DBB=WSTIMEA10.0DO
CALL QUANCB
WRITE(LU2,602)SOILOS,DOVER
WRITE(LU2,603)XINFL
WRITE(LU2,604)VWV
WRITE(LU2,605)EXPOS
300 CONTINUE
C
C CALCULATE AQUIFER VOLUME
AQVOL=GUVAPORAAAQXHKA=EXP(-DECAY(I>A(rfIME(I>+JIIME(I») ISINEWL
999 DEWS(I)=EXP(-DECAY(I)AJTIME(D) ISINEWL
C
C I?IX UP FOR SPEED FOR SUBROUTINE SUSPND
C
CALL XPRESS
C
JYR=1 RAE10S5
DO 1000 N=1,MAXYR
NYEAR=N
AUX=FLOAT(N)
A-9
-------�
INSITE=L4R
IF(N.EQ.1)INSITE=1
TRLS=0.
IE(DUVER -GT. OUER)1RLS=DOVER-OVER
TDEPXH=XDEPIH-TRLS
.IT. 0.)OVER=0.
TDEPIW= TDEPTH-QVER
FONSIT=0.
IF=TRAH( IDAXDECN
CS(II)=CS(II)AXDECN
CW(II)=CU(II)AXDECN
C -----
C ----- CALCULATE THE AMOUNT OF LEACHING.
C -----
CALL LEACH ( II. NYEAR.VOLB. VOLO,DHAX,CIOT,CFF,XDECN,TINFL,PERMT)
PLBT(II)=PLBT(II)+POLB(II)
OFT(II)=OEI(II)+J)OLO(II)
C ----- f
C ----- CALCULATE ADDITIONS TO AQUIFER.
C -----
CALL VERHOR( II. NYEAR. ITIME.DDETA)
C ITMP IS THE YEAR OF ARRIVAL OF POLB AND SDEEP TO A POINT IN ISINEUL
C THE AQUIFER EXACTLY BELOW XHE WELL ISINEWL
ITMP=ITIME(II)+NYEAR
IF(IIHP.LE.IOOO) GO TO 241
C IF R-ACIIVITY POLB AND SDEEP GET TO THE WELL POINT AFTER YEAR ISINEWL
C 1000 NO DECREASE BY WATER COMMUNITY USE IS CONSIDERED IN THE ISINEWL
C CALCULATION OF R-ACTIVITY FLOW FROM THE WELL POINT TO THE STREAM ISINEWL
JTMP=NYEAR+ITIME(II)+JTIME(II) ISINEWL
A-10
-------�
KIN=1NI4-DETWS(II)A(P0LB(im ISICH
8 SDEEP(II))ADDETA
QLBUl,10)=ClLB=AQAM(II.NYEAR>/(VOLUSW)
350 1F(N .GE. IAVG1 .AND. N .LE. 1AVG2)AQAVG(II)=AQAVG<1I)+AQCON
POW ISINEW
KIND=INT(FLOAT(JTMP-1)/1000.) ISINEU
IF(KIND.£Q.O)QDWS6(II)=QBWSB(imD£WS(II>A ISINEW
i (AQAM(I1,NYEAR)-AMX1)ADDEIA3(II) ISINEW
IF(KIND.EQ.O) GU 10 351 ISINEW
IF(KIND.GI.IO) KIND=10 ISINEU
IF(KIND.LT.IO) GO TO 352 ISINEW
QLB(IIf10)=QLB(lI,10)+EXP(-DECAY(II)A(10000-FLOAI(NYEAR)))A ISINEWL
& (AQAM(II,NYEAR)-AMTl)ADD£fA3(II) ISINEW
GO TO 351 ISINEWL
352 QLB(II,KIND)=QLB(II.KIND)+DEWS(II)A(AQAM(II,NYEAfi)-AMTl)A ISINEWL
I DDETA3UI)
351 CONTINUE ISINEWL
C
C CALCULATE TRANSPORT OF SOLUBLE SURFACE COMPONENT
C
CALL SURSOL(Il.NYEAR.VOLO)
IF(NYEAR .EQ. I)SSIREM(II)=STAM(II)+SSfREM(II)
STCON(II)=SSTREM(II)/STFLOW ISIMOD
AMT=VOLUSSASICON(II)
IF(AMI .LE. SSTREM(II) .OR. AMI .EQ. 0.)GO TO 365
STCON(II)=SSTREM(II)/(VOLUSS)
365 IF(N .GE. IAVG1 .AND. N .LE. 1AVG2)STAVG(1I)=STAVG(II)+STCON(II)
IF(STCONdl) .LEa SIMAX(II»GO TO 370
STMAX
-------�
DERATEdl) = 0.0
GNDCUN=CS< 1DABDENSAADEPTHA1.0E3
IFdNSIIE .£Q. 0 .Oil. NYEAR .NE. 1) GO 10 381
D1R=IRAMENCONA1000.A[iECOPAD3RA3.15E7
7778 D1R=D1RAFACIIMA(RMECH+B7R)A3.15E7
IRAMdI)=TRAMdI)-DECOP(II>A(DlR)
IF=RTA(IimSO
-------�
IFdOPVMV .LQ. 1) D1R=D1RABV(II)
384 CONTINUE
SOCGN(II)=1.0E12AADLPlHA
BSMTA(II)=BSMTA(II)A.03333333AFGIM/(TDEPrUATAREA)
QSUR=(CSP(II)+CSPO(II))/1.0E12
TEMP=AICON(II)
IF(PCKII) .GE. TEMP)GO 10 820
PC1(II)=TEMP
NPCKII)=NYEAR
820 CONTINUE
TEMP=QSUR+BSHTA(II)
IF(PC2(II) .GE. XEMPJGO TO 840
PC2(1I)=TEMP
NPC2(II)=NYEAR
840 CONTINUE
TE«P=QING(II)APOP
IF(PC3(II) .GE. TEMP)GO TO 860
PC3(II) = 1VEMP
NPC3(II)=NYEAR
860 CONTINUE
TEMP=(J1NH<1I)APOP
IF(PC4(II) .GE. TEMP) GO TO 880
PC4(II)=IEMP
NPC4(II)=NYEAR
880 CONTINUE
900 CONTINUE
UD=DHAX
IF(WD .GT. TDEP1H)UD=TD£PTH
IF(HOD(NYEAR-IPRTl,IDEL'f> .EQ. 0 .OR. NYEAR .EQ. 1)
& CALL OUI(NYEAR,PC,WD,VOLOrVOLB)
C RAE1085
C CALCULATE AVERAGE NUCLIDE CONCENTRATIONS RAE1085
C AND CALL DARTAB FOR INTERHEDIATE YEARS RAE1085
C RAE1085
IF(NYEAR .NE. IfllYR(JYR)) GO TO 1000 RAE1085
C RAE1085
C SAVE VALUES OF PERTINENT VARIABLES RAE1085
C RAE1085
ISAV1=IAVG1 RAE1085
ISAV2=IAVG2 RAE1085
DO 990 I=1.NONCLD RAE1085
SAVE(Ifl>=CLKI) RAE1085
SAVE(I,2)=CL2(1) RAE1085
SAVE(IF3)=CP1(I) RAE1085
SAVE(1,4)=CP2(I) RAE1085
A-13
-------�
c
c
c
990
c
c
c
992
SAVE(I,5)=CSP(I>
SAVEd,G)=CWAld)
SAVEdF7)=CMEAld>
SAVEdF8)=CCMIld)
SAVEd, 9)=CCHI2d)
SAVEd, 10)=CGMIld)
SAVEd, ll)=C(]MI2d)
SAVEd 12)=COL1(I)
SAVE(I,13)=COL2(I)
SAVEdF14)=COPld)
SAVEd 15)=COP2d)
SAVEd 16)=COCMIld)
SAVEd, 17>=COCMI2d>
SAVEd 18)=COGMIld)
SAVEd 19>=COGMI2d)
SAVEd 20)=COMEATd)
SAVEd 21>=CSPOd)
AQAVG< I)=AQAMGd)/NYEAR
ATAVG(I)=ATAVGd)/NYEAR
SOAVGd)=SOAVG(I)/NYEAR
STAVG(I)=S1AVG(I)/NY£AR
PREPARE CONCENTRATION ARRAYS, PCON, FOR DAR1AB
IAVG2=NYEAR
DO 992 I=1,NONCLD
11=1
DERATEdI)=AXAVG(II)AVDA3.6E15
CALL FOOD
CL2(I)=SAVEd,2)
CPKI)=SAVEd,3)
CP2(I)=SAVEd,4)
CSP(I)=SAVE(I.15)
CWAId)=SAVE(ltG)
CMEAT(I)=SAVE(i,7)
CCMIld)=SAVEd'8)
CCMI2d)=SAVE(I,9)
CGHIKI)=SAVt
-------�
C
C
C
C
C
C
COCMI2(I)=SAVE(I.17)
COGMI1(I)=SAVE(1,18)
COGMI2(I)=SAVE(I,19)
COHEAKI)=SAVE(I.20)
CSPO(I)=SAVE(I.2l)
AQAVG(I)=AQAVGfI)ANYEAR
ATAVG(I)=AIAVG(I)ANYEAR
SOAVG(I)=SOAVG(I)ANYEAR
994 STAVG(I)=STAi;G(I)ANYEAR
IAVG1=ISAV1
IAVG2=ISAV2
CALL DARTAB FOR INTERMEDIATE YEAR OUTPUT
IF(JYR .EQ. 1) CALL DARTAB(O)
CALL DAR1AB(4)
SAVE DATA FOR ACCOUNTING MODEL TABLE
DO 9% 1=1.NONCLD
POSS(I,JYR)=POS(I>
POWS<1,JYR)=POU(I)
RTAS(I.JYR>=RIA(I)
QBASIN(I,JYR)=QDUSB
-------�
c
c -----
C ----- CALCULATE RADIONUCLIDE CONCENTRATIONS IN FOOD DUE TO
C ----- HATER IRRIGATION. ALSO CALCULATE ANNUAL RADIONUCLIDE
C ----- INTAKE BY MAN.
C -----
C
URI1E
DO 1300 I=1,NONCLD
CUAI(lI) = (UUATLAAQAVGWRIIE(LU2,G026>
WRITE(LU2,6030)
DO 1310 I=1.NONCLD
URITE(LU2,6640)NUCLID(I),QING(I)rQINH(I)
1310 CONTINUE
C TABLE OF CUMULATIVE (AGGREGATED) VALUES OF RADIOACTIVITY
C PRODUCED HERE
URITE(LU2.6041)
6041 EORHAK 'I5, 10X, 'AGGREGATED VALUES OF RADIOACTIVITY:',/,
SIX, 'NUCLIDE' 6X, 'PUMPED OUT ',5X. 'PUMPED OUT ',5X.'LEFT BOTTOM',
S5X, 'OVERFLOWED J ,5X, 'RELEASED TO J ,5X 'RELEASED TOV' ',13X.
8' THE WELL '.5X.' THE STREAM'. 5X.' OF TRENCH ',5X,' TRENCH ',
83X,'THE ATMOSPHERE' ,4X,' BASIN')
DO 1313 I=1.NONCLD
URIIE(LU2,6042) NUCL1D( I) ,POU( I) f POS( I) , PLBT( I) ,OFT( I) ,RTA( I) ,
SQDWSB(I)
1313 CONTINUE
6042 tORMATC ' .IX, A8,5X,6( 1PE11.4F5X) )
URI1E(LU2,6045)
C
C -----
C ----- CALCULATE VARIABLES NECESSARY TO PASS TO DARTAB.
C ----- DARTAB COMBINES RADIONUCLIDE ENVIRONMENTAL EXPOSURE
C ----- DATA UITH DOSIMETRIC AND HEALTH EFFECTS DATA TO GENERATE
C ----- TABULATIONS OF PREDICTED IMPACTS.
C -----
C
DO 1320 I=1,NONCLD
QSUR=CSP(I)/1.0Eli2
QFRAC=0. *
FGIM=FGAM
IFdNSIIE.EQ.l .AND. NYEAR.EQ.l) EGI«=EGAMAFACIIMAPOPG/DECOP( I)
BSMT(I>=BSMTA.03333333AFGIM/(IDEPTUATAREA)
IF(QINGU) .EQ. 0.0) GO TO 1315
QFRAC=CUAT( DAUWAT /QING( I)
1315 URIIE(LU2.6050)NUCLID(I),QFRAC
PCON1(I)=ATAVG(I)APOP
PCON2( I)=QSURAPOP+BSMT( I)
PCON3(I)=QING(I)APOP
PCON4(1)=QINH(I)APOP
A-16
-------�
1320 CONTINUE
UmE
DO 1340 I=1.NONCLD
URITL
-------�
c"I" THE EOLLOUING LOOP IS EXECUTED FOR EACH NUCLIDE.
C
DO 50t> I=1,NONCLD
11=1
XDECN=DECN(I1)
TRAM(II)=IRAM(II>AXDECN
CS(II)=CS ISIMOD
210 CONTINUE
C
C CALCULATE TRANSPORT OF SOLUBLE SURFACE COMPONENT
C
CALL SURSOL/1000.)
IF(KIND.GT.IO) KIND=10
C SSTREM IS RADIOACTIVITY FROM SURFACE SUN-OFF
C RELEASED DOWNSTREAM IN MILLENIUM KIND+1
QLB(II,KIND)=QLB(II,KIND)+SSTREM(II)
C CALCULATE ATMOSPHERIC CONCENTRATION AND AMOUNT
C ABOVE SPILLAGE AREA
C
C
GNDCON=CS(II)ABDENSAADEPIHA1.0E3
CALL SUSPND(NYEAR.II,D1R,GNDCON,D7R,D8R)
RTA(II)=RTA(II)+YSC(II)A3.1536E7
387 CONTINUE
C
C
C MATERIAL BALANCE
C
C
C 3.1536E7 IS THE NUMBER Of SECONDS IN A YEAR
CS(II)=CS(II)+((TRLS/(TDEPTH+TRLS)ATRAM(II)-YSO(II)A3.1536E7)/
1 (EXTENIAPDAADEPTH))A1.0E-3/BDENS
TRAM(II)=TRAM(II)A(1.0-TRLS/(TDEPTH+TRLS))
RELIS = RELFAC
IF (RELFAC.LT.0.0) RELIS = XKD(2,II)
A-18
-------�
IF(LEAOPT.EQ.5 .AND. DMAX.GT.O. )IRAMdI) = TRAMdI)A< 1-RELIS) ISIMOD
IF(LEAOPT.NE.5)TRAM(II)=XRAM(II)-POLB(II)-POLO(II)
IF(TRAMdl) .LI. 0.)TRAMdI)=0.
CWdI) = CWdI) + (POLOdI>/
8 (EXTENTAPBAADEPIHAPORS))
IF(CWdl) .LI. 0.) CW(II)=0.
IF(CSdl) .LI. 0.)CSdI)=0.
C
C COMPUTE SOIL CONCENTRATION
C
D1R=0.
IFdOPVUV .LI. 0) GO 10 388
IFdRSI .LI. N .AND. 1DEP1H .61. 0.) DlR=FONSIIAIRAMdI)/
I (TAREAATDEPTW)
IFdOPVWV .EQ. 1) DlR=DlRABVdI)
388 CONTINUE
SOCONdI) = 1.0E12AABEPTHA
C
505 CONTINUE
WD=DMAX
IF(WD .GT. IDEPIH)WD=TDEPTH
C IF(MOD(NYEAR,1000).EQ.O .OR. NYEAR.EQ.1001)
C i CALL THSUM(
1001 CONTINUE
C QLBPTH IS THE AMOUNT OF RADIOACTIVITY LEAVING
C THE BASIN WITH THE STREAM WATER BETWEEN YEARS
C 1001 AND 10000
DO 506 II=1.NONCLD
DO 250 L=I,9
250 QLBPlHdI)=QLBPIHdmQLBdI.L>
C FIRST MILLENNIUM RELEASE INCLUDED FOR HEALTH EFFECTS CALC.
QLBTTHdI)=QLBPTHdI)+QDWSBdI)
506 CONTINUE
C HE IS THE HEALTH EFFECT CALCULATED USING CONVERSION FACTOR CON
DO 270 L=1,NONCLD
270 HE(L)=QLBITH(L)ACON(L)
C
C OUTPUT FOR THE EXTENDED SIMULATION PERIOD IS PRODUCED
C IN DO LOOP 1004. DO LOOPS 1007 AND 1010 REPORT THE HEALTH
C EFFECTS FROM THE RESIDUAL RELEASE DOWNSTREAM THE BASIN
C
URIIE(6,1002)
1002 tORMAT(Il/,32X,'RESIDUAL RADIOACTIVITY RELEASED ',
& 'OUTSIDE THE BASINV43X,'WITH THE STREAM WATER'//' '.
g 'NUCLIDE'.5X,'FIRST'.6X,'SECOND',5X,'THIRD',6X,'FOURTH' 5Xr
I 'FIFTH',5X.'SIXTH'6X 'SEVENTH',4X.'EIGHTH',5X,'NINTH',6X,
& 'TENTH'/' J.10X,10('MILLENNIUM'f1X),/)
DO 1004 I=l.NONCtD
1004 WRIIE(6,1003) NUCLIDd),QDWSBd),
-------�
& 32X 'RADIOACTIVITY RELEASED IN ',15 ' YEARS'.//.30X,
& 'NUCLIDE'.5X.'RESIDUAL' 3X.'CONVERSION',3X,'HEALTH',/,42X,
i 'ACTIVITY*5X.'FACTOR',5X,' EFFECTS',/)
DO 1410 I=1.NONCLD
1410 WRITE(6,1008> NUCLID,CON(I),HEE(I,J)
1420 CONTINUE
WRITE(b,100G)
1006 EORMAT(////.32X 'HEALTH EFFECTS RESULTING FROM RESIDUAL',/,
42X,
& 32X,'RADIOACTIVITY RELEASED IN 10000 YEARS'.//.30X.
& 'NUCLIDE' 5X'RESIDUAL'3X.'CONVERSION',3X,'HEALTH7,/,
& 'ACTIVITY' 5X 'FACTOR',5X,'EFFECTS',/)
DO 1007 I=1,NONCLD
1007 URIIE<6,1008) NUCLIDtI).QLBTIH,I=i,6)
1009 FORHAT(/1'.///.30X.'TABLE FOR ACCOUNTING HODEL — YEAR ',15,
imni \ x f///favAf xnvjuLi i. un FILTWWWI^XAITU tiwut* j
/,' COLUHN I: INDIVIDUAL CANCER RISK (UNItLESS)',
/!' COLUhN 2: POPULATION DOSE (PERSON-REM/YtAR)''
/,' COLUHN 3: COLLECTIVE CANCER RISK (DEATHS/YEAR)',
/,' COLUHN 4: GENETIC RISK (EFFECTS/YEAR)'
& /,' COLUHN 5: R-ACTIVITY PUHPED OUT THE WELL 1ST ',15,
i
YEARS (CI)',
/.' COLUMN 6: R-ACIIVIIY PUMPED OUT THE STREAM 1ST ',15,
'YEARS (CI)',
/,' COLUMN 7: R-ACIIVIIY RELEASED TO AIHOSPHERE 1ST ',15,
' YEARS (CI)'
I /,' COLUHN 8: R-ACT1VIIY RELEASED DOWNSTREAM 1ST '15,
' YEARS (CI)'
/,' COLUMN 9? R-ACIIVIIY RELEASED DOWNSTREAM LAST ',15,
' YEARS (CD '
/.' COLUMN 10? R-ACIIVIIY IN TRENCH AFTER 10000 YEARS ',
'ASSUMING PERFECT CONTAINMENT (CI)',/)
DO 1010 I=1,NONCLD
QLASI=QDWSB(I)-QBASIN(1,J)
QLASI=QLAST+QLBPTH(I)
WRI1E(6.1011) NUCLID(I),EICANS(I,J),POPDS(I.J),CCNRS(I.J).
* GNRS(IfJ),POUS(I,J),POSS(I,J),RIAS(I,J>,QBASIN(I,J),QLAST,
i IRAPdJ
UBIIE(14r1011) NUCLID(I),FICANS(I,J),POPDS(I.J),CCNRS(I,J),
S GNRS(I.J),POWS(I,J),POSS(I,J),RTAS(I,J),QBASIN(I,J),QLAST,
1010 CONTINUE
URIIE(6.1012) TFICS(J).TPOPDS(J).TCCNRS(J),TGNRS(J)
WRITE(H.1012i TFICS(J),TPOPDS(a5,TCCNRS(jJ,TGNRS(J)
1011 FORHAT(1X,A8.1X.1P10E11.4)
1012 FORMAKIX,'TOTALS:',2X,1P4E11.4)
1020 CONTINUE
1003 FORHATC ',A8,2X,12(PE10.4.1X))
STOP '
RAE1085
RAE1085
RAE1085
RAE1085
RAE1085
RAE1085
RAE1085
RAE1085
RAE1085
RAE1085
RAE1085
RAE108S
RAE1085
RAE1085
RAE1085
RAE1085
RAE1085
RAE1085
RAE1085
RAE1085
RAE1085
RAE1085
RAE1085
RAE1085
RAE1085
WA, nun x^unxnij t-JA, uutin , JA. oncnrv innu .
/' SllX.'RETARfiAIION'.SX/TlHE Y', 7X,'DDEIA',5X,
A-20
-------�
i 'RETARDATION',4X.'TIME Y',8X,'DDETA',21X,'TIME Y')
6210 FORMATC ',A8,3Xr9(lPEll.4,2X))
6215 FORMATC ' A8!3x'3(2(lPE11.4,2X).OPI4.5X))
6220 FORMAT*/' ' 5X,'&ADIONUCL1DE BREAKTHROUGH TIME IS ONLY SLIGHTLY',
I ' GREATER THAN SIMULATION TIME AND LEADING EDGE OF PULSE',
* ' MAY BE MISSED')
602 FORMAT*//' ',10X 'ANNUAL SOIL LOSS IS '.1PE11.4,' KILOGRAMS PER',
I ' SQUARE METER',/' ',20X,'OR ',£11.4,
t ' MEIERS IS REMOVED FROM THE SURFACE7)
603 FORMATC ',10X,'ANNUAL INFILTRATION INTO TRENCH IS ',
& F8.4,' METERS')
604 FORMATC ''lOX.'VERTICAL WATER VELOCITY IS ',F8.4,' METERS',
t ' PER YEAR')
605 FORMAT*' ',10X.'NORMALIZED DOWN WIND ATMOSPHERIC EXPOSURE',
I ' PER UNIT SOURCE RELEASE IS 'Ell.4 ' CI/MAA3 PER CI/SEC')
615 FORMAT*//' ' 5X.'WATER OUTFLOW FROM TRENCH BOTTOM IS APPROACHING',
I ' DILUTION VOLUME IN AQUIFER FOR YEAR ',14)
700 FORMATC1',35X 'AVERAGE CONCENTRATIONS OVER THE YEARS ',13,
\ ' TO ',14,' OF THE SIMULATION'
i /' '.50X 'MAXIMUM ANNUAL CONCENTRATIONS'
i ///' 'IX,'NUCLIDE',8X,'ATMOSPHERE DOWNWIND',
I 24X,'IN WELL',26X 'IN STREAM',
i //' ',7X,3(6X 'AVERAGE' 6X 'MAXIMUM',4X,'YEAR',IX),
S /' ' 7X,3*2*6Xf'CI/MAA3J),9X))
5000 FORMATC1'.SlX 'INITIAL CALCULATIONS',//' ' ,50X,'NUCLIDE',
i 10X 'MASS' //)
5005 FORMAT!' ' SIX.AB.SX.FS.O)
5006 FORMAT*' ',bX,JIH£ POPULATION RESIDES ONSITE')
5007 FORMATC ',5X.'POPULATION RESET TO ' F10.0,' FOR ONSITE FARM')
6000 FORMAT*'!'130X,'RADIONUCLIDE CONCENTRATION IN FOODS DUE TO'
S_^_ATMgSPHERIC DEPOSITION'f/''z55X,'PICO_CURIES_PER KILOGRAM')
1
L
4 / fit A, n.l.b. ,'A, ll.l.Li. ./A,^\ <
8 7X 'G P t ' 7X 'M 1 E ' 7X 'G P E ')
6010 FORMAT*/^//' J.35X 'ftADiONUCLiDE'CONCENXRAIION IN FOODS DUE TO'
s ' IRRIGATION'/' ',55x,'pico CURIES PER KILOGRAM')
6020 FORMAT*///' ',5X 'NOTE: G.P.E. - GENERAL POPULATION',
S ' EXPOSURE' /' J,11X,'M.I.E. - MAXIMUM INDIVIDUAL',
X ' EXPOSURE')
6024 FORMAT*'0'.11X,'M. I.E. WILL BE USL'D 10 CALCULATE',
& ' HEALTH EFFECTS')
6026 EORMATCO' HX.'G.P.E. WILL BE USED 10 CALCULATE',
& ' HEALTH EFFECTS')
6030 EORMATC1',IX.'NUCLIDE',10X/ANNUAL INTAKE',10X,
& 'ANNUAL INTAKE'/' '
& 18X 'BY INGESIION',11X,'BY INHALATION'/' ',20X,
& 'PCI/Y',18X 'PCI/Y')
6040 FORMAT*' ' ,1X.A&,9X.1PE11.4,12X,1PE11.4)
6050 FORMATC ' ,50X,A8,8X,F8.4)
6045 EORMATCl'.SOX.'FRACTION OF INGESTION DUE TO WATER',
S //' '.50X,'NUCLIDE',10X.'FRACTION')
6300 FORMAT*J1',55X.'MAXIMUM ANNUAL EXPOSURE'
t ///.2X,'NUCLIDE'.12X,'AIR'.8X,'YEAR' 8X,
S ' SURFACE'.6X,'YEAR',7X,'INGEST ION',5X,'YEAR',6X,
i 'INHALATION' 5X.'YEAR'
S /' ',15X,2CCONCENIRA1ION',12X),5X,
& 2CRATE',19X),
t /' /,18X,'CI/HAA3/f18X,'CI/MAA2',
A-21
-------�
6310
C
C
C
C
16X,2('PKRSON.PCI/Y',12X>/)
FORMAT*' *, A8,8X , 4( 1PE11 .4, 4X, OPI4 ,GX) )
END
C
C
C
XPRESS
COMMON/AIR/CHIQ.CHIQ2.DECOP<40),FACTIM,FTUINp,FTUND2,
I FVOLAT(46).H.HLID. IS, IT,POPDST,POPG,RE1 ,RE2,RE3,RINC;
i RMECH.ROUGH,U,VD,VG,XG
COM«ON/LAND/$AINF,ERODF,STPLNG. COVER, CONTRL.SEDELR.SOILOS,
1 PORS,BDENS,DWET, EXTENT, ADEPTH,PD, RUNOFF, RESAT,
& INSITE
COMHON/XP/ARG,RES( 10000)
CALCULATION FOR USE IN SUBROUTINE SUSPND
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
200
DO 200 IYR=1. 10000
TX = FLOAI(IYR)A365.
RES(IYR) = RE1AEXP
-------�
C XG =GAUGE DISTANCE FROM SOURCE BASE, M
COMMON/AIR/CHia.CHIQ2.LitCOP(40).FACTIM.FIWIND.FTWND2,
t FVOLAT(46),H,HLID.IS, IT,POPDST,POPG,RE1,RE2,RE3,RINC,
t RMECH,ROUGH,U,VD,VG,XG
C TEST FOR INVALID COMBINATIONS OF IS AND IT:
36 IF(IS.LT.1.OR.IS.GT.6)WRITE(6,38)IT.IS
IFIT,IS
38 FORMAK2X 'INVALID COMBINATION OF IT=',I2,'JNB IS=',I2)
C INITIALIZE PARAMETERS
PI=3.141593
IF(HLlD.fcQ.O.)HLID=12000.
XG = XG + EXIENI/0.3978247
LID=HLID
IXG=XG
C ACCOUNT FOB PLUME TILT
HH=H-VGAXG/U
IF(HH.LI.O.)HH=0.0
C COMPUTE PLUME WIDTH FACTORS AT DISTANCE XG
CALL SIGMAZtXG.ir.IS.ROUGH,SIGZ, IKPM.HLID,VG,U,HH)
C RESTRICT HLID TO IROfOPAUSE IF INPUT SPEC. =0.0
C COMPUTE CORREC1ION FACTOR FOR PLUME DEPLETION
C
COR=1.
IF(MG.EG.O..AND.VD.EQ.O.)GOT045
CALL DPLT(PI,HH,VD,UrIT,IS,XG,ROUGH,HLID,COR,VG,H)
C
C IF(COR.LT..999)WRITE(6,40) COR
40 FORMAK2X,'DEPLETION CORRECTION FACTOR =',F8.4)
45 EXPO=EXP(-HHAHH/2./SIGZ/SIGZ)
C COMPUTE SECTOR AVERAGE VALUES
EXPN=CORA2.032AEXPO/SIGZ/XG
EXPOS=EXPN/U
DEPO=EXPOSAVD
80 CONTINUE
1000 CONTINUE
RETURN
END
C
C
SUBROUTINE DPLKPI.HH, VD.U. It, IS,XG,ROUGH,HLID,COR, VG,H)
COMPUTES PLUME DEPLETION CORRECTION
DIMENSION XX(50).FX(50).AX(50)
COMHON/C/BY(6>,BZ1{6).BZ2(&>,BZ3.A2(6>,BI(G>,B2(G),
S B3(6),PY(6.5)'PZ(G,5),QY(G,5),QZ(Gf5),XM(50)
IFdS.GT.6)15=6
IKPM=1
IDUM=1 l
CALL SIGMAZ(XG.11,IS,ROUGH,SIGZ,IKPM,HLID,VG,U,HH)
C IKPM HAS BEEN RECOMPUTED
IKP=1KPM-H
SQRTPI=.79785
FX(IKP)=EXP(-.5A(HH/SIGZ)AA2)/SIGZ
XX(IKP)=XG
DO 20 1=1,IKPM
CALL)SIGMAZ(XX(I)fII.IS|ROU6H.SIGZ,IDUM,HLIDfV6,UfHH)
FX
-------�
L=l
CALL SIMPUN.PY(6,5),PZ(6.5)lQY(6,5>.Q2(&,5>fXM(50>
DIMENSION A6NE(6),B6NEf6),Afuo(6),BTUO(6),CONE(6),DONE<6),
*CTUO(6).DTUO(6>,RGH<6>
DATA AONE/0.112.0.130.0.112.0.098.0.0609,0.06387
DATA BONE/1.06,6.950,0.920,6.889.6.895,0.783/
DATA ATWO/5.38E-4,6.52E-4.9.05E-4,1.35E-3,1.96E-3,1.36E-3/
DATA BTWO/0.815.0.750,0.718.0.688.0.684,0.672/
DATA CONE/1.56,2.02.2.72.5.16,7.37,11.7/
DATA DONE/0.0480.0.0269,6..-0.060,-0.0957,-0.128/
DATA CIHO/6.25E-4,7.76E-4,0.,186.,4.29E+3,4.59E+4/
DATA DIWO/0.4S.0.3y.O..-0.225.-0.60.-0.78/
DATA RGH/0.01,0.04,0.10,0.40,1.0,4.6/
P=0.0
DO 8 1=1,50
IKP=I
IF(XM>
GO TO 27
26 F=F-ALOG(1.+C2AXGAAD2)
27 SIGZ=GAF
IF(SIGZ.LI.l.O) SIGZ=1.0
GOT099
C BRIGGS DISPERSION VALUES. FROM AIRDOS II
30 SIGZ=BZ1(IS)AXGA(H-BZ2(IS)AXG)AABZ3(IS)
GOI099
C DISPERSION VALUES AFTER KLUG, AND OTHERS
40 J=II-3
A-24
-------�
C =1 FOR KLUG
C =2 FOR BROOKHAVEN
C =3 FOR SI. LOUIS
C =4 FOR JULICH(SOH)
C =5 FOR JULICHUOOM)
SIGZ=PZ
-------�
C EXTRAPOLATION CAN OCCUR, IEX=-1 OR
C
C
DIMENSION X<1),Y(1)
IND=IND1
N=N1
IEX=0
IF (N.LE.IMAX) GO TO 10
N=IMAX
IEX=N
10 IE (IND.GT.O) GO 10 40
DO 20 J = l.IMAX
IF (Xl-X(J)) 30,130,20
20 CONTINUE
IEX=1
GO TO 70
30 IND=J
40 IF (IND.GT.l) GO TO 50
IEX=-1
50 INL=IND-
-------�
I B3/.1475
3/.1475,.0168,.0045,.0022,-.042,-.Ob5/
FOR KLUG, ET. AL. TYPES OF DISPERSION...
DATA PY/.469,.306..23..219,.23?,.273,0.,.4,.36,.32,.0,.31,
i .0.1.7.1.44,.91,1.02,.6..66,.66,.63,.53,.41,7.56,
ft .34,.37..40..43).46,7.56/
DATA GY/.903,.885..855..764,.691,.594,0.,.91,.86,.78,.0,.71,
I 0...717,.71,.729,.648,.6,.83,.83,.80,.80,.87,.52,
ft 1.6o..94,.a6,.82'.?6..52/
DATA PZ/.017,.072,.076,.14,.217,.262,.0..411,.326,.223,.0,
ft .063,.0..079 '131,.91,1.93,.0,.14,.14,.21,.26,.13,.56,
ft .037..076..16,.32,.66,1.37/
DAlA QZ/I.38 1.021..879..727,.61..5,.0,.90'/,.859,.776,.0,.709,
ft .0.1.2.1.046,.702,.465,.6,1.09,1.09,.98,.89,.83,.55,1.28,
ft l.h..$6,.88 .63,l47/ ' ' ' ' '
DATA XH/
ft 1.000E+00,2.000E+00,3.000E+00,4.000E+00,5.000E+00,
ft 1.000E+01,1.500E+01,2.000E+01,2.500E+01,3.000E+01,
ft 3.500E+01,4.000E+01,4.500E+01,5.000E+01,1.500E+02,
ft 2.000E+02,3.000E+02,4.000E+02,5.000E+02,6.000E+02,
ft 7.000E+02,8.000E+02,9.000E+02,1.000E+03,1.100E+03,
ft 1.200E+03,1.300E+03,1.400E+03,1.600E+03,1.800E+03,
ft 2.000E+03,2.500E+03,3.000E+03,3.500E+03,4.000E+03,
ft 4.500E+03,5.000E+03,6.000E+03,7.000E+03,8.000E+03,
ft 1.000E+04,1.500E+04 2.000E+04 3.000E+04 4.000E+04
ft 5.000E+04,6.000E+04,7.000E+04,8.000E+04,1.000E+05/
END
C
C
C
FUNCTION CAP(NYEAR)
C
C
CAAA
CAAA
CAAA THIS FUNCTION CALCULATES AND RETURNS THE FRACTION OF THE TRENCH
CAAA CAP THAT HAS FAILED. FAILURE CAN BE CAUSED BY EROSION AS
CAAA DETERMINED FROM THE UNIVERSAL SOIL LOSS EQUATION OR BY USER
CAAA INPUTS. CAP=1 INDICATES TOTAL CAP FAILURE. THIS FUNCTION
CAAA IS CALLED BY TRENCH.
CAAA
CAAA
CAAA
CAAA
CAAA
CAAA
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
INPUT VARIABLES
NYEAR = CURRENT YEAR OF SIMULATION
NYR1 = FIRST YEAR OF FAILURE
NYR2 = LAS1 YEAR OF FAILURE
PCT1 = PER CENT FAILURE IN NYR1
PCI2 = PER CENT FAILURE IN NYR2
OVER = THICKNESS OF TRENCH CAP
OUTPUT VARIABLE
CAP = FRACTION Ot CAP 1HAI HAS FAILED
A-27
-------�
DOUBLE PRECISION NUCLIB
COHHON/CNIRL/NONCLll.HAXYR,TITLE<20).LOCATE<12).NYRl.NYR2,
& PCT1.PCI2.LEAOPT.IOPVUV.IOPSAT,IPRT1.IPRT2.IDELT.IXIS,
i IRRE$l,IRfaS2.LIND,IAVGl,IAVG2;RR,FTftECH,INIYR<4), RAE1085
J UyAIL,&UAIA,UHATH,SUATL,SWAIA,SUAIH,IVAP,IBSMT
COHHON/IRCH/fAREA,fDEPTH,OVER,PORT,RELFACFDENCON,OLDWAI,FN
CAP=0.0
IF
-------�
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
MEAT CONSUMED BY MAN RESULTING FROM ATMOSPHERIC DEPOSITION
CALLED BY MAIN.
INPUT VARIABLES
NN = NUCLIDE NUMBER
DECAY = RADIOACTIVE DECAY CONSTANT 1/Y
XAMBUE = WEATHER DECAY CONSTANTS 1/H
AIRBORNE MATERIAL
TA = PERIOD OF TIME FOR WHICH SOIL IS EXPOSED TO THE
CONTAMINATED AIRBORNE MATERIAL H
PP = SURFACE DENSITY FOR SOIL KG/HAA2
RA = RETENTION FRACTION
BV = CONCENTRATION FRACTION FOR UPTAKE OF RAOIONUCLIDE
FROM SOIL BY VEGETATIVE PARTS OF CROPS
BR = CONCENTRATION FRACTION FOR UPTAKE OF RADIONUCLIDE
FROM SOIL BY REPRODUCTIVE PARTS OF CROPS
DERATE= RADIONUCLIDE DEPOSITION RATE PCI/MAA
IOPT = OPTIONS FOR SPECIALS RADIONUCLIDES H-3 AND C-14
IOPT = 1 IF H-3 AND C-14 IS NOT INCLUDED IN THIS RUN
IOPT = 2 IF ONLY H-3 IS INCLUDED
IOPT = 3 IF ONLY C-14 IS INCLUDED
IOPI = 4 IF BOTH ARE INCLUDED
Yl = AG PRODUCTIVITY FOR GRASS CONSUMED BY ANIMALS KG/MAA2
Y2 = AG PRODUCTIVITY FOR VEGETATION CONSUMED BY MAN KG/MAA2
TE1 = TIME PASTURE GRASS EXPOSED DURING GROWING SEASON H
TE2 = TIME CROP/VEG EXPOSED DURING GROUING SEASON H
TH1 = PERIOD DELAY BETWEEN HARVEST OF PASTURE GRASS
AND INGESTION BY ANIMALS H
TH2 = PERIOD DELAY BETWEEN HARVEST OF STORED FEED AND
1NGESI10N BY ANIMAL H
TH3 = PERIOD DELAY BETWEEN HARVEST OF LEAFY VEG AND
1NGESI10N BY MAN FOR MAXIMUM INDIVIDUAL EXPOSURE H
TH4 = PERIOD DELAY BETWEEN HARVEST OF PRODUCE AND
INGESTION BY MAN FOR MAXIMUM INDIVIDUAL EXPOSURE H
TH5 = TIME DELAY BETWEEN HARVEST LEAFY VEG AND
INGESIION BY MAN FOR GENERAL POPULATION EXPOSURE H
TH6 = TIME DELAY BETWEEN HARVEST OF PRODUCE AND
INGESIION BY MAN FOR GENERAL POPULATION EXPOSURE H
FP = FRACTION OF YEAR THAT ANIMAL GRAZE ON PASTURE
FS = FRACTION OF DAILY FEED THAT IS FRESH GRASS WHEN
ANIMALS GRAZE ON PASTURE
FMC = FRACTION OF THE COW'S DAILY INTAKE OF
RADIONU1LIDE WHICH APPEARS IN EACH LITER OF MILK D/L
EMG = FRACTION OF THE GOAT'S DAILY INTAKE OF
RADIONUCLIDE WHICH APPEARS IN EACH LITER OF MILK D/L
QFC = AMOUNT OF FEED CONSUMED BY CATTLE KG/D
QFG = AMOUNT OF FEED CONSUMED BY GOATS KG/D
IF1 = TRANSPORT TIME OF RADIONUCLIDE FROM
FEED-MILK-RECEPIOR FOR H.I.E. H
IE2 = TRANSPORT TIME OF RADIONUCLIDE FROM
FEED-MILK-RECEPTOR FOR G.P.E. H
FF = FRACTION OF THE ANIMAL'S DAILY INTAKE OF
RADIONUCLIDE WHICH APPEARS IN EACH KG OF FLESH D/KG
A-29
-------�
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
IS = TIME FROM SLAUGHTER OF MEA1 10 CONSUMPTION
ABSH = ABSOLUTE HUMIDITY OF THE ATMOSPHERE
P14 = FRACTIONAL EQUILIBRIUM RATIO FOR C-14
INTERMEDIATE VARIABLES
XAMBEF= EFFECTIVE DECAY CONSTANT
CPAST = NUCLIDE CONC IN PASTURE GRASS CONSUMED BY ANIMALS
CSTO = NUCLIDE CONC IN STORED FEED CONSUMED BY ANIMALS
CFEED = RADIONUCLIDE CONCENTRATION IN ANIMALS'S FEED
H
G/MAA3
OUTPUT VARIABLES
CL1 = RADIONUCLIDE
FOR M.I.E.
CL2 = RADIONUCLIDE
FOR G.P.E.
CP1 = RADIONUCLIDE
FOR M.I.E.
CP2 = RADIONUCLIDE
FOR G.P.E.
CCMI1 = RADIONUCLIDE
CCHI2 = RADIONUCLIDE
COMI1 = RADIONUCLIDE
CGMI2 = RADIONUCLIDE
CMEAI = RADIONUCLIDE
CONC IN LEAFY VEG CONSUMED BY MAN
CONC IN LEAFY VEG CONSUMED BY MAN
CONC IN PRODUCE CONSUMED BY MAN
CONC IN PRODUCE CONSUMED BY MAN
CONC IN COW'S MILK FOR M.I.E.
CONC IN COW'S MILK FOR G.P.E.
CONC IN GOAT'S MILK FOR M.I.E.
CONC IN GOAT'S MILK FOR G.P.E.
CONC IN BEEF CATTLE'S MEAT
PCI/KG
PCI/KG
PCI/KG
PCI/KG
PCI/L
PCI/L
PCI/L
PCI/L
PCI/KG
DOUBLE PRECISION NUCLID.H3.C14
COMMON/NUC/NUCLID<40).ATMASS(40).TRAM(40).SOAM(40).ATAM(40).
& AQAH(40I1000>,STAM(40>,POLO(40>,POLB(40>.CS(40).CU<4&>.
g SSTREM(40).SDEEP(40).AIRCON(40),YSO(40)TSOAVG(46),CON(40).
I AQCON(40),STCON(40),ATCON(40).AQAVG(40).STAVG(40)IDETW(40), ISINEUL
S ATAVG(40);FMC(40).FHG(40),DECAY(40),XKD(4f40).SOL(40)f
& FF(40)fRA(40),RW(40),BV(40),BR(40).DERATE(40).CUAT(40)
COMMON/IRRFOO/Y1.Y2,TE1,TE2.TH1.TH2.TH3,TH4.TH5,THG,FP,FS,
S ULEAFY,UPROD,UCMILK.UGMILK,UMEAI.UWAI.UAIR,
& QFC,QFG.TF1,TF2.TS.CL1(40).CL2(46),CP1(40),CP2(40),
* CCMI1(46),CCHI2(40).CGMI1(40),CGMI2(40),
S CHEA1(40).COL1(40).COL2(40).COP1(40).COP2(40),
t COCHIl(40)fCOCMI2(40).COGMIl(40),COGMI2(40),
* COMEAT(40)!QING(40).QINH(40),POP'
& CSP(40).CSPT(40).CSPO(40).CSPOT(40)
COMMON/FUNC/XAMBUE.IA.T&I.EI.PP.WIRATE,
& QCU,QGU,GBU,ABSR.P14
DATA H3/8HH-3 / C14?8HC-f4 /
DECA=D£CAY(NN)/8760.
IF(NUCLID(NN) .EQ. H3) GO TO 200
IF(NUCLID(NN) .£17. C14) GU TO 300
CALCULATION OF CPASI= RADIONUCLIDE CONCENTRATION IN PASTURE GRASS
CONSUMED BY ANIMALS
100 B=0.243ABV(NN) RAE0186
CPAST=CV(NN.Y1.IE1.TH1,B,1.)
CALCULATION OF CSlO = RADIONUCLIDE CONCENTRATION IN STORED FEED
CONSUMED BY ANIMALS
B=0.068A<0.378ABR
-------�
CAAA CALCULATION OF CLX = RADIONUCLIDE CONC IN LEAFY VEG CONSUMED
C BY MAN
B=0.066ABV(NN) RAL018G
CAAA 1. FOR MAXIMUM INDIVIDUAL EXPOSURE
CL1(NN)=CV
C
CAAA 2. FOR GENERAL POPULATION
CP2(NN)=CV(NN,Y2,IE2,TH6,B,0.1)
CAAA CALCULATION OF CCMIX = RADIONUCLIBE CONCENTRATION IN COW'S MILK
CAAA 1 FOR MAXIMUM INDIVIDUAL EXPOSURE
CCM1](NN)=FMC(NN)ACFEEDAQFCAEXP(-DECAATF1)
C
CAAA 2 FOR GENERAL POPULATION
CCHI2(NN)=FMC(NN)ACEEEDAQFCAEXP(-DECAATF2)
C
CAAA CALCULATION OF CGMIX = RADIONUCLIDE CONCENTRATION IN GOAT'S MILK
C 1 FOR MAXIMUM INDIVIDUAL EXPOSURE
CGMI1(NN)=FMG(NN)ACFEEDAQFGAEXP(-DECAATF1)
C
CAAA 2 FOR GENERAL POPULATION
CGMI2(NN)=FMG(NN)ACFEEDAQFGAEXP(-DECAATF2)
C
CAAA CALCULATION OF CHEAT = RADIONUCLIDE CONCENTRATION IN BEEF CATTLE
CHEAT(NN)=FF(NN)ACEEEDAQFCAEXP(-D£CAATS)
RETURN
C
CAAA CALCULATION FOR SPECIAL RADIONUCLIDE: TRITIUM
C
CAAA CALCULATION OF CVS = TRITIUM CONCENTRATION IN ALL VEGETATION
200 CV3=3.75E14AAXAVG(NN)/ABSH
CAAA CALCULATION OF CONCENTRATION OF TRITIUM IN VEGETATION, MILK,
CAAA AND MEAT CONSUMED BY MAN
CL1(NN)=CV3
CL2(NN)=CV3
CPKNN)=CV3
CP2(NN)=CV3
CCMI1(NN)=FHC(NN)ACV3AQFC
CCMI2(NN)=CCMI1(NN)
CGMI1(NN)=FMG(NN)ACV3AQFG
CGMI2(NN)=CGMI1(NN)
CMEAT(NN)=FF(NN)ACV3AQFC
RETURN
C
CAAA CALCULATION FOR SPECIAL RADIONUCLIDE: CARBON-14
C
CAAA CALCULATION OF CV14 = C-14 CONCENTRATION IN ALL VEGETATION
300 CV14=6.875£14AATAVG(NN)AP14
CAAA CALCULATION OF C-14 CONCENTRATION IN VEGETATION, MILK,
CAAA AND MEAT CONSUMED BY MAN
CL1(NN)=CV14
A-31
-------�
CL2(NN)=CV14
CP1(NN)=CV14
CP2(NN)=CV14
CCMI1(NN)=FMC(NN)ACV14AQFC
CChI2(NN)=CCMIKNN)
CGMI1(NN)=FMG(NN)ACV14AQFG
CGhI2(NN)=CGMIl(NN)
CMEAT(NN)=FF(NN)ACV14AQFC
RETURN
END
C
C
FUNCTION CVSTCON(40).ATCON(40).AQAVG(40).STAVG(40).DETW(40), ISINEUL
S ATAVG(40).FMC(40).FHG(40).DECAY(40).XKD(4140),SOL(40).
J FF(40).RA(40),RW(40).BV(46).BR(40).DERATEUO).CWAT(40)
COhMON/LAND/RAlNF^ERODF.STPLNG.COVERjCONTRL.SEDELR.SOILOS,
S PORS.BDENS,DUET,EXTENT,ADEPTH,PD,RUNOFF,RESAT,
COHMON/IRRFOO/Y1,Y2,TE1,IE2.TH1.TH2.TH3,TH4,TH5,TH6,FP,FS,
8 ULEAFY.UPROD.UCHILK.UGHILK^HEAI.UUAl.UAIR,
i QFC,QFG.TFl.IF2.TS.CLl<40):CL2(40),CPI(40),CP2(40)f
I CCMI1(46),CCMI2UO).CGMI1(40).CGMI2(40),
& CMEAT(40).COL1(40),COL2(40).COP1(40).COP2(40),
4 COCMI1(40),COCMI2(40).COGMI1(40),COGHI2(40),
S COMEAT<40)'QING(40),QlNH(40).POPr
S CSP(40).CSPT(40).CSPO(40),CSPOT(40)
COMHON/FUNC/XAHBUE.TA.TW.FI.PP.UIRAIE,
S QCU,QGU,QBU,ABSH.P14
COMMON/EVAP/PPN.PHID,P,XIRR,S(12),T(12),TD(12)rXINFL,SINFL,
$ SHASS UhASS UDEEP
COMMON/CNlRL>NONCLi.MAXYR,TITLE(20).LOCATE(12).NYRl,NYR2,
I PCI1.PCT2.LEAOPT,IOPVWV.IOPSAT,IPRT1.IPRT2.IDELT.IXTS,
8 IRRESl.IRfiES2.LIND,IAVGl.IAVG2!RR,FIHECH,lNTYR(4). RAE1085
S WWATL.HWATA.UHATH.SUATL^WATA^WArHjIVAp'lBSMT
NEXYR=IAVG2-IAVG1+1
DECA=DECAY(I)/8260.
XAMBEF=DECA+XAMBWE
IERhl=DERATE(I)ARA(I)ATVA(1.0-EXP(-XAMBEFATE))/(YAXAMBEF)
CSP(I)=CSPI(I)/FLOAI(NEXYR)
TERM2=CSP(I)AB/PP
CV=(TERhl+TERM2)AEXP(-D£CAATH)
RETURN
END
C
C
C
SUBROUTINE FOODA(NN)
A-32
-------�
c
c
c
CAAAAA CALCULATION OF RADIONUCLIDE CONCENTRATION IN VEGETABLES, MILK AND
C HEAT CONSUMED BY HAN RESULTING FROH ATHOSPHERIC DEPOSITION
C CALLED BY HAIN.
C
C
C
C
C
C
C
C INPUT VARIABLES
C
C
C
C
C
C
C
C
C
C
C
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NN
DECAY
XAHBUE
TA
PP
kA
BV
BR
DERATE
IOPT
Yl
Y2
TE1
TE2
TH1
TH2
TH3
TH4
TH5
TH6
FP
FS
FHC
FMG
QFC
QFG
m
=
=
=
=
=
=
=
=
=
=
=
=
s
3
=
=
=
=
=
=
=
=
—
=
=
NUCLIDE NUHBER
RADIOACTIVE DECAY CONSTANT
= WEATHER DECAY CONSTANTS
AIRBORNE HATER1AL
PERIOD OF TIME FOR WHICH SOIL IS EXPOSED TO THE
CONTAHINATED AIRBORNE MATERIAL
SURFACE DENSITY FOR SOIL
RETENTION FRACTION
CONCENTRATION FRACTION FOR UPTAKE OF RADIONUCLIDE
FROH SOIL BY VEGETATIVE PARTS OF CROPS
CONCENTRATION FRACTION FOR UPTAKE OF RADIONUCLIDE
FROH SOIL BY REPRODUCTIVE PARTS OF CROPS
= RADIONUCLIDE DEPOSITION RATE
OPTIONS FOR SPECIALS RADIONUCLIDES H-3 AND C-14
IOPT = 1 IF H-3 AND C-14 IS NOT INCLUDED IN THIS
IOPT = 2 IF ONLY H-3 IS INCLUDED
IOPI = 3 If ONLY C-14 IS INCLUDED
10PI = 4 IF BOTH ARE INCLUDED
AG PRODUCTIVITY FOR GRASS CONSUHED BY ANIMALS
AG PRODUCTIVITY FOR VEGETATION CONSUMED BY HAN
TIME PASTURE GRASS EXPOSED DURING GROWING SEASON
TIHE CROP/VEG EXPOSED DURING GROWING SEASON
PERIOD DELAY BETWEEN HARVEST OF PASTURE GRASS
AND INGESTION BY ANIHALS
PERIOD DELAY BETWEEN HARVEST OF STORED FEED AND
INGESTION BY ANIMAL
PERIOD DELAY BETWEEN HARVEST OF LEAFY VEG AND
INGESTION BY HAN FOR MAXIMUM INDIVIDUAL EXPOSURE
PERIOD DELAY BETWEEN HARVEST OF PRODUCE AND
INGESIION BY MAN FOR HAXIMUM INDIVIDUAL EXPOSURE
TIHE DELAY BETWEEN HARVEST LEAFY VEG AND
INGESTION BY MAN FOR GENERAL POPULATION EXPOSURE
TIME DELAY BETWEEN HARVEST OF PRODUCE AND
INGESIIONi BY MAN FOR GENERAL POPULATION EXPOSURE
FRACTION UF YEAR THAT ANIMAL GRAZE ON PASTURE
FRACTION OF DAILY FEED THAT IS FRESH GRASS WHEN
ANIMALS GRAZE ON PASTURE
FRACTION OF THE COW'S DAILY INTAKE OF
RADIONUCLIDE WHICH APPEARS IN EACH LITER OF MILK
FRACTION OF THE GOAT'S DAILY INTAKE OF
RADIONUCLIDE WHICH APPEARS IN EACH LITER OF HILK
AHOUNT OF FEED CONSUHED BY CATTLE
AHOUNT OF FEED CONSUMED BY GOATS
TRANSPORT TIME OF RADIONUCLIDE FROM
FEED-MILK-RECEPTOR FOR H.I.E.
1/Y
1/H
H
KG/HAA2
PCI/HAA
RUN
KG/HAA2
KG/HAA2
H
H
H
H
H
H
H
H
D/L
D/L
KG/D
KG/D
H
A-33
-------�
c
c
c
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c
IF2 = TRANSPORT TIME OF RADIONUCLIDE FROM
FEED-MILK-RECEPfOR FOR G.P.E.
FF = FRACTION OF THE ANIMAL'S DAILY INTAKE OF
RADIONUCLIDE WHICH APPEARS IN EACH KG Of FLESH
IS = TIME FROM SLAUGHTER OF MEAT 10 CONSUMPTION
ABSH = ABSOLUTE HUMIDITY OF THE ATMOSPHERE
P14 = FRACTIONAL EQUILIBRIUM RATIO FOR C-14
INTERMEDIATE VARIABLES
XAHBEF= EFFECTIVE DECAY CONSTANT
CPAST = NUCLIDE CONC IN PASTURE GRASS CONSUMED BY ANIMALS
CSTO = NUCLIDE CONC IN STORED FEED CONSUMED BY ANIMALS
CFEED = RADIONUCLIDE CONCENTRATION IN ANIMALS'S FEED
H
D/KG
H
G/HAA3
OUTPUT VARIABLES
CL1 = RADIONUCLIDE
FOR M.I.E.
CL2 = RADIONUCLIDE
FOR G.P.E.
CP1 = RADIONUCLIDE
FOR M.I.E.
CP2 = KAD10NUCLIDE
FOR G.P.E.
CCMI1 = RADIONUCLIDE
CCMI2 = RADIONUCLIDE
CGMI1 = RADIONUCLIDE
CGMI2 = RADIONUCLIDE
CHEAT = RADIONUCLIDE
CONC IN LEAFY VEG CONSUMED BY MAN
CONC IN LEAFY VEG CONSUMED BY MAN
CONC IN PRODUCE CONSUMED BY MAN
CONC IN PRODUCE CONSUMED BY MAN
CONC IN COW'S MILK FOR M.I.E.
CONC IN COW'S MILK FOR G.P.E.
CONC IN GOAT'S MILK FOR M.I.E.
CONC IN GOAX'S MILK FOR G.P.E.
CONC IN BEEF CATTLE'S MEAT
PCI/KG
PCI/KG
PCI/KG
PCI/KG
PC1/L
PCI/L
PCI/L
PCI/L
PCI/KG
DOUBLE PRECISION NUCLID.H3.C14
COMMON/NUC/NUCLID(40),AfMA§S<40).TRAM<40>.SOAM(40).ATAM(40),
& AQAH<40,1000),STAM<40),POLO(40),POLB(40>.CS(40).CU<40>.
X SSTREM<40),SDEEP<40).AIRCON<40),YSO(40),SOAVG<40),CON<40).
& AQCON(40),STCON(40),ATCON(40).AQAVG(40).STAVG(40).DETW(40>. ISINEWL
& ATAVG(40) FMC<40> .FMG(40) ,DECAY<40) ,XKDU. 40) ,SOL(40).
& FF<40>,RA(40>,RU<40),BV<40).BR<40),DERATE(40>,CUAT(40)
COMMON/IRRFOO/Yl.Y2,TEl.TE2,IHl.IH2fTH3fTH4.TH5.IH6,EP,FS,
& ULEAFY,UPROD,UCMILK.UGMILK,UMEAT.UWAT.UAIR,
* QFC,QFG.IFl,TF2.TS.CLl<40).CL2<40>,CPl<40)fCP2<40),
S CCMI1(46)ICCMI2UO).CGMI1(40),CGMI2(40),
I CMEAI<40).COL1(40).COL2(40).COP1<40).COP2<40),
J COCMIl(40),COCMI2(40),COGMIl(40)rCOGHI2(40),
& COMEAT(40),QING(40).QINH(40).POP,
i CSP(40),CSPT(40),CSPO(40),CSPOT(40)
COMMON/LAND/RAINF,ERODF,STPLNG.COVER,CONTRL.SEDELR, SOILOS.
& PORS.BDEIfS, DUET, EXTENT, ADEPTH,PDf RUNOFF, RESAT,
& INSITE
COMMON/EVAP/PPN.PHID,P,XIRRfS(12),T<12),TD<12),XINFL,SINFL.
X SMASS,HMASSfWDEEP
COMMON/EUNC/XAMBWE.TA.TW.FI.PP.WIRATE.
& QCU.QG& Q&W,ABSH,Pl4
COMMON/PCM/SOCON(40)
DATA H3.C14/8HH-3 .8HC-14 /
IF(NUCLID(NN) .EQ. H3) GO TO 200
IF(NUCLID(NN) .EQ. C14) GO TO 300
DECA=DECAY(NN)/8760.
DECSL=bINFL/(0.15A
-------�
CSP(NN)=+DERATE(NN>A87GO.)AEXP(-(D£CA+B1-CSL>A87GO.>
C CALCULATION OF CPAST= RADIONUCLIDE CONCENTRATION IN PASTURE GRASS
C CONSUMED BY ANIMALS
B=0.243ABV(NN) RAE018G
TERH2=CSP(NN)AB/PP RAE0186
CPASI=CVA=CVA
-------�
CP1(NN)=CV3
CP2(NN)=CV3
CCHIHNN)=FMC,CS(40).CM(46).
S SSTREM(40).SDEEP(40).AIRCON(40),YSO(40),SOAVG(46),CON(40),
& AQCON(40),STCON(40).ATCON(40) ,AQAVG(40) ,STAVG(40> .DETW(40) , ISINEUL
8 ATAVG(40).FHC(40),FMG(40).DECAY(40).XKD(4.40),SOL(40),
S FF(40).RA(40).RU(40),BV(40).BR(40),DERATEUO)|CWAT(405
COHHON/FUNC/XAMBWE.TA.TU.FI.PP.WIRATE,
& QCU.QGW,Q&U,rtBsATPl4
DECA=DECAY(I)/8760.
XAHBEF=DECA+XAMBWE
TERH1=DERATE(I)ARA(I)ATVA(1.0-EXP(-XAMBEFATE))/(YAXAMBEF)
CVA=(TERhl+TERH2)AEXP(-DECAATH)
RETURN i
END
C
C
C
SUBROUTINE HUHEX(NN)
C
C
C CALCULATION OF ANNUAL RADIONUCLIDE INTAKE BY HAN. CALLED BY MAIN
U
c
C
A-36
-------�
c
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c
c
CAAAA
C
C
100
200
C
CAAAA
C
C
C
C
INPUT VARIABLES
NN = RADIONUCLIDE NUMBER
ULEAFY = ANNUAL INTAKE OF LEAFY VEGETABLES (KG/Y)
UPROD = ANNUAL INTAKE OF PRODUCE (KG/Y)
UCH1LK = ANNUAL INTAKE OF COW'S HILK(L/Y)
UGMILK = ANNUAL INTAKE OF GOAT'S HILK(L/Y)
UMEAT = ANNUAL INTAKE OF BEEF CATTLE'S MEAKKG/Y)
UWAT = ANNUAL INTAKE OF DRINKING WATER(LXY)
UAIR = ANNUAL INHALATION RATE OF AIR(M3/Y)
OUTPUT VARIABLES
Q1NG = ANNUAL INTAKE OF RADIONUCLIDE BY INGEST10N OF CONTAMINED
FOOD CONSIDERING ATMOSPHERIC AND AQUATIC PATHWAYS(PCI/Y)
QINH = ANNUAL INTAKE OF RADIONUCLIDE BY INHALATION(PCI/Y)
DOUBLE PRECISION NUCLID,PNUC
COMMON/IRRtOO/Yl.Y2,TEl,TE2.IHl.TH2.TH3,TH4.TH5,THG,FP,FS,
i ULEAFY.UPROD.UCMILK.UGMILK,UHEAT.UHAI.UAIR,
i QFC,QF,CCMI2(40>.CGMn(40>.CGMI2(40).
g CMEAI(40).COL1(40).COL2(40)IC6P1<40).COP2(40).
& COCMI1<40),COCMI2<40),COGHI1(40>,COGHI2(40>,
& COMEAT<40).QING<40).QINH<40).POP,
I CSP(40).CSPT<40>,CSPO<40>,CSPOI(40)
COMMON/NUC/NUCLID(40),ATMASS(40).TRAH(40).SOAM<40).ATAM<40).
t AQAM(40.1000).STAM(40),POLO(40).POLB(40)1CS(40).CW<46)I
I SSTREM(40)1SDEEP<40)fAIRCON(40)!YSO(40).SOAVG(46).CON(40).
& AQCON(40)fSICON(40),ATCON(40).AQAVG(40),STAVG(40) DETW(40), ISINEUL
i ATAVG(40).FMC(40).FHG(40).DECAY(40).XKD(4.40)fSOL(40).
& FF(40).RAUO)fRU(40).BV(40).BR(40),DERATEUO) CWAK40)
COMMON/PASS/PNUC(40),PCONK40),PCON2(40)fPCON3(40)r
I PCON4(40>,PPOP,LLIND,LDIST
CALCULATION OF RADIONUCLIDE INTAKE BY CONSUMPTION OF VEGETATION,
MILK, MEAT AND DRINKING WATER
IF
-------�
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c
CALCULATION Of ANNUAL RADIONUCLIDE INTAKE BY MAN. CALLED BY MAIN
c
CAAAA
C
C
100
200
C
CAAAA
C
INPUT VARIABLES
NN = RADIONUCLIOE NUMBER
ULEAFY = ANNUAL INTAKE OF LEAFY VEGETABLES (KG/Y)
UPROD = ANNUAL INTAKE OF PRODUCE (KG/Y)
UCMILK = ANNUAL INTAKE OF COW'S MILK(L/Y)
UGMILK = ANNUAL INTAKE OF GOAT'S MILK(L/Y)
UMEAT = ANNUAL INTAKE OF BEEF CATTLE'S MEAKKG/Y)
UWAT = ANNUAL INTAKE OF DRINKING WAIER(L/Y)
UAIR = ANNUAL INHALATION RATE OF AIR(M3/Y)
OUTPUT VARIABLES
KING = ANNUAL INTAKE OF RADIONUCLIDE BY 1NGESTION OF CONTAMINED
FOOD CONSIDERING ATMOSPHERIC AND AQUATIC PATHUAYS(PCI/Y)
QINH = ANNUAL INTAKE OF RADIONUCLIDE BY INHALATION(PCI/Y)
DOUBLE PRECISION NUCL1D,PNUC
COMMON/IRRFOO/Yl.Y2,TEl,IE2,IHl.IH2.TH3fTH4,TH5,TH6,FP,FS,
& ULEAFY,UPROD,UCMILK.UGMILK,UMEAT.UUAI.UAIR,
g QFC.QFG.TF1.TF2.TS.CL1(40).CL2(40).CP1(40),CP2(40),
g CCHI1(46)FCCMI2UO).CGMI1(40),CGMI2(40),
g CMEAl(40).COLK40)rCOL2(40).COPl(40),COP2(40),
g COCMI1(40),COCMI2(40).COGMI1(40),COGMI2(40),
g COMEAI(40).QING(40).QINH(40).POP.
& CSP(40).CSPT(40),CSPO(40>,CSPOT<40>
COMMON/NUC/NUCLIB(40),AIMASS(40).TRAM<40).SOAM(40).ATAM<40),
i AQAM(40.1000)1STAM(40),POLO(40)>POLB(40).CS(40).CW(40).
g SSIREM(40),SDEEP(40).AIRCON(40),YSO(40)ISOAVG(40).CON(40).
J AQCON(40)fSTCON(40),ATCON(40).AQAVG(40).STAMG(40).DETW(40), ISINEUL
g ATAVG(40),FMC(40),EMG(40),DECAY(40).XKD(4.40).SOL(40).
8 FF(40).RA(40),RW(40).BV(40),BR(40).DERATE(40),CWAT(40)
COMMON/PASS/PNUC(40),PCON1(40),PCON2(40),PCON3(40).
g PCON4(40),PPOPfLLIND,LDISI
CALCULATION OF RADIONUCLIDE INTAKE BY CONSUMPTION OF VEGETATION,
MILK, MEAT AND DRINKING WATER '
IF(LLIND .EQ. 0) GO TO 100
QVEG=(CL2(NN)+COL2(NN))AULEAFY+(CP2(NN)+COP2(NN))AUPROD
QMILK=(CCMI2(NN)JCOCHI2+COGMI2(NN»AUGMILK
GO TO 200 '
GVEG=(CL1(NN)+COL1(NN))AULEAFY+(CP1(NN)+COP1(NN))AUPROD
QMILK=(CCMI1(NN)+COCMI1(NN))AUCMILK+(CGMI1(NN)+COGMI1(NN))AUGMILK
QMEAT=(CMEAT
-------�
RETURN
END
C
C
C
C
SUBROUTINE INEILUXI.TP)
C THIS SUBROUTINE. WITH SUBROUTINES SOIL AND ROUT. CALCULATES
C INFILRATION THROUGH THE TRENCH CAP FOR A SINGLE YEAR AND
C RETURNS THAT VALUE TO THE MAIN PROGRAM. THE ORIGINAL MODEL AND
C PROGRAM WERE WRITTEN BY C.Y.HUNG, OFFICE OF RADIATION PROGRAMS,
C USEPA. WASHINGTON D.C.
COMMON /BLOCK1/R(25),EP(25),H(25),QL(25),YP(25).YG(25),ETO(25),
1 ETS(25>.VP(25).VG(25).YTP<25>,YTG(25>,XI(25>,PU2,31,25>
COMMON /BLOCK2/HT(4),YPT<4).YGT(4)
COMMON /BLOCK3/RI.EPT.YPTE,XKL,ETOTfQLT.XL.VGT.VPT,DELT,ETST,EPSP,
1YIGPP.HUPMAX,VPMAX,HUGMAX,VGMAX,YPMAX,XNS,UYMAX,XKI,I,XIT,
2EPSG.YTGPG.YGMAX.XDE.XKE
DIMENSION HODAY<12),THP(12,31),DTH<12)
DATA IAMP/99/,MODAY/31,28,31,30,31,30,31,31,30,31,30,317
WRIIE(6.3010)
C READ CONTROL PARAMETERS
READ(4.1010)TUI,SLOP.XKI,EPSG,EPSP.YGMAX.XDE,XKE,YPI,YGI
URITE(6r9010)TUT,SLOP.XKI,EPSG,EPSP,YGMAXIXDE.XKE.YPI,YGI
9010 FORMAK//,' INPUT DATA AS READ IN', //,5X,6F7.3,2E10.3,2F7.3)
YP(1)=YPI
YG(1)=YGI
YPMAX=YGMAX
VPMAX=0.0
VGMAX=XKI
C CREATE A 3-DIMENSIONAL ZERO-RATE RAINFALL MATRIX
DO 100 IM=1.12
NODAY=MODAY(IM)
DO 100 ID=1,NODAY
DO 100 IH=2,25
P(IM,ID.IH)=0.
100 CONTINUE
C READ MONTHLY MAXIMUM DAY LENGTH
READU.1020)
-------�
600 CONTINUE
C CALCULATE OK DEFINE CONSTANTS
DELI=1.0
IAU=O.GG
XKCHHD=120./39.37
CEP=.14/(24. A 1000.)
XL=IH1V2,
XKL=SGRHSLOP)A3600./0.05
H(l)=0.
XKCH=XKCMMD/(1000.A24)
TEP=0.
TP=0.
TXI=0.
HSNH=0.
TRO=0.
XKI=VG«AX+VPHAX
WRITE (6, 3050)
WRITE<6f3051) XKCMMD.YGMAX, TUT, SLOP, XKI
URITE(6,3052)EPSP,EPSG,XDE,XKEFDELT
C STEADY STATE INFILTRATION LOOP
C
TXIL=0.0
DO 80 IY=1,10
TP=0.0
TEP=0.0
TRO=0.0
TXI=0.0
C
C HONTHLY LOOPAAAAAAAAAAAAAAAAAAAAAAAA
DO 70 IH=1,12
NODAY=HODAY(IM)
DT=DIH(IM)/12.
C DAILY LDOPAAAAAAAAAAAAAAAAAAAAAAAAAA
DO 60 ID^l.NODAY
TC=lHP+32. T
IF(IE.GE.32.) GO 10 10
HSNH = HSNU + P(IH,ID.I)
R(I) =0.
GO TO 40
10 S«=XKCMA(TF-24.)
IF(SM .LT. HSNU) GO TO 30
SH=HSNU
30 HSNU=HSNU-SH
40 CONTINUE
A-40
-------�
CALL ROUT
TEP=IEP+(ETS( IHEIO< I) )ADELT
TP=TP+P(IM,ID,I)ABELT
IXI=IXHX1(I)ADELT
TRO=IRO+QL(I>ADELI
ETSO=ETS(I)+ETO(I)
11=1-1
HR=HR+1.
C
50 CONTINUE
H(1)=H(25)
YG(1)=YG(25)
YP(1)=YP(25)
60 CONTINUE
70 CONTINUE
URIIE<6,81) IY
81 FORMAI YP(25>,YG(25>.HSNU
3061 FORMAT(5X,'PELLICULAR' 4X,'GRAVITY',5X.'SNOW'/,5X,'DEFICIT',
C 7X 'DEFICIT'/,5X,50('-')/,4X,3(1PE11.2)/)
PER1XI=IXI-1XIL
URII£(6.82) PERTXI
PER=0.02ATXIL
IF(PERIXI.LE.PER.AND.IY.NE.l) RETURN
TXIL=TXI
80 CONTINUE
82 FORMAK//.' CHANGE OF TOTAL ANNUAL INFILTRATION='
C .1PE11.2.////)
C FORMAT StATEHLNTSAAAAAAAAAAAAAA^AAAAAAAAAAAAAA
1010 FORMAK10F7.3)
1020 tORMAT(12f5.1)
1030 FORHAT(2X,12F6.2)
1040 EORHAI(I2flX.I2.1X,24(F3.0),2X)
3010 FORhATdX 'OUTPUT FROM SUBROUTINE INFIL'/.28('A').//)
3020 EORHAK1X,'DAILY SUNSHINE BY MONTH (HOURS)'/.3X.12F8.1//)
3030 FORMATdX,'DAILY TEMPERATURES (DEGREES CELSIUS)!'//,
1 2Xf'MONTH= JAN FEB MAR APR MAY JUN JUL AUG
2 SEP OCI NOV DEC'/,3X,'DAY'/)
3031 FORMAT(3X,I2,3X.12(F6.2,1X)./)
3040 FORMAT(//,1X 'HONTH.DAY,J RAINFALL AS READ IN (0.1MM/HR):'/)
3041 EORMAT(1X.2(I2.1X).24F4.0)
3050 FORMATC/.lX.'lkNCH CHARACTERISTICS: '/)
3051 FORMATdSX/SNOUMELT COEFFICIENT ='.F10.2,'MM/DEG-DAY'/,
115X,'THICKNESS OF TRENCH COVER =',F10.2,' M'/.
215X:'TOTAL WIDTH OF TRENCH COVER =',F10.2,' M7/,
315X.'AVERAGE SLOPE OF TRENCH COVER =',F10.2.' M/MV,
415X.'PERMEABLITY OF TRENCH CAP =' E12.3,'M/HR')
3052 FORHATdSX 'POROSITY FOR PELLIC WATER =J, F10.2,' (UNTILESS)'/,
115X,'POROSITY FOR GRAVITY WATER =',F10.2['(UNIILESS)'/,
215X,'EQUIVALENT UPWARD DIFFUSIVITY =' E12.2,' MAA2/HR',/,
315X 'EQUIVALENT UPWARD HYDRAULIC CONDUCTIVITY =',E12.2,' M/HR',/
415X 'TIME STEP FOR MODEL ='. E10.2.' HOURS'/)
3060 FORHAK///. IX. 12('A'). 'CUMULATIVE ANNUAL VALUES (M)'. 12(' A')//
1 8X,'PRECIP',6X.'EVAPJ,6X,'RUNOFF',6X,'INEIL',/,5X,50('-')/,
2 4X.4(1PE11.2)/)
RETURN
END
C
C
A-41
-------�
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SUBROUTINE ROUT
COMMON /HLOCKl/R(2b),EP(2b),H(25).QL(25),YP(25),YG(25).ETO(25),
1 ETS(25)1VP(25).VG(25).YTP(25).YTG(25)lXI(25)fP(12,31f55)
COMMON /6LOCK2/HK4),YPT<4).YGI<4)
COMMON /BLOCK3/RT.EPT.YPTE,XKL,ETOT.QLT.XL.VGT.VPT,DELT.ETSI,EPSP,
lYTGPP,HUPMAX.VPMAX.HUGMAX,VGMAXFYPMAX,XNSrUYMAX,XKI,I,XII,
2EPSG.YTGPG,YGMAX,XDEfXKE
RT=R(I)
EPT=EP(I)
CALL SOIL
IF(H10T .EQ. 0.0) GO TO 300
HT(1) = H(I-l)
DO 200 J=1.4
QLt=XKLAHfU>AAl.&&7
HT(J) = (RI-EI01--E1SI-QLI/XL-VPT-VGT)ADELT + H(I-l)
IF(HKJ) .LI. 0.0) HI(J)=0.
IE<3 .GE. 3) GO 10 100
HT(J+1) = (H1(J) * H(I-1»A0.5
GO TO 200
100 IEU .EQ. 3) HKJ+1) = HI(J)
200 CONTINUE
H(I)=(H1(1)+2.0A(H1(2)+H1(3)) + Ht(4))/6.0
QL(I)=(R(I)-EIOI-VG1-VPT-(H(I)-H(I-1))/DELT)
GO 10 400
300 H(I)=0.
QL(I)=0.
400 YP(I)=YP(I-1)+(ETSI-VPI)ADELI/EPSP
YG(I)=YG(I-1)+(XIT-VGT)ADELT/EPSG
ETO(I) = ETOT
EIS(I)=ETST
XI(1)=XIT
VP(I)=VPI
VG(I)=VGT
RETURN
END
C
C
C
C
SUBROUTINE SOIL
COMMON /BLOCK1/R(25).EP(25),H(25).QL(25).YP(25).YG(25).ETO(25),
1 ETS(25).VP(25),VG(25),YTP(25).YTG(25),XI(25),P(12.31.25)
COMMON /BLOCK2/HT<4),YPT(4).YGT(4)
COMMON /BLOCK3/RT.EPT.YPTE,XKL,ETOT.QLT,XL.VGT.VPT,D£LT.EXST.EPSP,
Lit
-------�
VGT=VGMAX-VPI
IFdGHW .LT. VGI) VGI=TGHW/DELT
YGTT= VGIADELT/EPSG
IF(YGIT .GT. YG(I-D) VGI = YG(1-1)AEPSG/DELI
IF(YGTT .GT. YG(I-l)) YGTI=VGTADELT/EPSG
GO 10 150
100 ETOT=TSWE/DELT+EPT
IF(EIOT .LT.O.) E10T=0.
EPSPG=EPSP+EPSG
EPIE=EPT-tlOT
IF(YP(I-1).EQ.O.) GO TO 110
ETSTU=(XDEAEPSP/YP(I-1))-XKE
IF(ETSTU.GT.EPIE) EISTW=EPTE
GO TO 120
110 EISTW=EPTE
120 EISIV=EPTE//(0.66AEPSPG)))
IF(ETSTV.G£.ETSTU> ETST=EISTV
IF(ETSTW.GE.ETSIV) ETST=ETSTU
VPI=0.
VGT=0.
150 IF
-------�
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IOPT = OPTIONS FOR SPECIAL RADIONUCLIDE H-3
IOPI = 1 IE H-3 IS NOT INCLUDED IN THIS RUN
IOPT = 2 IF H-3 IS INCLUDED
Yl = AG PRODUCTIVITY FOR GRASS CONSUMED BY ANIMALS KG/MAA2
Y2 = AG PRODUCTIVITY FOR VEGETATION CONSUMED BY MAN KG/MAA2
TE1 = TIME PASTURE GRASS EXPOSED DURING GROWING SEASON H
TE2 = TIME CROP/VEG EXPOSED DURING GROWING SEASON H
TH1 = PERIOD DELAY BETWEEN HARVEST OF PASTURE GRASS
AND INGESTION BY ANIMALS H
TH2 = PERIOD DELAY BETWEEN HARVEST OF STORED FEED
AND INGESTION BY ANIMAL H
IH3 = PERIOD DELAY BETWEEN HARVEST OF LEAFY VEGETABLE
AND INGESTION BY HAN FOR M.I.E. H
1H4 = PERIOD DELAY BETWEEN HARVEST OF PRODUCE AND
INGESTION BY MAN FOR H.I.E. H
TH5 = PERIOD DELAY BETWEEN HARVEST OF LEAFY VEG
AND INGESTION BY MAN FOR G.P.E. H
1H6 = PERIOD DELAY BETWEEN HARVEST OF PRODUCE
TH5 = PERIOD DELAY BETWEEN HARVEST OF LEAFY VEG
FP = FRACTION OF YEAR THAT ANIMAL GRAZE ON PASTURE
FS = FRACTION OF DAILY FEED THAT IS FRESH GRASS WHEN
ANIMALS GRAZE ON PASTURE
FMC = FRACTION OF THE COW'S DAILY INTAKE OF
RADIONUCLIDE WHICH APPEARS IN EACH L OF MILK D/L
FMG = FRACTION OF THE GOAT'S DAILY INTAKE OF
RADIONUCLIDE WHICH APPEARS IN EACH L OF MILK D/L
QFC = AMOUNT OF FEED CONSUMED BY CATTLE KG/D
QFG = AMOUNT OF FEED CONSUMED BY GOATS KG/D
TF1 = TRANSPORT TIME OF RADIONUCLIDE FROM
FEED-MILK-RECEPl'OR FOR M.I.E. H
TF2 = TRANSPORT TIME OF RADIONUCLIDE FROM
EEED-MILK-RECEPTOR FOR G.P.E. H
FF = FRACTION OF THE ANIMAL'S DAILY INTAKE OF
RADIONUCLIDE WHICH APPEARS IN EACH KG OF FLESH D/KG
TS = TIME FROM SLAUGHTER OF MEAT TO CONSUMPTION H
QCW = AMOUNT OF WATER CONSUMED BY COW L/D
QGW = AMOUNT OF HATER CONSUMED BY GOAT L/D
QBW = AMOUNT Of WATER CONSUMED BY BEEF CATTLE L/D
INTERMEDIATE VARIABLES
XAMBEF= EFFECTIVE DECAY CONSTANT
COPAST= RADIONUCLIDE CONCENTRATION IN PASTURE GRASS CONSUMED BY A
COPAST= RADIONUCLIDE CONCENTRATION IN STORED FEED CONSUMED BY ANI
COFEED= RADIONUCLIDE CONCENTRATION IN ANIMALS'S FEED
OUTPUT VARIABLES
COL1 =
COL2 =
COP1 =
COP2 =
COCMI1=
COCMI2=
COGMI1=
COGMI2=
RADIONUCLIDE
FOR H.I.I.
RADIONUCLIDE
FOR G.P.E.
RADIONUCLIDE
FOR H.I.E.
RADIONUCLIDE
FOR G.P.E.
RADIONUCLIDE
RADIONUCLIDE
RADIONUCLIDE
RADIONUCLIDE
CONC IN LEAFY VEG CONSUMED BY MAN
CONC IN LEAFY VEG CONSUMED BY MAN
CONC IN PROCUCE CONSUMED BY MAN
CONC IN PRODUCE CONSUMED BY MAN
CONC IN COW'S MILK FOR M.I.E.
CONC IN COW'S MILK FOR G.P.E.
CONC IN GOAT'S MILK FOR M.I.E.
CONC IN GOAT'S MILK FOR G.P.E.
PCI/KG
PCI/KG
PCI/KG
PCI/KG
PCI/L
PCI/L
PCI/L
PCI/L
A-44
-------�
C tOMEAI= RADIONUCLIDE CONG IN BEEF CATTLE'S HEAT PCI/KG
DOUBLE PRECISION NUCLIO,H3.C14
COMMON/CNTRL/NONCLB.MAXYR,TITLE(20).LOCATE<12),NYR1.NYR2,
* PCT1.PCT2.LEAOPT.IOPVWV.IOPSAT,IPRT1.IPRT2 .IDELT.IXIS,
J IRRESl.IRRES2.LIN[i,IAVGl.IAVG2,RR,FTI1ECH,INTYR(4), RAE1085
S WWATL,&WATA.U&AIH,SWATL.SWATA,SWATH.IVAP.IBSMT
COMMON/NUC/NUCLIB(40),ATMASS<46).TRAM(40>.SOAM<40>,ATAM(40),
& AQAM(40.1000>,STAM(40>,POLO<40>,POLB(40),CS(40).CW<4&).
& SSTREM<40),SDEEP<40).AIRCON(40),YSO<40)fSOAVG(46),CON(40>.
S AQCON(40),STCON(40).ATCON(40).AQAVG(40).STAVG(40).BETU<40), ISINEUL
S ATAVG<40).FMC<40),FHG(40>.DECAY<40).XKD(4.40),SOL(40).
* FF(40>,RA(40),RW(40),BV(40).BR(40),DERAIE(40),CUAI(40)
COHMON/IRRFOO/Y1,Y2,TE1,TE2.TH1.TH2.TH3,TH4,TH5,TH6,FP,FS,
S ULEAFY.UPROD,UCHILK,OGMILK,UHEAT.UWAT.UAIR,
S QFC,QFG.IF1,TF2,TS.CL1(40).CL2(40),CP1<40),CP2(40),
S CCMI1(40),CCMI2(40).CGMI1(40).CGMI2(40).
S CMEAI(40).COL1(40).COL2(40).COP1(40).COP2(40),
& COCMII (40),COCMI2(40),COGMIl(40)fC06H12(40),
S COMEAT(40),QING(40).QINH(40),POP,
& CSP(40).CSPI(40),CSPO(40),CSPOT(40)
COMHON/FUNC/XAHBUE.TA.TW.FI.PP.UIRATE,
& QCUyQGU,QBU.ABSH.P14
DATA H3.C14/8HH-3 ,8HC-14 /
DECA=DECAY(NN)/8760.
C
IF(NUCLID(NN) .EQ. H3)GO TO 200
IF(NUCLID(NN) .EQ. C14) GO TO 300
C CALCULATION OF COPASI=RADIONUCLIDE CONCENTRATION IN PASTURE GRASS
C CONSUMED BY ANIMALS
B=0.243ABU(NN) RAE0186
COPASX=COV
-------�
c
CAAA 2. FOR GENERAL POPULATION
COCHI2(NN)=FMCAEXP(-BECAATS)
RETURN
CAAA CALCULATION FOR SPECIAL RADIONUCLIDE: TRITIUM
CAAA TRITIUM CONC. IN VEGETATION = TRITIUM CONC. IN ANIMAL FEED =
CAAA TRITIUM CONC. IN WATER = CWAT(l)
CAAA CALCULATION OF H-3 CONCENTRATION IN VEGETATION, MILK,
CAAA AND MEAT CONSUMED BY MAN
200 COL1(NN)=CWAT(NN)
COL2(NN)=CUAt(NN)
COP1(NN)=CWAT(NN)
COP2(NN)=CWA1(NN)
CUAT(NN)= WMA1AAAQAVG
-------�
4 AQAM<40.1000).STAM(40>,POLO(40>,POLB(4(».CS<40>.CW<40>.
I SSTREM(40)rSDEEP<40).AlRCON<40),YSO(40)fSOAVG<46)fCON<40>.
i AQCON<40),£TCON(40>fATCON<40>.AQAVG<40>.STAVG(40>.DETW<40>, ISINEWL
3 ATAVG(40).FMC(40).FMG<40).DECAY<40).XKD<4,40)rSOL<40).
& FF<40).RA<40>.RW(40).BV(40>,BR(40>,DERATE(40),CWAT(40)
COMMON/LANB/RAINF,ERODF.STPLNG.COVER,CONIRL.SEDELR.SOILOS,
& PORS.BDENS.DWET,EXTENTFADEPTH,PD,RUNOFF,RESAT,
8 INSlfE
COMMON/IRRFOO/Y1.Y2,TE1,TE2.TH1.TH2.TH3,TH4,TH5,TH6,FP,FS,
I ULEAFY,UPROD,UCMILK.[IGMILK,UMEA.r.UUAT.UAlR,
I QFC,QFG.TFl,IF2.TS.CLl(40)fCL2(40),CPl(40),CP2(40),
J CCMI1(46),CCMI2(40).CGMI1(40).CGMI2(40),
2 CHEA1(40).COL1(40).COL2(40).COP1(40).COP2(40),
S COCMI1(40),COCMI2(40).COGMI1(40).COGHI2(40),
S COMEAT(40),QING(40).QINH(40).POP,
& CSP(40).CSPT(40),CSPO(40).CSPOT(40)
COMMON/FUNC/XAHBUE.TA.TU.FI.PP.WIRATE,
i QCU,QGhl.Q§U,ABSH.P14
COHMON/EVAP/PPN.PHlD.P,XIRRrS(12),I<12),TD(12),XINFLfSINFL,
$ SHASS,HMASS.UDEEP
COMMON/CNTRL/NONCLD.MAXYR.IITLE(20),LOCATE(12).NYR1.NYR2,
i PCT1.PCT2.LEAOPT. IOPVUV. IOPSAT, IPRT1. IPRT2. iflELT. IXTS,
X IRRESl.IRRES2.LIND,IAVGl,IAVG2,RR,FTI:IECHf INTYR(4), RAE1085
I UWATL,UUATA.WUATH,SUATL,SWArA,SI.JATH, IVAP IBSHT
NEXYR=IAVG2-IAVGH-1
DECA=DECAY(I)/8760.
XAMBEF=DECA+XAMBUE
TERM1=HIRAIEACUAT(I)ATVARH(I)A(1.0-EXP(-XAMBEFATE))/(YAXAMBEF)
CSPO( I)=CSPOI(I)/FLOAX(NEXYR)
TERM2=CSPO(I)AB/PP
COV=(TERM1+TERM2)AEXP(-DECAATH)
RETURN
END
C
C
C
SUBROUTINE IRRIGA(NN)
C
C
C
CAAAAA CALCULATION OF RADIONUCLIDE CONCENTRATION IN VEGETABLE, MILK AND
C CONSUMED BY MAN RESULTING FROM WATER IRRIGATION. CALLED BY MAIN.
C
C
C
C
C
C INPUT VARIABLES
C NN NUCLIDE DUMBER
C DECAY = RADIOACTIVE DECAY CONSTANTE 1/Y
C XAMBUE = WEATHER DECAY CUNSTANTE 1/H
C IW PERIOD OF TIME FOR WHICH SOIL IS EXPOSED TO THE
C CONTAMINATED WATER H
C PP SURFACE DENSITY FOR SOIL KG/MAA2
C RW RETENTION FRACTION
C BV CONCENTRATION FRACTION FOR UPTAKE OF RADIONUCLIDE
C FROM SOIL BY VEGETATIVE PARTS OF CROPS
C BR CONCENTRATION FRACTION FOR UPTAKE OF RADIONUCLIDE
C FROM SOIL BY REPRODUCTIVE PARTS OF CROPS
A-47
-------�
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FI
WIRATE
CUAT
IOPT
Yl
Y2
TE1
TE2
TH1
IH2
IH3
TH4
TH5
TH6
TH5
EP
FS
FMC
FMG
QFC
QFG
IF1
TE2
FF
TS
QCW
QGW
FRACTION OF THE YEAR CROPS ARE IRRIGATED
IRRIGATION RATE
RADIONUCLIDE CONCENTRATION IN WATER
OPTIONS FOR SPECIAL RADIONUCLIDE H-3
IOPI = 1 IF H-3 JIS NOT INCLUDED IN THIS RUN
IOPT = 2 IF H-3 IS INCLUDED
AG PRODUCTIVITY FOR GRASS CONSUMED BY ANIHALS
AG PRODUCTIVITY FOR VEGETATION CONSUMED BY MAN
TIME PASTURE GRASS EXPOSED DURING GROWING SEASON
TIME CROP/VEG EXPOSED DURING GROWING SEASON
PERIOD DELAY BETWEEN HARVEST OF PASTURE GRASS
AND INGESIION BY ANIMALS
PERIOD DELAY BETWEEN HARVEST OF STORED FEED
AND INGEST ION BY ANIMAL
PERIOD DELAY BETWEEN HARVEST OF LEAFY VEGETABLE
AND INGESTION BY MAN FOR M.I.E.
PERIOD DELAY BETWEEN HARVEST OF PRODUCE AND
INGESTION BY MAN FOR H.I.E.
PKRIOD DELAY BETWEEN HARVEST OF LEAFY VEG
AND INGESTION BY MAN FOR G.P.E.
PERIOD DELAY BETWEEN HARVEST OF PRODUCE
PERIOD DELAY BETWEEN HARVEST OF LEAFY VEG
FRACTION OF YEAR THAT ANIMAL GRAZE ON PASTURE
FRACTION OF DAILY FEED THAT IS FRESH GRASS WHEN
ANIMALS GRAZE ON PASTURE
FRACTION OF THE COW'S DAILY INTAKE OF
RADIONUCLIDE WHICH APPEARS IN EACH L OF MILK
FRACTION OF THE GOAT'S DAILY INTAKE OF
RADIONUCLIDE WHICH APPEARS IN EACH L OF MILK
AMOUNT OF FEED CONSUMED 6Y CATTLE
AMOUNT OF FEED CONSUMED BY GOATS
TRANSPORT TIME OF RADIONUCLIDE FROM
EEEH-MILK-RECEPTOR FOR M.I.E.
TRANSPORT TIME OF RADIONUCLIDE FROM
FEED-MILK-RECEPTOR FOR G.P.E.
FRACTION OF THE ANIMAL'S DAILY INTAKE OF
RADIONUCLIDE WHICH APPEARS IN EACH KG OF FLESH
TIME FROM SLAUGHTER OF MEAT TO CONSUMPTION
AMOUNT OF WATER CONSUMED BY COW
AMOUNT OF HATER CONSUMED BY GOAT
AMOUNT OF WATER CONSUMED BY BEEF CATTLE
L/MAA2-
PCI/L
KG/MAA2
KG/MAA2
H
H
H
H
H
H
H
D/L
D/L
KG/D
KG/D
H
H
D/KG
H
L/D
L/D
L/D
INTERMEDIATE VARIABLES
XAMBEF= EFFECTIVE DECAY CONSTANT
COPAST= RADIONUCLIDE CONCENTRATION IN PASTURE GRASS CONSUMED BY A
COPAST= RADIONUCLIDE CONCENTRATION IN STORED FEED CONSUMED BY ANI
COFEED= RADIONUCLIQE CONCENTRATION IN ANIMALS'S FEED
OUTPUT VARIABLES
COL1 = RADIONUCLIDE CONC IN LEAFY VEG CONSUMED BY MAN
FOR M.I.E. PCI/KG
COL2 = RADIONUCLIDE CONC IN LEAFY VEG CONSUMED BY MAN
FOR G.P.E. PCI/KG
COP1 = RADIONUCLIDE CONC IN PROCUCE CONSUMED BY MAN
FOR M.I.E. PCI/KG
COP2 = RADIONUCLIDE CONC IN PRODUCE CONSUMED BY MAN
FOR G.P.E. PCI/KG
COCMI1= RADIONUCLIDE CONC IN COW'S MILK FOR M.I.E. PCI/L
A-48
-------�
C COChI2= RADIONUCLIDE CONC IN COW'S MILK FOR G.P.E. PCI/L
C COGHI1= RADIONUCLIDE CONC IN GOAT'S MILK FOR h.I.E. PCI/L
C COGMI2= RADIONUCLIDE CONC IN GOAT'S HILK FOR G.P.E. PCI/L
C COMEAT= RADIONUCLIDE CONC IN BEEF CATTLE'S MEAT PCI/KG
DOUBLE PRECISION NUCLID,H3,C14
COMMON/CNTRL/NONCLD.MAXYR,TITLE*20).LOCATE(12).NYR1,NYR2,
& PCI1.PCT2.LEAOPT,IOPVUV.IOPSAT,IPRT1.IP&T2.IDELT.IXIS,
S IRRESl.IRRES2.LIND,IAVGl.IAVG2lRR,FTMECHFlNTYR(4), RAE1085
& UUATL.WUATA.WHATH.SWATL.SWATA.SWAIH.IVAP,IBSMT
COMMON/NUC/NOCLID(40),ATMASS(46).TRAH(40).SOAM(40).ATAM(40)I
I AQAM(40.1000),STAM<40>,POLO(40),POLB(40),CSUO).CW<40).
I SSTREM<40),SDEEP(40).AIRCON<40),YSO<40)fSOAVG<40),CON<40),
4 AQCON<40),STCON(40>,ATCON<40).AQAVG(40>.STAVG<40).DETU<40), ISINEUL
I ATAVG<40) FMC(40),FMG(40),DECAY<40),XKD(4.40)fSOL(40).
& FF(40)rRAUO),RU(40),BV(40),BR(40).DERATE(40),CWAT(40)
COMMON/IRRFOO/Yl.Y2fTEl,IE2.THl.TH2.TH3fTH4,TH5,TH6,FP,FS.
4 ULEAFY,UPROD,UCMILK.UGMILK,UHEAT.UUAT.UAIR.
i QFC,QFG.TF1,TF2,TS.CL1(40),CL2(40),CP1(40),CP2(40)I
& CCMIl(40)fCCMI2(40),CGMIl(40),CGMI2(40),
i CMEAT(40).COL1(40).COL2(40).COP1(40).COP2(40),
X COCMIl(40JfCOCMI2<40>,COGMlI(40),COGMI2(40>,
i COMEAT(40)'QING(40),QINH(40),POP.
& CSP(40),CSPT(40),CSPO(40),CSPOT(40)
COMMON/LAND/RAINF,ERODF.STPLNG.COVER,CONTRL.SEDELR.SOILOS.
i PORS,BDENS,DWEI,EXTENT,ADEPIH,PD,RUNOFF,RESAT,
COMMON/EVAP/PPN.PHID.P,XIRR,S<12),T(12),TD<12)fXINFL,SINFL,
& SMASS.UMASS,UDEEP
COMMON/EUNC/XAMBWE.TA.TU.FI.PP.WIRATE,
& QCU.QGU.QBU,ABSH,P14
COMMON/PCV/SOCON(40J
DATA H3,C14/8HH-3 ,8HC-14 /
IF(NUCLID(NN) .EQ. H3)GO TO 200
IF(NUCLID(NN) .EQ. C14) GO TO 300
DECA=DECAY(NN)/8760.
DECSL=SINFL/(0.15A(1.+BDENS/PORSAXKD(1.NN)))/8760.
CSPO(NN)=(CSPO(NN)+CWAT(NN)AWIRATEA8766.AFI)AEXP(-(DECA+DECSL)
8 A8760.)
B=0.243ABV(NN) RAE0186
TERM2=CSPO(NN)AB/PP RAE0186
C CALCULATION OF COPAST=RADIONUCLIDE CONCENTRATION IN PASTURE GRASS
C CONSUMED BY ANIMALS
COPAST=COVA(NN,Y1,1E1,TH1,TERM2.1.)
C CALCULATION OF COSTO = RADIONUCLIDE CONCENTRATION IN STORED FEED
C CONSUMED BY ANIMALS
B=0.68A(0.378ABR(NN)+0.622ABV(NN» RAE0186
IERM2=CSPO(NN)AB4PP RAE0186
COSTO=COVA(NN.Y1.TE1.TH2,IERM2.0.1>
C CALCULATION OF COEEEI) = RADIONUCLIDE CONCENTRATION IN ANIMAL FEED
COFEED=FPAFSACOPAST+(1.0-FPAFS>ACOSTO
C
CAAA CALCULATION OF COPLX = RADIONUCLIDE CONCENTRATION IN LEAFY
C VEGETABLE CONSUMED BY MAN
B=0.066ABV(NN) RAE0186
TERM2=CSPO(NN)AB/PP RAE0186
CAAA ]. FOR MAXIMUM INDIVIDUAL EXPOSURE
COL1(NN)=COVA(NN,Y2,TE2,TH3,TERM2,1.)
C
CAAA 2. FOR GENERAL POPULATION EXPOSURE
A-49
-------�
COL2(NN>=COVAAB/PP RAE018G
COPHNN)=COVA(NN,Y2,TE2,TH4,TERM2,0.1)
C
C
CAAA 2. FOR GENERAL POPULATION
COP2(NN)=COVA(NN.Y2,TE2.TH6.TERM2,0.1)
CUAT(NN)= WWATAAAQCON
C
CAAA 2. FOR GENERAL POPULATION
COCMI2(NN)=FMC(NN)A(COFEEDAQFC+CWAT(NN)AQCU)AEXP(-DECAATF2)
C
CAAA CALCULATION OF COGMIX = RADIONUCLIDE CONCENTRATION IN GOAT'S MILK
CAAA 1. FOR MAXIMUM INDIVIDUAL EXPOSURE
COGM11(NN)=FMG(NN)A(COE'EEDAQFG+CWAT
RETURN
C
CAAA CALCULATION FOR SPECIAL RADIONUCLIDE: TRITIUM
CAAA TRITIUM CONC. IN VEGETATION = TRITIUM CONC. IN ANIMAL FEED =
CAAA TRITIUM CONC. IN WATER = CUAT(l)
CAAA CALCULATION OF H-3 CONCENTRATION IN VEGETATION. MILK,
CAAA AND MEAT CONSUMED BY MAN
200 COL1(NN)=CWAT(NN)
COL2(NN)=CUAT(NN)
COP1(NN)=CWAT(NN)
COP2(NN)=CWAT(NN)
CWA1(NN)= WWATAAAQCON(NN)+SWATAASTCON(NN)
COCMI1(NN)=FMC(NN)ACWAT(NN)A(QFC+QCW)
COCMI2(NN)=COCMI1(NN)
COGMI1(NN)=FMG(NN)ACWAT(NN)A(QFG+QGW)
COGMI2(NN)=COGMI1(NN)
COMEAT(NN)=FF(NN)ACUAT(NN)A(QFC+QCW)
RETURN
300 C014=0. »
COL1(NN)=C014
COL2(NN)=C014
COP1(NN)=C014
COP2(NN)=C014
CWAI(NN)= WWATAAAQCON(NN)+SUATAASTCON(NN)
COCMI1(NN)=FMC(NN)AC014A(OFC+QCW)
COCMI2(NN)=COCMI1(NN)
COGMI1(NN)=FMG(NN)AC014A(QFG+QGW)
COGMI2(NN)=COGHI1(NN)
COMEAT(NN)=FF(NN)AC014A(QFC+QCW)
RETURN
END
A-50
-------�
c
c
c
FUNCTION COVA,STAM(40),POLO<40),POLB<40),CS<40>.CU(40).
& SSTREM(40),SDEEP<40).AIRCON<40).YSO(40)fSOAVG(40),CON<40).
i AQCON(40)>STCON(40),ATCON(40).AQAVGUO) ,STAVG<40> DETW(40), ISINEUL
& ATAVG<40) FMC<40).FfiG(40),DECAY<40).XKDJ4.40),SOL(40).
I FF(40>.RA(40).RW(40),BV<40>.BR<40),DERAIEUO>,CWAT(40)
COMMON/FUNC/XAMBUE.TA.TU.FI.PP.giRjTE,
t QCU,QGU,QBU,ABSH,P14
DECA=DECAY
RETURN
END
C
C
C
SUBROUTINE LEACH(NN,NYEAR,VOLB,VOLO,DMAX,CIOT,CFF,XDECN,
i TINFL,PERMT)
C
CAAA
CAAA
CAAA
CAAA
CAAA
CAAA THIS SUBROUTINE CALCULATES THE AMOUNT OF EACH RADIONUCLIDE
CAAA THAT LEAVES FROM THE BOTTOM OF THE TRENCH TO THE AQUIFER
CAAA AND THE AMOUNT THAT LEAVES AS A RESULT OF WATER OVERFLOWING THE
CAAA TRENCH. THIS SUBROUTINE IS CALLED BY MAIN.
CAAA
CAAA THERE ARE FIVE METHODS THAT MAY BE USED TO CALCULATE THESE
CAAA AMOUNTS. THEY ARE GIVEN BY THE FOLLOWING VALUES OF
CAAA LEAOPT:
CAAA 1 TOTAL CONIACT.CHEMICAL EXCHANGE
CAAA 2 IMMERSED FRACTION, CHEMICAL EXCHANGE
CAAA 3 TOTAL CONTACT, CHEMICAL SOLUBILITY
CAAA 4 IMMERSED FRACTION, CHEMICAL SOLUBILITY
CAAA 5 RELEASE FACTOR
CAAA
C
C INPUT VARIABLES
C
C NN NUCLIDE NUMBER
C NYEAR = CURRENT YEAR OF SIMULATION
C TAREA = AREA OF TRENCH
C TDEPTH = DEPTH OF TRENCH
C PORT = POROSITY OF TRENCH MATERIAL
C RELFAC = RELEASE FACTOR
A-51
-------�
C LEAOPT = LEACHING OPTION
C SOL = SOLUBILITY OF RADIONUCLIOE IN TRENCH
C DENCON = DENSITY OF UASTE
C VOLO = VOLUME OF WATER OVERFLOWING TRENCH
C VOLB = VOLUME OF UATER LEAVING BOTTOM OF TRENCH
C NONCLD = NUMBER UF NUCLIBES
C TRAM = AMOUNT OF NUCLIDE IN TRENCH
C OLDUAT = AMOUNT OF WATER IN TRENCH
C BILFAC = DILUTION FACTOR
C BMAX = MAXIMUM WATER DEPTH IN TRENCH
C XKD = CHEMICAL EXCHANGE COEFFICIENT
C
C OUTPUT VARIABLES
C
C POLB = AMOUNT OF EACH NUCLIDE LEAVING BOTTOM OF TRENCH
C POLO = AMOUNT OF EACH NUCLIDE OVERFLOWING TRENCH
C
C INTERMEDIATE VARIABLES
C
C CCWAI = CONCENTRATION OF NUCLIDE IN WATER
C FWET = WETTED OR IMMERSED FRACTION
C PULOUT = TOTAL AMOUNT Of NUCLIDE LEAVING TRENCH
C
C
DOUBLE PRECISION NUCLID
COMMON/CNTRL/NONCLD.MAXYR,TIILE<20).LOCATE(12),NYR1,NYR2,
S PCI1.PCT2.LEAOPT.IOPVWV.IOPSAT,IPRI1,IPRT2.IDELI.IXTS,
g IRRES1.IRRES2.LIND,IAVG1.IAVG2!RR,FTI1ECH,INTYR(4),
& WWATL.ttWATA,WWATH.SWATL.SWATA.SWATH.IVAP.IBSMT
COHMON/EVAP/PPN.PHID.P,XlRR,S<12)fT(12>,TDU2),XINFL,SINFL,
i SMASS.WMASS.WDEEP
COMMON/TRCH/TAREA.TDEPTH.OVER.PORT.RELFAC,DENCON.OLDWAT.FN
COMMON/NUC/NUCLID(40).ATMASS(40).TRAM(40).SOAM(40)IATAM(40).
S AGAM(40r1000).SIAM<40).POLO(40),POLB<40),CS(40).CW<40>,
& SSTREM(40).SDEEP(40).AIRCON(40).YSO(40)fSOAVG(40),CON(40).
S AQCON(40),STCON(40>.AICON<40).AQAVG(40)rSTAVG<40),DETW(40).
S ATAVG(40).FMC(40)IFMG(40).DECAY(40),XKD(4.40),SOL(40).
& FF(40),RA(40),RW(40).BV(4d),BR(40),DERATE(40),CWAT(40)
DIMENSION CIOT(40>,CINEWI<40)
DATA LUG/6/
IE(DMAX.LE.O.)CCWAT=0.
IF(DMAX.LE.O.)GOTO 600
C—
C— FOR OPTIONS 1 AND 3 ASSUME WETTED FRACTION
C— TO BE TOTAL CONTACT AREA.
C
FWET=1.
TCON=1.
GO TO <200,100.400,300,500),LEAOPT
WRITE(LU6.6000)1
6000 FORMAT*' ;,'AAA ERROR AAA - INVALID LEACHING PARAMETER')
RETURN
C
C FOR OPTION 2 USE IMMERSED FRACTION TO COMPUTE WETTED FRACTION.
C
100 FHEI=DMAX/TDLPTH
IF(FWET.GT.1.0)FWET=1.0
TCON=TINFL/PERHT
IF (ICON.GI.1.0) TCON = 1.0
IE(FWET.GE.1.0)TCON=1.0
A-52
-------�
FWAST=(DMAX-VOLB/(PORTATAREA))/(TDEPIH-OVER)
IF(FUAST.GT.1.0)FUAST=1.0
IFTCON=TCONA<1.-FWASI>+FWAST
IFABENCON»
IEMP=5.163E11ASOL(NN)ADECAY(NN)/ATMASS(NN)
IFCCCWAT.GT.TEMP.AND.SOL(NN).NE.O.O)CCWAI=TEMP
CCUAI=CCUAIACFF
GO TO 600
C
C FOR OPTION 4 WETTED FRACTION IS THE IMMERSED FRACTION.
C
300 FWEI=BMAX/IDEPTH
IF(EUET.GT.1.0)FUET=1.0
C
C tOR OPTIONS 3 AND 4 USE CHEMICAL SOLUBILITY
C
400 CCWAI=TRAM
-------�
CAAA THIS ROUTINE OUtPUlS AN ANNUAL SUMMARY FOR YEARS
CAAA REQUESTED BY USER INPUT. OUT IS CALLED BY MAIN.
CAAA
CAAA
CAAA
CAAA
C
C
C INPUT VARIABLES
C
C NYEAR = CURRENT YEAR OF SUMULATION
C PC FRACTION OF TRENCH CAP THAT HAS FAILED
C WDEPTH = MAXIMUM DEPTH OF WATER IN TRENCH
C
DOUBLE PRECISION NUCLID
COMMON/CNTRL/NONCLB.MAXYR,TIILE<20).LOCATE<12).NYR1,NYR2,
8 PCT1,PCI2,LEAOPT,IOPVWV.IOPSAT,IPRT1,IPRT2.IDELT.IXTS,
& IRRE§l.IRftES2.LIND,IAVGl,IAVG2!RR,FTHECH,INTYR(4), RAE1085
8 UWATL,HWATA,WWATHFSUAIL.SUArA,SHATH,IVAP,IBSMT
COMMON/NUC/NUCLIB<40),ATMASS(46).TRAM(40).SOAM(40),ATAM<40).
8 AQAM<40.1000),SIAM<40),POLO<40>,POLB(40),CS<40).CW<46).
8 SSIREM(40),SDEEP(40)lAIRCON(40),YSO(40)fSOAVG<40),CON(40).
8 AQCON(40)lSTCON(40),ATCON(40).AQAVG(40).STAVG(40).DEIU(40)f ISINEWL
8 ATAVG<40)fFMC<40).FMG<40).DECAY<40),XKD(4.40),SOL<40).
I FF(40),RAUO),RW(40),BV(40>,BR(40>,DERATE(40),CWAT(40)
DATA LU6/6/
URITE(LU&,6000)NYEAR
PER=100.APC
URIT£(LU6,6005)PER
URIIE(LU6,6010)UDEPIH
URITE(LU6,6015)VOLB,VOLO
WRITE(LU6,6020)
DO 10 I=1,NONCLD
WRITE(LU6,6025)NUCLID(I),TRAM(I),POLO(I)fPOLB(I),
& AQAM
-------�
8 /' '.13X 'SOIL CUNC',3X.'HATER CONG' ,4X, 'SIREAM' ,4X,
* 'DEEP LAYERS'.2X,'AT SPILLAGE',3X 'DOWN WIND',6X,'CONC',
* /' ',15X 'CI/KG'.SX.'CI/hAAS'. 9X.'CI',11X,
* 'CI' 8X ' CI J,2(5X,'i:i/MAA3')>
END
C
C
SUBROUTINE SOURCE(NUCL,CFT1,DCFI,FGAM,IRST,PERM!,RTGR,SSAT,XRIM)
CAAAAAAAA^AAAAAAAAAAAAAAAAAAAAAAAAAAAAAA^AAAAAAAAAAAAAAAAAAAAAAAAAAAAAAA
CAAA
CAAA THIS SUBROUTINE PERFORMS THE NECESSARY INPUTS TO INITIALIZE
CAAA PARAMETERS AND VARIABLES. SOURCE IS CALLED FROM MAIN.
CAAA
CAAA
CAAA
CAAA
DOUBLE PRECISION NUCLID,NU,NC,DAIE,DTIME
COMMON/SIREAM/DWS ISINEU
COMMON/CNTRL/NONCLD.MAXYR.TITLE(20).LOCATE(12).NYR1,NYR2,
I PCT1.PCT2.LEAOPT, IOPVUV.IOPSAT,IPRT1.IPRT2,IDELT.IXTS,
i IRRES1.IRRES2.LIND,IAVG1,IAVG2.RR,FTMECH,INTYR<4), RAE1085
i UUATL.UUATA.WHATH.SUATL.SUATA.SWATH.IVAP,IBSMT
COMMON/EVAP/PPN.PHID,P,XIRR,S(l2)fT(12)rTD(12)fXINFLfSINFLf
$ SMASS HMASS UDEEP
COMMON/TRCH/fAREA,fDEPTH,OVER.PORT,RELFAC,BENCON.OLDWAT,FN
COMMON/UATER/DTRAQ.DWELL,GUD,XLSATfSTFLOW,AQTHKfAQDISP,
& PORA PORV PERMV IAQSTF CPRJ
COMMON/NUC^NUCLlfi(40).AfMASS(40).TRAM(40).SOAM(40).ATAM<40).
& AQAM(40.1000),STAM(40),POLO(40),POLB(40),CSUO).CW(46).
S SSTREM(40),SDEEP(40).AIRCON(40)!YSO(40).SOAVG(40),CON<40).
& AQCON(40)FSTCON(40).ATCON(40)fAQAVG(40).STAVG(40).DETU(40)f ISINEUL
& ATAVG(40).FMC(40).FHG(40).DECAY(40).XKD(4.40),SOL(40).
4 FF(40).RA(40),RU(40).BU(40)rBR(40) ,DERATEUO),CWAT(40)
COMMON/LAND/RAINF,ERODF.STPLNG.COVER,CONTRL.SEDELR.SOILOS,
X PORS.BDENS,DUET,EXTENT,ADEPIH,PD,RUNOFF,RESAT,
COMMON/AIR/CHIQ.CHIQ2.DECOP(40),FACIIM,FTUIND.FTUND2,
& EVOLAT(40).H.HLID.IS.IT,POPDST,POPG,RE1,RE2,RE3,RINC,
S RMECH,ROUGH.U,VD,VG.XG
COMMON/IRRFOO/Yl.Y2,TEl'TE2.THl.TH2.TH3,TH4,TH5,TH6,FP,FS,
& ULEAFY.UPROD.UCMILK.UGMILKjUMEAT.UWAT.UAlR,
I QFC,QFG.TF1,TF2.TS.CL1(40).CL2(40),CP1(40),CP2(40),
S CCMI1(40),CCMI2(40),CGMI1(40),CGMI2(40),
& ' CHEA1(40).COL1(40).COL2(40).COP1(40),COP2(40),
J COCMIl(40>fCOCMI2(40),COGMIl(40),COGMI2(40)r
S COMEAT(40).QING(40).QINH(40).POP,
& CSP(40).CSPT(40),CSPO(40),CSPOT(40)
COMMON/FUNC/XAHBVJE.TA.TU.FI. PP. W IRATE,
S QCU.QGUfQBU.ABSH,P14
DIMENSION MONTHU2).DAT(20),NUCL<40>8)
DATA LU5/5/,LU6/6/.LU26/26/
C DATA MONTH/'JAN','FEB','MAR','APR','MAY','JUN','JUL'('AUG',
C i 'SEPVOCTVNOVVDEC'/
URI1E(LU6.2010)
5 READ
-------�
c
C CONTROL INFORMATION.
C
READ(LU26,3000)TI1LE
READ(LU26,3000)LOCATE
READ
INTYk(K)=INIYR(J)
INIYR(J)=I
30 CONTINUE
C
RAE1085
RAE1085
RAE1085
RAE1085
RAE1085
KAE1085
RAE1085
RAE1085
RAE1085
RAE1085
RAE1085
RAE1085
RAE1085
RAE1085
RAE1085
C-
C-
C-
C
C
C
C
C
IT RETURNS THE CURRENT
WRI1E(LU6.6000)
— IT1HE IS fART OF THE SYSTEM LIBRARY.
--- UALL TIME, ELAPSED TIH£, AND DATE.
CALL ITIMEdCLOCK. IDIFF.DATE, IDAT)
CLOCK=FLOAT(ICLOCK)/3&0000.
WRITE(LUG.6002)CLOCK.DATE
CALL CIIHE(DATE,DTIME>
URITE(LU6.6002) DTIME,DATE
URIIE(LU&,6005)TITLE
WRITE(LU6,6008)
URITE(LU6,6010)LOCATE
IF(NONCLD .GE. 1 .AND. NONCLD .LE. 40) GO TO 10
WRItE(LU6,6015)
STOP
10 CONTINUE
URITE(LU6,6020 )*iAXYR, NONCLD
URITE(LU6.6025)LEAOPT
IF(NYR1 .LT. NYR2)WRITE(LU6,6030)NYRl,PCTl,PCT2fNYR2
IFdOPVUV .EQ. DURrrE(LU6,6035)
IFdOPyUV .EQ. 0)HRITE(LU6,6040)
IFdOPSAT .EQ. 1)URITE(LU6'6045)
IFdOPSAT .EQ. 0)WRIIE(LU6,6050)
URIIE(LU6,6060)LIND
IF(LIND .EQ. 0)URI1E
-------�
IFdBSMT .GT. 0)URIIE
-------�
c
READ(LU26r3005)RAINF.ERODE.STPLNG.COVER,CONTRL,SEDELR
READ(LU2G,3005)PORS,BDENS,STFLOW,EXTENT,ADEPTH
READ(LU26,3005)PD,RUNOFF
C
URItE(LU6,6500)
WRITE(LUG 6505)RAINF.ERODF,SIPLNG,COVER,CONTRL,SEBELR
URri£SIFLOW,EXTENT,ADEPTH,PD
C AIR-FOODCHAIN INFORMATION
C
UR HE (LUG, 7800)
READ(LU26.3005)Y1.Y2.PP.XAMBUE,TA.TE1.TE2
READUU26 3005)THl,IH2,TH3,TH4,TH5.THG,FP.FS
READ(LU2&,3005)QFC,QEG,TFl,TF2fIS,ABSH,P14
READ(LU26,3005) XRTHfRTGR
WRITEFI,UIRATE,QCU,QGU,QBU
C
C HUMAN INGESTION AND INHALATION INFORMATION
C
READ(LU26,3005)ULEAFY,UPROD,UCMILK,UGMILK,UMEAT,UWAT,UAIR,POP
URITE(LU6,6905)
URITEdUb,6910)ULEAFYfUPROD,UCHILKTUGHILKrUhEAT,UWAT,UAIR,POP
C NUCLIDE INFORMATION
C
URITE(LU6.7000)
SMASS=1000.ABBENSAEXTENTAPDAADEPTH
WHASS=1000.APORSAEXTENTAPDAADEPTH
UDEEP=SINFLAEXTENIAPD
DO 40 I=1,NONCLD
READ(LU26f3012)NUCLID(I).(NUCL(I.K).K=1.8).TRAM(I),
X SOAM(I).ST&M(I)fATAM(I),DECAY(I)fSOL{l)rCON(I)
READ(LU26r3015)NUf(XKfi
-------�
WRIIE,BV
70 CONTINUE
RETURN
2005 FORMAK' ',20A4)
2010 EORMAK'1',5X,'AA INPUT DATA AS READ IN AA',/7)
3000 FORMAK20A4)
3005 FORMAK8F10.0)
3006 FORMAK2F5.0,7F10.0) ISINEU
3010 EORHAT(16I5)
3012 FORMAKA8,II,8A1.2X.7F10.0)
3015 FORMAKA8.2X;7F10.0)
6000 FORMAK'l',30X, 'PRESTO - A MODEL EOR PREDICTING THE',
& ' MIGRATION OF RADIOACTIVE WASTES'.
& /' '.40X 'FROM SHALLOW TRENCH BURIAL SITES')
C6002 FORMAK'0'f40XfJIHIS RUN WAS MADE AT ',E6.3,' ON ' A8)
6002 FORHAK'0',40X 'THIS RUN WAS MADE AT ',A8,' ON ',A8)
6005 FORMAK'0'.2(/J '.20X,20A4»
6008 EORMAK///1 ' bX,JAAA CONTROL INFORMATION AAA')
6010 EORMAK'0',lOX.'THE BURIAL SITE IS LOCATED AT ',12A4)
6015 tORHATCOVAAA ERROR :AAA INVALID NUMBER OF NUCLIDES')
6020 EORMAK' '.lOX.'THE SIMULATION WILL RUN FOR',15,' YEARS AND',
* ' WILL INCLUDE'.13.' NUCLIDES')
6025 FORMAK' '.10X.'LEACHING OPTION NUMBER', 12,' WILL BE USED')
6030 FORMAK' ''lOXl'IN YEAR' 14.' ,',F4.2.' OF THE CAP WILL BE',
i ' ASSUMED TO FAIL*./* ' 15Xf'IHIS WILL CONTINUE',
8 ' UNTIL '.F4.2.' HAS FAILED IN YEAR ',14.
X /' '.10X.?CAP HAY ALSO FAIL BY SURFACE EROSION')
6035 FORMAK' ' .10X. VERTICAL WATER VELOCITY WILL BE CALCULATED',
i ' USING INFILTRATION AND POROSITY')
6040 FORMAK' '.10X,'PERMEABILITY WILL BE USED FOR MINIMUM',
8 ' VERTICAL WATER VELOCITY')
6045 FORMAK' '10X.'LENGTH OF VERTICAL SATURATED ZONE WILL BE',
& ' CALCULATED USING INFILTRATION AND POROSITY')
6050 FORMAK' '10X,'LENGTH OF VERTICAL SATURATED ZONE WILL BE',
& ' SET TO THE TRENCH TO AQUIFER DISTANCE')
6055 EORMAK' ' lOX.'FROM YEAR ',14.' TO YEAR ',14.
I ' THE RESUSPENSION RATE DUE TO MECHANICAL DISTURBANCES',
I ' WILL BE '1PE11.4,/' ',15X,'THIS WILL OCCUR DURING ',
X F5.2.' OF E&CH YEAR*)
6060 FORMAK' ' ,10X, 'POPULATION INDICATOR IS '12)
6064 FORMAK' ''l5X!'MAXIMUM INDIVIDUAL EXPOSURE WILL BE USED',
i ' TO CALCULATE HEALTH EFFECTS')
6066 FORMAK' '15X 'QENERAL POPULATION EXPOSURE WILL BE USED',
i ' TO CALCULATE HEALTH EFFECTS')
6070 FORMAK' '.lOX.'THE POPULATION WILL BE EXPOSED TO CONTAMINATED ',
& 'MATERIALS FROM YEAR ',13,' TO ',14)
6072 FORMAK' ',10X,F6.3,' OF IRRIGATION WATER WILL BE GOTTEN FROM ',
I 'WELL'
8 /' ',10X,F6.3,' OF DRINKING WATER FOR ANIMALS WILL BE',
& ' GOTTEN FROM WELL'.
S /' '.10X.F6.3,' OF DRINKING WATER FOR HUMANS WILL'.
\ ' BE GOTTEN FROM WELL')
6074 FORMAK' ',10X,F6.3,' OF IRRIGATION WATER WILL BE GOTTEN FROM ',
A-59
-------�
o 'STREAM'
& /' vox,F6.3,' OF DRINK!NG WATER FUR ANIMALS WILL BE ',
£ 'GOTTEN FROM STREAM',
£ /' ' 10X.F6.3 ' OF DRINKING WATER FOR HUMANS WILL',
£ ' BE GOTTEN FROM STREAM')
6088 FORMATC ',10X,'BEGINNING IN YEAR ',14,', PEOPLE WILL LIVE ',
£ 'IN THE BASEMENT')
6200 FORMATC1',5X.'AAA TRENCH INFORMATION AAA')
6205 FORMAK//' ',10X.'THE TRENCH HAS AN AREA OF ',
£ Ell.4,' SQUARE METERS AND A DEPTH OF ',
I Ell.4.' METERS')
6210 FORMATC ',10X,'TRENCH POROSITY IS '18.2)
6215 FORMATC '10X.'ANNUAL INFILTRATION FOR THE WATERSHED IS',
£ F7 4 ' METERS')
6300 FORMAT*//5 ' 5X,'AAA AQUIFER INFORMATION AAA')
6305 FORMAK//' ',10X 'THE GROUND WATER HAS A VELOCITY OF ',F10.3,
I ' METERS PER YEAR')
6310 EORMATC ',10X,'TRENCH TO AQUIFER DISTANCE IS ',F6.1.' METERS')
6315 FORMATC ',10X,'TRENCH TO WELL DISTANCE IS ' F8.2 ' METERS')
6316 FORMATC ',10X,'WELL TO STREAM DISTANCE IS',F8.2.'METERS')
6320 FORMATC ' 10X/THE AQUIFER THICKNESS IS '.F8.2,f METERS'
i /' VOX 'THE AQUIFER DISPERSION ANGLE IS -,F8.4,' R
too* rnuMATf 'irtvf/ '
6325 FORMATC ',10X 'POROSITY OF THE AQUIFER REGION IS ',F8.5,
£ /' VOX.'POROSITY BENEATH THE TRENCH IS ',F8.^
• i. U • M • I ILi i. Lil\ tj /
F8.2,'METERS') ISINEW
RADIANS')
. 1V/A. rUKUO 1 1 1 DL.l11jl-l.LM J.I)Li XI\L,IXlvll ij . i U m >J ,
/' VOX 'PERMEABILITY BENEATH THE TRENCH IS ',F8.3,
£ ' METERS/YKAR')
6400 FORMAK//'1',5X 'AAA ATMOSPHERIC INFORMATION AAA')
6405 FORMAK//' ',10X 'SOURCE HEIGHT IS '.F6.1 ' METERS')
6410 FORMATC VOX.'VELOCITY OF GRAVITATION FALL IS ',
£ F6.2.' METERS/SECOND')
6425 FORMATC ',10X,'GAUGE DISTANCE FROM SOURCE IS ',F8.2,' METERS')
6420 FORMATC '10X,'DEPOSITION VELOCITY IS ' F6.2 ' METERS/SECOND')
6415 FORMATC ',10X,'WIND VELOCITY IS ',F6.2.J METERS/SECOND')
6435 FORMATC VOX,'LID HEIGHT IS ' F8.2 ' METERS')
6440 FORMATC ',10X,'HOSKER ROUGHNESS FACTOR IS ' F6.2)
6445 FORMATC ',10X,'TYPE OF STABILITY FORMULATION IS ',12,
£ /' ' 10X 'STABILITY CLASS IS ' 12)
6450 FORMATC ' !lOx!'FRACTION OF TIME WIN& BLOWS TOWARD POPULATION IS'
£ F10.6)
6460 FORMATC ',10X 'NORMALIZED DOWN WIND ATMOSPHERIC EXPOSURE PER ',
£ 'UNIT SOURCE AREA IS ' 1PE11.4,' CI/MAA3 PER CI/SEC')
6470 FORMATC ' 10X 'NORMALIZED DOWN WIND ATMOSPHERIC EXPOSURE PER ',
£ 'UNIT SOURCE AREA WILL BE CALCULATED INTERNALLY')
6480 FORMATC ',10X.'RESUSPENSION FACTOR PARAMETERS ',3(5X,E11.4))
6500 FORMAK//' ',5X 'AAA SURFACE INFORMATION AAA')
6505 FORMAK//' '10X.'PARAMETERS FOR UNIVERSAL LOSS EQUATION',
£ /' ',15X,'RAINFALL ',F8.2,
£ /; ;,15X,'ERODIBILIIY ,',F8.2,
£ /' '|l5X|'COVER b ','F8.'2j
£ /' ',15X,'EROSION CONTROL',F8.2.
£ /' ',15X,'DELIVERY RATIO ',F8.2)
6510 FORMATC VOX,'SOIL POROSITY IS ' F8.5.
£ /' VOX 'SOIL BULK DENSITY IS '.E8.5,' G/CC')
6515 FORMATC '10X.'RUNOFF FRACTION IS ',F8.5>
6520 FORMAK/' J,10X,
£ 10X 'STREAM FLOW RATE IS ' 1PE11.4 ' CUBIC METERS PER YEAR',
£ /' VOX. 'CROSS SLOPE EXTENT OF SPILLAGE IS ',OPF8.2,' METERS'
£ /' VOX,'ACTIVE SOIL DEPTH IS ' F8.2,' METERS',
£ /' VOX, 'AVERAGE DOWN SLOPE DISTANCE TO STREAM IS ',F8.2,
A-60
-------�
F10X,'SURFACE DENSITY FOR SOIL '.F10.2.' KG/MAA2',
,10X,'WEATHER DECAY CONSTANT',E1&.2,' I/HOURS'
,10X.'PERIOD PASTURE GRASS EXPOSURE GROWING SEASON',
F10.2,' HOURS',
I ' METERS')
7800 FORMAK'l',5X,'AAA AIR-EOODCHAIN INFORMATION AAA')
7805 FORMAK/' ', lOX,'AGRICULTURAL PRODUCTIVITY FOR GRASS',F10.2,
I ' KG/MAA2 ,
g /' ,10X,'AGRICULTURAL PRODUCTIVITY FOR VEGETATION',
g /'
I /'
g /'
o
& /' VOX/fERlolTckdP/VEGETATION EXPOSURE GROWING SEASON',
* £10.2,' HOURS')
7815 FORMAK' ' ,10X,'PERIOD BETWEEN HARVEST PASTURE GRASS AND',
X ' INGESTION BY ANIMAL' F10.2 ' HOURS',
g /' '.10X.'PERIOD BETWEEN STORED FEED AND INGESTION',
g ' BY ANIMAL'.E10.2,' HOURS',
g /' VOX. 'PERIOD BETWEEN HARVEST LEAFY VEGETABLES AND',
g * INGESTION BY MAN(M.I.E.)',F10.2 ' HOURS'.
g /' VOX.'PERIOD BETWEEN HARVEST PRODUCE AND INGESTION BY',
* ' HANCM.I.E.)' F10.2.' HOURS'
g /' VOX, 'PERIOD BETWEEN HARVEST LEAFY VEG '.
g 'AND INGESTION BY MAN'G.P.E.)'.F10.2,' HOURS',
g /' VOX. 'PERIOD BETWEEN HARVEST PRODUCE'
g ' AND INGESTION BY MAN'G.P.E.)' F10.2,' HOURS'
g /' '.10X,'FRACTION OF YEAR ANIMALS GRAZE ON PASTUREJ,F10.2
g /' VOX, 'FRACTION OF DAILY FEED THAT IS FRESH GRASS',F10.2,
g /' VOX, 'AMOUNT OF FEED CONSUMED BY CATTLE' F10.2,' KG')
7825 FORMAK' ' ,10X,'AMOUNT OF FEED CONSUMED BY GOATS',E10.2,' KG',
g /' VOX, 'TRANSPORT TIME FEED-hlLL-RECEPTOR FOR M.I.E.',
g F10.2.' HOURS',
g /' VOX, 'TRANSPORT TIME FEED-MILL-RECEPTOR FOR G.P.E.',
g t'10.2,' HOURS',
g /' '.10X,'TIME FROM SLAUGHTER OF MEAT TO CONSUMPTION',E10.2,
& ' HOURS',
g /' '.10X, 'ABSOLUTE HUMIDITY OF THE ATMOSPHERE',F10.2,
X ' G/MAA3'.
g /' ',10X,;ERACIIONAL EQUILIBRIUM RATIO FOR C-14',F10.2)
7900 FORMAK'!' 5X,'AAA WATER-FOODCHAIN INFORMATION AAA')
7905 FORMAK///' '.10X. 'FRACTION OF YEAR CROPS ARE IRRIGATED',F10.2,
g /' VOX, 'IRRIGATION RATE ' F10.3 ' L/(MAA2-H)'.
g /' VOX, 'AMOUNT OF WATER CONSUMED BY COWS ' F10.2 ' L/D'.
g /' ' 10X 'AMOUNT OF WATER CONSUMED BY GOATS '.F10.2,' L/D*
g /' '.10X,'AMOUNT OF WATER CONSUMED BY BEEF CATTLE ' F10.2,
g ' L/D')
6905 FORMAK///' ' 5X 'AAA HUMAN INGESTION AND INHALATION RATE',
g ' INFORMATION AAA')
6910 FORMAK/' '10X.'ANNUAL INTAKE OF LEAFY VEG ',F8.2,
g ' KILOGR6MS PER YEAR',
g /' '.lOXT'ANNUAL INTAKE OF PRODUCE ',F8.2,
g ' KILOGRAMS PER YEAR',
g /' ',10X, 'ANNUAL INTAKE OF COW'S MILK ',F8.2,
g ' LITERS PER YEAR',
g /' VOX, 'ANNUAL INTAKE OF GOAT"S MILK',F8.2,
& ' LITERS PER YEAR',
g /' VOX, 'ANNUAL INTAKE OF MEAT ' F8.2,' KILOGRAMS PER YEAR'
g /' VOX, 'ANNUAL INTAKE OF DRINKING WATER',F8.2,
g ' LITERS PER YEAR'
g /' ',10X.'ANNUAL INHALATION RATE OF AIR '.F8.2,
g ' CUBIC MEIERS PER YEAR' /' ',10X,'A POPULATION OF ',
g F10.0,' WILL BE CONSIDERED')
A-61
-------�
7005 FORMAIC ',A8,3X.9(1PE11.4,2X>)
7000 lORMAT('l'f5X.'AAA NUCLIDE INFORMATION AAA'.
i //' '50X.'INFORMATION ON INDIVIDUAL NUCLIDES'
i //' ','NUCLIDE',3X,'AMT IN TRENCH' 3X,'SPILLAGE',4X,
I 'STREAM AMT ' 2X.'AIR CONCEN',2X 'DECAY CONST'
I 2X,'SOLUBILITY CONST'.2X 'DECAY CORRECTION FACTOR'.
& /' ' 3X,3(12X,'Cr>,8X '£l/MAA3' 7X,'1/Y'.11X,'G/ML'>
7010 FORMAI
-------�
COMMON/EVAP/PPN.PHID,P,XIRR,S<12),T<12),TD<12),XINFL,SINFL,
$ SHASS UhASS UDEEP
COMMON/NUC/N6CLID(40),ATMASS(40).TRAM(40).SOAM(40).ATAM(40).
i AQAH(40.1000),STAM(40),POLO(40)fPOLB(40).CS(40).CU(40).
I SSIREM(40).SDEEP<40).AIRCON(40).YSO<40),SOAVG<40)fCON(40). ___.,_.„
i AQCON(40),§TCON(40),ATCON(40).AfiAVG(40) STAVG(40).DETU(40)r ISINEUL
S AIAVG<40),FMC<40),FMG(40).DECAY<40).XKD(4f40),SOL(40>.
& EF(40)fRA(40),RU(40).BV(40).BR(40).DERATE(40),CWAT(40)
COMMON/LAND/RAINF,ERODF,STPLNG.COVER.CONIRL.SEBELR.SOILOS,
I PORS,BDENS,DWEI,EXTENT,ADEPTH,PB,RUNOFF,RESAT,
& INSIIE
C
C
WSTREM=RUNOFFA(PPNAEXTENTAPD+VOLO)
SUAH=CS(II)ASMASS+CW(II)AWMASS/1.0E3
UMASS2=1000.A(PORSAEXIENTAPDAADEPIH+WDEEP+USTREM)
C
C COMPUTE NUCLIDE CONCENTRATION PER CUBIC MEIER OF UATER
C
CU(1I)=1000.ASUAM/(XKD<1,II)ASMASS+UMASS2)
C
C COMPUTE NUCLIDE CONCENTRATION PER KG OF SOIL
C
CS(Il)=CU(II)AXKD(l.II)A1.0E-3
SSTREM(II)=USTREMACU(II)
SOE£P(1I)=UDEEPACU(II)
RETURN
END
C
C
C
SUBROUTINE SUSPND(IYR,II,D1R,GNDCON,YS01,YS02)
C
C
CAAA COMPUTES AIR CONCENTRATION AND ATMOSPHERIC SOURCE TERM
CAAA AT SPILLAGE AREA. CALLED ANNUALLY BY MAIN.
CAAA
CAAA
CAAA
C
C
C
C INPUT VARIABLES
C
C IYR = CURRENT YEAR OF SIMULATION
C II CURRENT NUCLIDE
C SAREA = AREA COVERED BY SPILLAGE
C GNDCON= GROUND CONCENTRATION
C IRRES1= FIRST YEAR OF RESUSPENSION RATE
C IRRES2= LAST YEAR OF RESUSPENSION RATE
C RR RESUSPENSION RATE
C FTMECH=FRACTION OF YEAR FOR MECHANICAL DISTURBANCE
C U WIND VELOCITY
C
C
C
C INTERMEDIATE VARIABLES
C
C RE RESUSPENSION FACTOR
C YS01 = NORMAL CONTRIBUTION TO ATMOSPHERIC SOURCE
A-63
-------�
C YS02 = CONTRIBUTION 10 ATMOSPHERIC SOURCE FROM MECHANICAL
C DISTURBANCE
C
C
C OUTPUT VARIABLES
C
C AIRCON= AIR CONCENTRATION AT SPILLAGE AREA
C YSO = ATMOSPHERIC SOURCE AMOUNT AT SPILLAGE AREA
C
C
C
C ASSUME ALL RADIONUCLIDES DEPOSITED ON SOIL SURFACE AT
C TIME ZERO.
C
C
DOUBLE PRECISION NUCLID
COMMQN/CNIRL/NONCLD.MAXYR,TITLE<20), LOCATE<12).NYR1.NYR2,
& PCT1.PCT2.LEAOPT,IOPVUV.IOPSAT,IPRT1,IPRI2,IDELT.IXTS,
& IRRESl.IRRES2.LIND,IAVGl,IAVG2'RR,FI«ECH,INIYR<4), RAE1085
& UWATL.WWATA.WUATH.SWATL.SUATA.SWATH.IVAP,IBSMI
COMHON/NUC/NUCLID<40),AT«ASS<40).TRAM<40).SOAM(40).ATAM<40).
J AQAH(40.1000),STAH(40),POLO(40),POLB(40).CS(40).CU(46).
& SSIREM<40),SDEEP<40).AIRCON(40).YSO<40),$OAVG(40),CON<40).
& AQCON(40>FSTCON(40>,AICON(40).AQAVG<40>.STAVG(40>.BETW<40)f ISINEWL
S ATAVG(40),FMC(40)fFMG(40).DECAY(40),XKD(4,40),SOL(40).
i FF(40).RA(40).RW(40).BV(40).BR(40).DERATE(40).CUAT(40)
COMMON/LAND/RAINF,ERODF.STPLNG.COVERfCONTRL.SEDELR.SOILOS,
I PORS,BDENSFDWET,EXTENT,ADEPTH,PD,RUNOFF,RESAT,
£ INSITE
COMMON/A1R/CHIQ.CHIQ2.DECOP(40),FACTIM,FTWIND.FTWND2,
X FVOLAT(40),H,HLID.IS,IT,POPDST,POPG,RE1,RE2,RE3,RINC,
8 RMECH.ROUGfl.U.VDjOG.XG
COMMON/IRRFOO/Yl.Y2,TEl'TE2.THl.TH2.TH3,TH4.TH5.TH6fFP,FS,
& ULEAFY,UPROD'UCMILK,LIGMILK,UHEAT;UWAT.UAIR,
I QFC,QFG.TF1.TF2,TS.CL1(40),CL2(40),CP1(40),CP2(40),
I CCHI1(46),CCMI2(40),CGMI1(40).CGMI2(40).
& CMEAT(40).COL1<40),COL2(40).COP1(40).COP2(40).
X COCMI1(40),COCMI2(40),COGMI1(40),COGMI2(40),
8 COMEAT(40).QING(40),QINH(40),POP,
S CSP(40),CSPT(40),CSPO(40),CSPOT(40)
COMMON/XP/ARG,RES(10000)
L, —— — — —
C
C RESUSPENSION FACTOR BY ANSPAUGH ET AL
C
AIRCON(II)=RES(IYR)AGNDCON
HD=1.0
F = AKGAVG/U/flD
IF(E .GT. 1.) E=1.0
YS01=AIRCON(1I)AHDAUAARGAF
IFdYR .EQ. 1) GO TO 11
P _____
C THE FOLLOWING IS FOR RESUSPENSION DUE TO MECHANICAL
C DISTURBANCES
C
YS02=0.
IF (RR.GE.O.) GO 10 12
IF«IYR .GE. IRRES1) .AND. (IYR .LE. 1RRES2))
& YS02=CS(II)ARMECHAFTMECH
C
A-64
-------�
12 YSO
-------�
& PORS.BDENS,DUET,EXTENT,ADEPIH,PD,RUNOFF,RESAI,
& INSITE
VOLBT=0.
VOLQI=0.
PC=CAP(NYEAR>
DELT=0.1
DO 30 1=1,10
NEWUAT=IAREAAAPORT
VOLO=0.
IFAIAREA
VOLB=0.
IF(HDEPIH .LI. l.E-7)GO 10 20 mAi%M
VOLB=
-------�
c
c
c
c
c-
c-
c-
c-
c-
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
c
OUTPUT VARIABLES
AQAH = AMOUN1 OF NUCLIDE AT HELL SITE
DOUBLE PRECISION NUCLID
COMMON/CNIRL/NONCLD.MAXYR.TITLE(20).LOCATE(12>.NYR1.NYR2,
& PCT1.PCT2.LEAOPT,IOPVWV1IOPSAT,IPRT1.IPRI2.IDELT.IXIS,
i IRRESXlR*ES2.LIND.IAVGl,IAVG2lRR.FTHECH,INTYR<4J, RAE1085
i WWATL.HUATA.UWATH.SWAfL.SWAIA.SWAIH.IVAP.IBSMI
COMMON/NUC/NUCLID<40).ATHASS<40).IRAfi(40).SOAM(40).ATAM<40). -
S AQAH(4011000),STAM(40),POLO(40),POLB(40).CS(40).CW(40).
& SSTREM<40),SDEEP<40>.AIRCON(40).YSO(40),SOAVG<40),CON<40).
& AQCON(40).STCON<40>,ATCON<40) .AQAVG(40> .STAVGUO) .DEIW<40), ISINEUL
I ATAVG(40).FMC(40).FMG(40.).DECAY<40),XKD(4.40>,SOL(40).
& FF(40).RA(40).RU(40).BV(40),BR(40)IDERATE(40),CWAI(40)
DIMENSION IIIME(40),DDEIA(46)
CALCULATE CORRECT POSITION IN ARRAY AND DECAY THE MATERIAL
FOR THE PERIOD OF TIME MATERIAL IS IN TRANSIT FROM TRENCH
TO WELL.
ITMP=ITIME(II)
IF«NYEAR+IIMP) .61. (MAXYR) .OR. IIMP .LT. 0) GO TO 10
AQAM(II.NYEAR+ITIM£ + ISIMOD
g SDEEP(II))ADDETA(II)
10 CONTINUE
RETURN
END
SUBROUTINE QUANC8(FUN,A,B,ABSERR,RELERR,RESULT,ERRESI,NOFUN,FLAG)
REAL FUN ,A.B,ABSERR,RELERRTRESULTfERRESTTFLAG
INTEGER NOFUN
ESTIMATE THE INTEGRAL OF FUN(X) FROM A TO B
TO A USER PROVIDED TOLERANCE.
AN AUTOMATIC ADAPTIVE ROUTINE BASED ON
THE 8-PANEL NEUTON-COXES RULE.
INPUT
FUN THE NAME OF THE INTEGRAND FUNCTION SUBPROGRAM FUN(X)
THE LOUER LIMIT OF INTEGRATION
B THE UPPER LIMIT OF INTEGRATIONS MAY BE LESS THAN A)
RELERR A RELATIVE ERROR TOLERANCE. (SHOULD BE NON-NEGATIVE)
ABSERR AN ABSOLUTE ERROR TOLERANCE. (SHOULD BE NON-NEGATIVE)
OUTPUT
RESULT AN APPROXIMATION TO THE INTEGRAL HOPEFULLY SATISFYING THE
LEAST STRINGENT OF THE TUO ERROR TOLERANCES.
ERREST AN ESTIMATE OF THE MAGNITUDE OF THE ACTUAL ERROR.
NOFUN THE NUMBER OF FUNCTION VALUES USED IN CALCULATION OF RESULT.
FLAG A RELIABILITY INDICAITOR IF FLAG IS ZERO. THEN RESULTPROBABLY
SATISFIES THE ERROR TOLERANCE. IF FLAG IS
XXX.YYY. THHEN XXX = THE NUMBER OF INTERVALS UHICH HAVE
NOT CONVERGED AND O.YYY = THE FRACTION OF THE INTERVAL LEFT
TO DO WHEN THE LIMIT NOFUN WAS APPROACHED.
REAL WO,W1,W2,W3,W4,AREA,XO,FO,STONE,STEP,CORllrTEMP
A-67
-------�
REAL QPREV,QNOU,QDIFF,QLEFT,ESIERR,TOLERR
REAL QRIGHt(31).F<16) X(16)'FSAVE(8.30).XSAVE<8.30)
INTEGER LEVMIN,LEVhAX,LEVOUT,NOhAX,NOFINfLEVfNIH,IfJ
C
C AAA STAGE 1 AAA GENERAL INITIALIZATION
C SET CONSTANTS
C
LEVMIN = 1
LEVMAX = 30
LEVOUT = 6
NOHAX = 5000
NOFIN = NOMAX - 8A(LEVMAX-LEVOUT+2AA(LEVOUH-1))
C
C 1ROUBLE WHEN NOFUN EQUALS NOFIN
C
yO = 3956.0/14175.0
Ul = 23552.0/14175.0
W2 = -3712.0 / 14175.0
U3 = 41984.0/14175.0
W4 = -18160.0 / 14175.0
C
C INITIALIZE RUNING SUMS TO ZERO
C
FLAG = 0.0
RESULT =0.0
COR11 = 0.0
ERRESI = 0.0
AREA = 0.0
NOFUN = 0
IF(A .EQ. If ) RETURN
C
C AAAAA STAGE 2 AAAA INITIALIZATION FOR FIRST INTERVAL
C
LEV = 0
NIH = 1
XO = A
X(16) = B
QPREV = 0.0
EO = FUN(XO)
STONE = (B-A)/16.0
X(8) = (XO + X(16))/ 2.0
X<4) = (XO + X(8))/2.0
X(12) = (X(8) ^ X(16))/ 2.0
X(2) = (XO < X(4)) / 2.0
X(6) = (X(4) ^ X(8» / 2.0
X(10) = (X(8) + X(12)) / 2.0
X(14) = (X(12) + X(16»/ 2.0
C
DO 25 J=2.16.2
F(J) = FUN(X(J>1
25 CONTINUE
C
NOFUN = 9
C
C AAAAA STAGE 3 AAA CENTERAL CALCULATION
C REQUIRES QPREV,X10.X2,X4. .X16,FO,F4. F16
C CALCULATIES XI.X3,X5...Xl5, F1,F3,.. ,F15,GLEtIfQRIGHT
C QNOW,ODIFF,AREA. ' ' '
30 X(l) = (XO + X(2)) / 2.0
A-68
-------�
F(l) = FUN(XU))
DO 35 J = 3, 15, 2
X(J) = (X(J-1> 4- X(J+1)> / 2.0
F(J) = FUN(X(J))
35 CONTINUE
NOFUN = NOFUN 4 8
STEP = (X(16) - XO) / 16.0
QLEFI = 4- W1A(F(1) + F(7)) + W2A(F<2) < F(6))
& 4- U3A(F(3)4-F(5» 4- U4AF(4) )ASTEP
HOLTM1=ABS(QLEFT)
IF(HOLTM1 .EQ. 0.0) GO TO 183
IF(HOLTM1 .GI. l.OE-65) GO TO 183
QLEFT=0.0
183 QBIGHT(LEV+1)=(UOA+U1A 4- W4AE(12»ASTEP
HOL1M2=ABS(QRIGH1(LEV+1))
IF(HOLXM2 .£Q. 0.0) GO TO 184
IF(HOLTM2 .Gt. l.OE-65 ) GO TO 184
QRIGHI(LEV+1>=0.0
184 QNOM = QLEFT 4- QRIGHKLEV4-1)
QDIFF = QNOU - QPREV
195 AREA = AREA + QDIFF
C
C AAAA STAGE 4 AAA INTERVAL CONVERGENCE TEST
C
ESTERR = ABS(QDIFF) / 1023.0
TOLERR = AHAXKABSERR,R£LERRAAfiS(AfiEA)) A (STEP/STONE)
IFCLEV .LT. LEVMIN) GOTO 50
IF (LEV .GE. LEVMAX) GO TO 62
IF(NOFUN .GT. NOFIN) GO TO 60
IF(£STERR .LE. TOLERR) GO TO 70
C
C AAAA STAGE 5 AAA NO CONVERGENCE
C
C LOCATE NEXT INTERVAL
C
50 HIM = 2ANIH
LEV = LEV + 1
C
C STORE RIGHTHAND ELEMENTS FOR FUTURE USE
C
DO 52 I = 1.8
ESAVE(IfL£V5 = f(I 4- 8)
XSAVE(I.LEV) = X(l4-8)
52 CONTINUE
C
C ASSEMBLE LEFT HAND ELEMENTS FOR IMMEDIATE USE
C
QPREV = QLEFT i
DO 55 I = 1,8 '
J = -I
F<2AJ4-18) = FU+9)
X(2AJ+18) = X(J+9)
55 CONTINUE
GO TO 30
C
C AAAA STAGE 6 AAA TROUBLE SECTION
C
C NUMBER OF FUNCTION VALUES IS ABOUT TO EXCEED LIMIT
A-69
-------�
60 NOFIN = 2ANOFIN
LEVMAX = LEVOUT
C IHM?1=B-A
FLAG = FLAG+(B-XO)/(B-A)
GO TO 70
C CURRENT LEVEL IS LEVMAX.
C
62 FLAG = FLAG + 1.0
C
C
C AAAASIAGE 7 AAA INTERVAL CONVERGED
C ADD CONTRIBUTIONS INTO RUNNING SUMS
C
C
70 RESULT = RESULT + QNOW
ERREST = ERRESI + ESTERR
COR11 = COR11 + QDIEF / 1023.0
C
C LOCATE NEXT INTERVAL
C
72 IF (NIM .EQ. 2A
-------�
C FCN IS CALLED BY QUANC8.
C
IMPLICIT REALA8 NRL.NRU1IDIST(20),lLOC,JLOC
COMMON/COMOR/ORGN(20).NORGN,TIME(20),DOSE(20,40.4,2), DTABLE(7)
COMMON/LETEAC/HLET(20),LLET(20)
COMMON/COMCA/CANC(20),NCANC,RELABS(20),RISK(20,40,4.2), RTABLE(7),
> AGEX.YRLL(20.40.4.2)
COMMON/COMRF/REE(26.40.4).FTABLE<7)
COMMON/COMNU/NUCLIDt405,NONCLD,PSIZE(40),RESP(40),GIABS (4,40),
> INDPOP » ' ' '
COMMON/COMLOC/RNLOC(10).OGLOC(10),PTLOC(10),FALOC(10),
> HLLOC(10).LTAfiLE(10),NTLOC
COMMON/COHGEN/GEN(3),NGEN.GDOSE(3.40,4,2),GRISK(3.40.4,2),
> GENEFF,GRFAC(2),REPPER,GLLET(3),GHLET(3).GREF(3,40.4)
COMMON/COMRN/OREP(20),RREP(20),CREP(20),IJLRN(20,20),
A RRISK.RREF(2).RYRLL.NOREP,NRREP,NCREP
COMMON/COMUS/ARRAY(2200)
C
C TRANSFER TO 33 IE DOSE CALCULATION; ELSE CONTINUE WITH INPUT
Lr
A-71
-------�
IF (IFLAG.GT.O) GO TO 33
C
CAAA SET DEFAULT VALUES.
OUXPUT=.TRUE.
ILOC=0
JLOC=0
PLOC=100.
AGEX=70.7565
REPPER=1.41330E-2
GSCFAC=.5
NORGN=0
NCANC=1
CANC(1)=TOTBOD
ILEI(1)=0
ILEI<2)=2
DO 10 J=l,7
DIABLE(J)=0
RTABLE(J)=0
FTABLE(J)=0
10 CONTINUE
RIABLE<6)=4
ILET(1)=1
ILET(2)=1
DO 20 J=1.20
TIMEU)=76.
HLET(J)=20.
LLE1(J)=1.
RELABS(J)=1.
20 CONTINUE
NGEN=0
NOREP=4
NCREP=1
NRREP=0
RREPS<1)=P0218
RR£PS(2)=PB214
RREPS(3)=BI214
RREPS(4)=P0214
CREP<1)=PULMO
OREP(1)=LUNGS
OREP(2)=NDP
OREP(3)=TDP
OREP(4)=PUL
READ(26,11700) TITLE
URITE<6,10000) TITLE
READ(26.INPUT)
IF (PLOC.NE.O) WRITE(6,10100)PLOC
IF (ILET(1).EQ.O.OR.ILET(1).EQ.2) URIlE(6y10200)
IE (ILET(1).EQ.1.0R.ILET(1).EQ.2) URITE(6,10300)
IF (ILET(2).EQ.O.OR.ILET(2).EQ.2) URITE(&,10400)
IF (ILEI(2).EQ.1.BR.ILEI(2).EQ.2) URITE(6,10500)
URITE(6.10600) DTABLE.RTABLE,FTABLE
URITE(6,11900) GSCFAC
CAAA READ IN ORGAN PARAMETERS
40 READ(26rORGAN)
WRITE(6,10700) NORGN
WRITE(6,10800) NORGN)
CAAA READ IN CANCER PARAMETERS
A-72
-------�
50 READ(26,CANCER)
WRIItffi,11000) NCANC
WR HE < 6,11100) (CANC(1),RELABS(I),1=1,NCANC)
CAAA READ IN GENETIC PARAMETERS
READ(26,GEN1IC)
IF(GENEFF) HRITE<6,11800) NONCLD5
DO 30 1=1,NONCLD
DO 25 K=1.4
IF(NUCLID(I).EQ.RREPS(K)) GO TO 27
25 CONTINUE
GO TO 30
27 NRREP=NRREP+1
RREP(NRREP)=RREPS(K)
30 CONTINUE
NTLOC=0
READ(26,LOCTBL)
IF(NTLOC.EQ.O) GO TO 55
URITE(6,11305) NTLOC
WRITE(6,11310) (RNLOC(I),OGLOC(I),PTLOC(I),FALOC(I),HLLOC(I),
> I=1.NTL6C)
55 CONTINUE
11305 FORHATCO',12,' LOCATION TABLES ARE TO BE OUTPUT FOR:'/
> ' NUCLIDE ORGAN PATHWAY QUANTITY LET'/
> ' OR CANCER'/)
11310 FORMAT(1X,A8,1X.A8,4X,I2,7X,I2.7X,I2)
CAAA READ IN LOSE RATES AND HEALTH RISKS
CALL RDSTOR(OUTPUT)
IF(NORGN.NE.O) CALL RDORGF
C
C END OF DARTAB INPUT; RETURN
C
RETURN
C
C
C BEGIN DOSE CALCULATIONS
C
C
CAAA CHOOSE LOCATION AND FIND EXPOSURES
C
33 CALL CHLOC(PLOC,CONC.GSCFAC.IFLAG)
IF ( IFLAG .NE. 1 ) CALL SUMhRY(TITLE,GSCFAC,IFLAG)
C RETURN IF ANNUAL SUMMARY OR MAXIMUM DOSE CALCULATION
A-73
-------�
IF ( IFLAG .EG. 2 ) RETURN
IF ( IELAG .EQ. 3 ) RETURN
C
IF (NORGN.LE.O) GO TO 70
CAAA DECIDE IE LOU AND HIGH LET ARE TO BE SEPARATE TABLES
CAAA AND THEN OUTPUT TABLES
IDO=0
DO 60 J=l,7
IE (DIABLE(J).NE.O) IDO=1
TABLE(J)=DTABLE(J)
60 CONTINUE
IE(NTLOC.EQ.O .OR. IDO.EQ.l) GO TO 67
DO 65 J=1,NILOC
IF(EALOC(J).EQ.1)IBO=1
65 CONTINUE
67 CONTINUE
CAAA ILET = 0 MEANS ONLY TABLES FOR LOW AND HIGH LET SEPARATELY
CAAA ILET = 1 MEANS ONLY A TABLE FOR LOW AND HIGH LET COMBINED
CAAA ILET = 2 MEANS BOTH SETS OF TABLES
IF (IDO.EQ.l) CALL PREPDRdABLE, ILEX(l) ,fIIL£,GSCFAC, IELAG)
C RETURN IF PATHWAY DOSE CONVERSION FACTOR CALCULATION
C
IF ( IFLAG .EQ. 1 ) RETURN
C
C
70 IDO=0
DO 80 J=l,7
IF (FIABLE(J).NE.O) IDO=1
80 TABLE(J)=FTABLE(J)
IF(NTLUC.EQ.O .OR. IDO.EQ.l) GO TO 87
DO 85 J=1,NTLOC
IF(EALGC(J).EG.3) 1DO=1
85 CONTINUE
87 CONTINUE
IE (IDO.fcQ.l) CALL PREPRE(TABLE,TITLE.GSCEAC.IFLAG)
CAAA OUTPUT RISK TABLES
IDO=0
DO 90 J=1.7
IF (RIABLE(J).NE.O) 1DO=1
90 TABL£(J)=RIABLE(J)
IF(N1LOC.EQ.O .OR. IDO.EQ.l) GO TO 97
DO 95 J=1,NTLOC
IF(EALOC(J).EQ.2)IDO=1
95 CONTINUE
97 CONTINUE
IF (IDO.EQ.l) CALL PREPHRdABLE, ILEH2) ,IITLEfGSCFAC, IFLAG)
RETURN I
10000 FORMATC1'.20A4>
10100 EORMATC TABLES FOR THE SELECTED INDIVIDUAL WILL BE DONE FOR'.
>' THE LOCATION HAVING' F8.2,' % OF THE HIGHEST TOTAL RISK.'/}
10200 FORMAIC DOSE RATE TABLES FOR LOW AND HIGH LEI WILL BE '.
y 'PRINTED SEPARATELY ')
10300 FORMATC DOSE RATE TABLES COMBINING LOW AND HIGH LET '.
> 'WILL BE PRINTED.')
10400 FORMATC HEALTH RISK TABLES FOR LOW AND HIGH LET WILL BE '.
> 'PRINTED SEPARATELY.') '
10500 FORMATC HEALTH RISK TABLES COMBINING LOW AND HIGH LET '.
> 'WILL BE PRINTED.')
A-74
-------�
10600 EORMAK'OO INDICATES THE TABLE UILL NOT BE PRINTED'/
A' 1 INDICATES INDIVIDUAL VALUES UILL BE PRINTED'/
B' 2 INDICATES HEAN INDIVIDUAL VALUES UILL BE PRINTED'/
C' 3 INDICATES COLLECTIVE VALUES UILL BE PRINTED'/
D' 4 INDICATES ALL OF THE ABOVE UILL BE PRINTED'//
> ; QUANTITY TABLE NO. 123456 T/f
> '+i:50SE~RfiXES 777n271XT7
> ' 2.HEALTH RISKS ',7(12,1X)/
> ' 3.RISK EQUIVALENT FACTOR '7(12,IX))
10700 FORMAK'OIHERE ARE ',14 ' ORGANS TO BE OUTPUT. THEY ARE:'/)
10800 EORMAKIX.'ORGAN',4X 'TIME',4X,'ORGAN',4X,'TIME',4X,
I'ORGAN'^X/IIME'/
> <3(1X. A8,2X,F4.0,2X»)
10900 FORMAT!'o ORGAN DOSE EQUIVALENT FACTORS •/
A ' LOU LET HIGH LET'/
A (2X.A8.F15.5.1X.F15.4))
11000 FORhAK'OTHERE ARE ',14,' CANCERS TO BE OUTPUT.'/
> ' A 1 INDICATES ABSOLUTE RISK; A 2 IS RELATIVE RISK.')
11100 FORMATC CANCER CANCER CANCER CANCER'/ (1X,4(A8,
> 1X.F2.0.1X)))
11200 FORHATCOIHERE ARE ',14,' RADIONUCLIDES TO BE OUTPUT.')
11300 FORMATC NUCLIDE PARTICLE SIZE CLEARANCE CLASS '.
> 20X 'G.I. ABSORPTION FRACTION'/49X,'STOMACH' 8X.'SIJ,13X,'ULI',
> m.'LLI'/ (1X,A8,1X,F10.5,6X,10X,A1,4X,4F15.5))
11700 EORMAf(20A4)
11900 FORMAK'OIHE GROUND SURFACE CORRECTION FACTOR IS ',F5.2/)
END
C
C
C
C
SUBROUTINE RDSIOR(OUTPUT)
CAAA THIS SUBROUTINE READS AND STORES DOSE RATES
CAAA AND HEALTH RISKS FOR ORGANS AND CANCERS
REALA8 NUC.NUCLID.ORGN,CANC,0,C,OG,GEN,OREP,CREP,RREP
LOGICAL GENEFF.OUTPUT
COMMON/COMOR/ORGN<20>.NORGN.IIME<20),DOSE(20.40,4,2). DTABLE(7)
COMMON/COMRN/OREP(26),RREP(20),CREP<20),ULRN<20,20),
A RRISK,RREF(2).RYRLL,NOREP,NRREP.NCREP
COHMON/COMCA/CANC(20).NCANC,RELABS(20),RISK(20.40.4,2). RTABLE(7).
> AGEX,YRLL(20,40,4,25 ' ' ' ' '
COMMON/COMRE/REF(20f40.4).FTABLE(7)
COMMON/COMNU/NUCLID(40),NONCLD,PSIZE(40),RESP(40)rGIABS (4,40),
> INDPOP
COHMON/COMUS/C(40).0(40).D(2,40),R(2.40),RF(40).YLL(2,40),
> G(2,3),OG(3).aCHK(20,46),RCHK(20,40),GCHK(3,40)
COMMON/COMGEN7GEN(3),NGEN.GDOSE(3.40,4.2).GRISK(3,40,4,2),
> GENEFF.GREAC(2),REPPER,GLLET(3),GHLET(3),GREF(3,40,4)
DIMENSION GIIN(4) ' '
LOGICALA1 FAL,IRU,DCHK,RCHK,GCHK,IW
DATA TRU/.TRUE./.FAL/.FALSE./
CAAA ZERO OUT ALL ARRAYS
NDO=NORGN+1
DO 35 N=l,2
DO 30 J=l,4
DO 30 K=1,NONCLD
DO 10 L-llNDO
DOSE(L,K,J.N)=0.0
IF(L.GT.NGEN) GO TO 10
A-75
-------�
GDOSE(L,K,J,N)=0.0
10 CONTINUE
NDO=NCANC+1
DO 20 L=1.NDO
RISK(L.K,J,N)=0.0
YRLL(L.K,J,N>=0.0
REF(L.K,J)=0.0
IF(L.GI.NGEN) 60 TO 20
GRISK(L.K,J,N)=0.0
GREf(L,KfJ)=0.0
20 CON1INUE
30 CONTINUE
35 CONTINUE
DO 38 L=l,40
DO 37 K=l,20
DCHK(K,LJ=TRU
RCHK(K.L)=TRU
37 CONTINUE
DO 39 K=l,3
GCHK(K,L)=IRU
39 CONTINUE
38 CONTINUE
CAAA READ FIRST RECORD
41 READC25,ENB=180) NUC,SIZEIN,RESPIN,GUN,TIMIN, IND
IFIND=0
CAAA CHECK 10 SEE IF THE RADIONUCLIDE IS IN OUTPUT LIST
DO 50 K=1,NONCLD
IF (NUC.EQ.NUCLID(K)) GO TO 60
40 CONTINUE
50 CONTINUE
IF(IEIND.EQ.O)GO TO 125
GO TO 41
CAAA FIND OUT WHAT 1YPE OF RECORD FOLLOWS
60 IRA=IND/10
IF(IRA.GI.2) GO TO 401
ICHOS=IND-IRAA10
IF (ICHOS.NE.2) GO TO 75
DO 70 L=l,4
IF (ABS(GIIN(L)-GIABS(L,K)).GI.l.E-6) GO TO 40
70 CONTINUE
75 IE (ICHOS.NE.3) GO TO 80
IF (ABS(SIZEIN-PSIZ£(K».GT.l.E-6> GO TO 40
IF (RESPIN.NE.RESP(K)) GO TO 40
80 IF (IND.LE.5) GO TO 130
CAAA THE NEXT TWO RECORDS CONTAIN CANCERS AND RISKS
IFdFIND.NE.O) GO TO 81
READ(25) NC.ILEI.(C(I),I=1.NC)
READ(25) ((R(L.D.L=1,ILE1),I=1,NC)
READ(25) «YLLaFI).L=l,ILEl),i=l,NC)
READ(25)(RF(I)U = 1,NC),TRF
81 IFIND=1
REF(NCANC+l,K,ICHOS-l)=l:RF+REF(NCANC+l,Kf ICHOS-1)
CAAA CHECK TO SEE IE THE CANCER IS IN OUTPUT LIST
DO 110 1=1.NC
DO 90 J=1,NCANC
IF
-------�
CAAA A MATCH. STORE THE RISK
RCHK(J,K>=FAL
RISK(J.K,ICHOS-1,1)=R<1.I)
YRLL(JFK,ICHOS-1,1)=YLL(1,I)
IF (ILET.LE.l) GO TO 105
RISK DUM
READ<25,END=180) DUM
GO TO 41
CAAA THE NEXT TWO RECORDS CONTAIN ORGANS AND DOSE RATES
130 IF(IFIND.NE.O) GO TO 131
READ(25) NO.ILET.(0(I),I=1,NO)
READ(25) «D,I = 1,NO)
131 lt'lND=l
CAAA FOR INTERNAL DOSES. ALSO CHECK OTHER NUCLIDE PARAMETERS
CAAA CHECK TO SEE IF THE ORGANS ARE ON OUTPUT LIST
140 DO 170 I=1,NO
DO 150 J = KNORGN
IF (O(I).EQ.ORGN(J)) GO TO 160
150 CONTINUE
GO TO 170
CAAA A MATCH SO STORE THE DOSE
160 IFdND.GI.3) GO TO 159
IF(ABS(TIMIN-TIME(J)).GI.l.E-6) GO TO 40
159 DOS£(J,K.IND-1.1)=D(1,I)
IF (ILEI.GT.l) DOSE(JfK,IND-l,2)=D(2rI)
DCHK(J,K)=FAL
IF(1ND.NE.3) GO TO 170
DO 162 L=1.NRREP
IF(NUCLID
-------�
DO 152 J=1,NGEN
IF(0(I).£Q.GEN(J» GO TO 161
152 CONTINUE
GO TO 172
161 GDOSEA30.
172 CONTINUE
GO 10 40
CAAA DOSES HAVE BEEN SKIPPED OR STORED, GO TO NEXT RECORD
180 CONTINUE
IW=TRU
DO 200 K=1,NONCLD
DO 200 J=1,NORGN
IF(.NOI.DCHK(JFK)) GO TO 200
IE(IM) HRrrE<6.900)
URIIE(6,901) ORGN(J),NUCLID(K)
IU=FAL
200 CONTINUE
900 FORHATCO THE FOLLOWING NUCLIDES AND ',
< 'ORGAN DOSE FACTORS WERE NOT FOUND',
> ' IN THE INPUT DATA SETS:'/
> ' ORGAN NUCLIDE'/)
901 EORHATUX,A8,1X,A8)
IW=TRU
DO 300 K=1,NONCLD
DO 300 J=I,NCANC
IF(.NOI.RCHK ' IN THE INPUT DATA SETS:'/
> ' CANCER NUCLIDE'/)
yRITE(6,901) CANC(J),NUCLID(K)
300 CONTINUE
IF(.NOT.GENEFF) RETURN
IU=TRU
DO 400 K=1,NONCLD
DO 400 J=1,NGEN
IF(.N01.GCHK(J,K)) GO 10 400
IF(IW) WRITE(6F903)
IU=FAL
903 FORMATCOTHE FOLLOWING NUCLIDES AND ',
< 'GENETIC DOSE FACTORS WERE NOT'.
> ' FOUND IN THE INPUT DATA SETS:7/
> ' GEN.DOSE NUCLIDE')
WRITE<6,901) GEN(J),NUCLID
-------�
GRISK<1.K.I.L)=GDOSE<3,K,I,L)AGRFAC/<30.AGRFAC(l))
705 CONTINUE
IF(OUTPUl) CALL FACOUT
RETURN
401 IF<1RA.NE.9) GO TO 800
ICHOS=0
IFUND.EQ.98) 1CHOS=3
IFUND.EQ.99) ICHOS=2
IF(ICHOS.EQ.O) GO TO 125
IF(.NOT.GENEFF) GO TO 125
IF(ICHOS.NE.2)GO TO 507
DO 505 L=1.4
505 IF GO TO 40
510 IF
IF(LET.GT.l) GDOSE(J,K,ICHOS-1,2)=G(2,I)
GCHK(J.K)=FAL
530 CONTINUE
GO 10 40
800 IF(IND.NE.33) GO TO 125
READ(25) NC,ILEX.(C(I),I=1.NC)
READ<25) «R(L.I).L=lf ILET). 1=1,NO
READ(25) <(YLL(L,I)vL=lrILEI)fI=lyNC)
READ(25) (RF(I),I=1,NC),TRF
IFIND=1
CREP(1)=C(1)
NCREP=NC
RRISK=R(1,1)
RYRLL=YLL(1.1)
RREF(1)=RF(1)
RR£f(2)=TRF
GO TO 40
END
C
C
C
C
SUBROUTINE FACOUT
REALA8 NUCLID,ORGN,CANC,OG,GEN,OREP,CREP,RREP,RN222,UBODY
DATA RN222/8HRN-222 /,UBODY/JW BODY '/
LOGICAL GENEFF
COHHON/COMOR/ORGN(20),NORGN,TIHE(20).DOSE(20.40.4,2).DTABLE(7)
COHMON/COMRN/OREP(20).RREP(20>.CREP(20)fULRN(20.20).
A RRISK.RREF(2),RYRLL.NOREP.NRREP.NCREP
COHMON/COMCA/CANC(20),NCANC,RELABS<20>,RISK<20,40,4,2>,
A-79
-------�
A
A
10000
10100
A
A
B
10200
10300
100
10175
10250
A
A
A
A
B
B
B
B
A
B
RTABLE<7),AGEX.YRLL<20,40,4.2)
COMMON/COMRF/REF(20,40.4).FTABLE(7)
COMMON/COMNU/NUCLID(40),NONCLn,PSIZE(40),RESP(40),GIABS<4F40),
INDPOP
COMMON/COMGEN/GEN(3),NGEN.GDOSE(3,40,4,2),GRISK(3,40.4,2),
GENEFF.GRFAC<2),REPPER,GLLET(3>,GHLEI(3>,GfiEl:(3,40,4)
DO 1000 K=1.NONCLD
WRITE(6,10000) NUCLID(K)
WRIIE<6,10100)
FORMAT(51FOR NUCLIDE
A8//)
L unrm i v x i. un i\\j\*u ivu • • no// /
FORMAIC DOSE RATE CONVERSION FACTORS'/
IX, 'ORGAN',11X,'INGEST ION',10X,'INHALATION',
9X 'AIR',5X 'GROUND'/
12X.'LOU LET',3X,'HIGH LET'.2X,'LOW LET'
SX'HIGH LET'.2X,'IMMERSIONJ.ix,'SURFACE')
URIIE<6,10200) (ORGN
-------�
400 CONTINUE
RETURN
450 URIIE(6.10700) RRISK.RYRLL.RREF
10700 FORMATt'lFOR RN-222 WORKING LEVEL CALCULATIONS:'/
A ' RISK CONVERSION FACTOR = ',1PG10.3/
B ' YEARS OF LIFE LOST FACTOR = ',1PG10.3/
C ' RISK EQ. CONVERSION FACTOR (PULMNARY) = ',1PG10.3/
D ' RISK EQ. CONVERSION FACTOR (U BODY ) = 'V1PG10.3)
RETURN
END
C
C
C
C
SUBROUTINE FREPBRdABLE, ILET,TITLE,GSCFAC, IFLAG)
CAAA THIS ROUTINE PREPARES DOSE RATES TO BE OUTPUT.
REALA8 ORGN.NUCLID,RNLOC,OGLOC,ORC,ORGfLAST,GEN,OREP,RREP,CREP,
A GON
COMMON/HEAD/ORC
COMMON/COMRN/OREP(20),RREP(20).CREP(20),ULRN(20,20),
A RRISK.RREF(2),RYRLL.NOREP,NRREP,NCREP
COHMON/COMWOR/FACO<20.4>
COMMON/COMGEN/GEN<3),NGEN.GDOSE<3.40,4.2).GRISK(3.40.4,2)T
> GENEFF.GRFAC<2).REPPER.GLLET(3),GHLET(3).GREF(3,40,4)
DATA ORG/8H ORGAN /.LAST/SHUT. SUM /.GON/8H GONAD /
COHMON/COMLOC/RNLOC(10).OGLOC(10),PTLOC(10),FALOC(10),
> HLLOC(10),LTABLE(10),NT£OC
REAL LLET
INTEGER TABLE.FALOC.HLLOC.PILOC
DIMENSION TA&LE<1),TITLE(1>.IITLA<10.3>, FACD<4,3).TLET(2,3),
> IITL2(2),nAB(7).lITLB(10.3),TIILGAtl0.3).f IILGB FACG(4.3).NOTE<20).NOT2<20),OFAC<20,26).NUN<8,3)
DIMENSION SDOSE(20.46,4,2),SGOSE(3,40,4.2)
DATA NUN/4H(WOR.4HKING.4H LEV,4HEL) ,4A4H ,4H(UOR,
> 4HKING,4H LEV,4HEL) ,4A4H ,4H(PER,4HSON ,4HHORK,
> 4HING .4HLEVE.4HL) ,2A4H /
DATA NOTE/4HRAB0.4HN DA,4HUGHT,4H£R E,4HXPOS,4HURE:,
> 14A4H /.NOT2/20A4H /
LOGICAL IDO.GENEFF
DATA TITLA/4HINDI,4HVIDU.4HAL D,4HOSE .4HRATE.4H (MR. 4HAD/Y,
> 4HEAR),4H ,4H ,4HMEAN,4H IND,4HIVID,4HL)AL . 4HDOSE,4H RAT.
> 4HE (M,4HRAD/ 4HYEAR,4H) 4HCOLL,4HECTI, 4HVE D.4HOSE 4HRATE.
> 4H (PE.4HRSON.4H RAD.4H /YE.4HAR) /
DATA inLB/4HINDI,4HVIDU.4HAL D,4HOSE .4HEQ. r4HRATE.4H(MRE.
> 4HM/YE,4HAR) ,4H ,4HMEAN,4H IND,4HIVID,4HUAL . 4HDOSE,4H EQ..
> 4H RAT,4HE (M,4HREM/r4HYR) ,4HCOLL,4HECTI 4HVE C.4HOSE .4HEQ.
> 4H (PE.4HRSON.4H REM.4H /YE.4HAR) /
DATA tlILGA/4HINDI,4HVIDU,4HAL G,4HENET,4HIC D.4HOSE .
< 4H(MRA,4HD), ,4H ,4H .
> 4HMEANF4H IND,4H1VID,4HUAL ,4HGENE,4HTIC ,4HDOSE.4H (MR.
> 4HAD) 4H
> 4HCOLL,'4HtCII,'4HVE G,4HENET,4HIC B,4HOSE ,4H( PE,4HRSON,
'> 4H RAD 4H) /
DATA lhLGB/4HINDI,4HVIDU,4HAL G,4HENET,4HIC D.4HOSE .
> 4HEQ. ,4H(MR£,4HM) ,4H ,
> 4HMEAN,4H IND,4HIVID,4HUAL ,4HGENE,4HTIC .4HDOSE.4H EQ..
> 4H (MR,4HEM) . '
> 4HCOLLr4HECTI,4HVE G,4HENET,4HIC D,4HOSE ,4HEQ. ,4H(PER.
< 4HSON .4HREM)/
DATA ILET/4HLOU ,4HLET ,4HHIGH,4H LEI,4H ,4H /
A-81
-------�
COHhON/COMOR/ORGN(20>.NORGN.TIHE(20),DOS£(20,40,4,2)
COhhON/LEIFAC/HLET(20).LLEI(20)
COMMON/COMNU/NUCLID(40)fNONCLD,PSIZE(40),RESP(40),GIABS (4,40),
> INDPOP
DATA FACD/1..1..1..100..1..!..!..100...001..001,.001,.l/
DATA FACG/I.,I.,1.,100.,1.,1.,1.,106.,.001,.Oftl,.001,.I/
DATA IKP/0/
CAAAAA?????????
CAAA hULTIPLY DOSES BY EXPOSURES
CAAA PREPARE TABLE FOR HIGH AND LOU LET SEPARATELY
IF (1KP.EQ.1) GO TO 6
IKP = 1
DO 5 J=1.3
FACD<4,J)=FACD(4,J)AGSCFAC
FACG(4.J)=FACG(4,J)AGSCFAC
5 CONTINUE
6 DO 50 L=l,2
10 DO 20 K=1.2
20 TIU2
DO 40 11=1.3
DO 42 J=1,NOREP
DO 42 K=l,l
OEAC(J.K)=1.
42 CONTINUE
IDO=.FALSE.
IF(lLET.EQ.l) GO TO 35
DO 30 K=l,7
ITAB(K)=0
IF (IABLE(K).Nt.Il.AND.TABLE(K).NE.4) GO TO 30
ITAB(K)=1
IDO=.IRUE.
30 CONTINUE
35 CONTINUE
IF (IIAB(G).NE.O) 1IAB(6)=0
ORC=ORG
IF (IDO) CALL MULKlI.FACDd, IT), DOSEd . 1.1,L) .NORGN.ORGN, TITLE.
> TITLA(1,IT),ITAB,IITL2,NOTE,NUN(1,IT),OFAC,OREP,NOREP,20,IFLAG)
ORC=GON
IF(lDO.AND.GENEtF) CALL MULKII.FACG(1,IT),GDOSE(1.1,1,L).NGEN.
> GEN,TITLE,TITLGA(1,II),ITAB,TITL2,N012,NOX2,0.,0.,6,3,IFLAG)
IF(Il.EQ.2) GO TO 3s
IF(NTLOC.EQ.O) GO TO 38
DO 45 LL=1.NTLOC
IF(FALOC(LL).NE.l) GO TO 45
IF(HLLOC(LL).EQ.l) GO TO 45
IF(LTABL£(LL).NE.IT .AND. LTABLE(LL).NE.4) GO TO 45
CALL LOCTAB(IT,RNLOC(LL).PTLOC(LL),OGLOC(LL),FACD(1,II),
A DOSE(l,l.lrL)1TITLE,TITLA(l.IT).TITL2,ORGN.NORGN,20rl)
IF(GENEFt) CAEL LOCTAB(IT,RNLOC(LL).PTLOC(LL).OGLOC(LL).
< FACG( 1, IT), GDOSE(1,1,1,L>; TITLE, TIlLGAd, IT ),flTL2, GEN, NGEN,
45 CONTINUE
38 CONTINUE
IF (INLPOP.NE.l) GO TO 50
40 CONTINUE
50 CONTINUE
CAAA COMBINE HIGH AND LOW LEI USING INPUT QUALITY FACTORS
DO 70 K=1.2
IIIL2
-------�
DO 80 1=1,4
DO 80 J=1.NONCLD
DOSE = ktET(K>+ DOSE(K, J. 1,2) AHLET GO TO 138
IF(NTLOC.EQ.O) GO TO 138
DO 135 LL=1.N1LOC
IF(FALOC(LL).NE.l) GO TO 135
IF(HLLOC(LL).EQ.O) GO TO 135
IF(LTABLE(LL).NE.II -AND. LTABLE(LL).NE.4) GO TO 135
CALL LOCTAB( IT.RNLOC(LL) .PTLOC(LL) .OGLOC(LL) .FACDd, IT),
> DOSE.TITLE,TITLB(1,IT).TIIL2.0RGN,NORGN.20.1)
IF(GENEFF) CALL LOCTAB( IT,RNLOC(LL) ,PTL(3C(LL) ,OGLOC(LL),
> FACG(l.IT),GDOSE,TITLEfTITLGB(l,IT),TITL2,GEN,NGEN,3,l)
135 CONTINUE
138 CONTINUE
IF (INDPOP.NE.l) GO TO 105
100 CONTINUE
105 DO 180 I = 1,4
DO 180 J = 1,N8NCLD
DO 180 K = 1,NORGN
DOSE(K,J,I,1) = SDOSE(K,J,Ifl>
IF ( K .GT. NGEN ) GO TO 180
GDOSE(K,J,1,1) = SGOSE(K,J,I,1)
180 CONTINUE
RETURN
END
C
C
C
C
A-83
-------�
SUBROUTINE PREPHRdABLE, ILET, IITLE.GSCFAC, IFLAG)
CAAA PREPARE HEALTH RISKS TO BE OUTPUT
REALA8 CANC,NUCLID,RNLOC,OGLOC,ORG,CAN,LAST,GEN,RREP,OREP,CREP,
A BL.GON
COHMON/HEAD/ORG
COMHON/COMRN/GREP(20),RREP(20),CREP(20),ULRN(20,20),
A RRISK,RREF<2>.RYRLL,NOREP,NftREP.NCREP
DATA CAN/8H CANCER /,LAST/8HTOTAL /,
A GON/8H GONAD /
INTEGER TABLE,FALOC,HLLOC,PTLOC
LOGICAL IDO,GENEFF
COMMON/COMLOC/RNLOC(10).OGLOC(10>,PTLOC<10),FALOC<10),
> HLLOC(10),LIABLE(10),NTLOC
COMMON/COMGEN/GEN(3),NGEN.GDOSE<3.40,4,2),GRISK<3.40.4,2),
> GENEFF.GRFAC(2),REPPER.GLLET<3>.GHLEI<3>,GREF<3.40,4)
DIMENSION IABLE FACD<4,3),IIAB(7>'TITLG(10.3>.FACG(4.3).NOI£(20>,NOT2<20>
> ,NUN(8.3),DRISK(2),SRISK<26.46,4,2).SGISK<3,40.4.2)
DATA NOTE/4HRABO,4HN DA,4HUGHT,4HEft E,4HXPOS,4HURE ,4HRISK,
> 4H: ,12A4H /,NOT2/20A4H /
DATA NUN/16A4H .4H(D£A,4HrH/Y,4HR) ,5A4H /
DATA IIl'LA/4HlNDlr4HVIDU.4HAL LF4HIFET,4HIME .4HRISK. 4H (DE,
> 4HATHS,4H) ,4H ,4HHEAN,4H IND,4HIVID,4HOAL , 4HLIFE,4HTIhE,
> 4H RIS,4HK (D,4HEATH,4HS) ,4HFATA,4HL CA,4HNCER,4H RAT,
> 4HE (D.4HEAIH.4H/YR).3A4H /
DATA 11ILG/4HINDI,4HYIDU,4HAL Gf4HENET,4HIC E,4HFFEC,4HTS P,
< 4HER B,4HIR1H,4H ,
< 4HMEAN,4H IND,4HIVID,4HUAL ,4HGENEf4HTIC ,4HEFFE,4HCIS ,
< 4H/BIR,4HTH '''''''
< 4HCOLL,4HECII,4HVE G,4HLNET,4HIC E,4HFFEC,4HT(EF,4HFECI,
< 4HS/YR'4H) I
DATA FACD/2A1.E-5,10..1000.,2A1.E-5.10.,1000.,4AO./
DATA FACG/1.,1.,1.,100.,1.,1.,1.,100.,.001,.001,.001,. I/
CAAAAA???????
DATA IKP/0/
DATA TLE1/4HLOW .4HLET .4HHIGH.4H LET.4HCOMB.4H.LET/
COMMON/COMCA/CANC(20),NCANC,RELABS(20),RISK(20f40,4,2),RTABLE(7).
> AGEX,YRLL(20,40,4,2)
COMMON/COMNU/NUCLlfi(40),NONCLDfPSIZE(40),RESP(40),GIABS (4.40),
> INDPOP ' '
CAAA MULTIPLY RISKS BY EXPOSURES
CAAA PREPARE HIGH AND LOU LET SEPARATELY
IE (IKP.EQ.l) GO TO 6
IKP = 1
DO 2 J=1.3
FACD(4,J5=GSCFACAFACD(4,J)
FACG(4.J)=GSCFACAFACG(4,J)
2 CONTINUE »
DO b J=l,4
FACG(j;3)=FACG(J.2)AREPPER
5 FACD(J.3)=EACD(J,2)/AGEX
6 DO 50 1=1,2
10 DO 20 K=1.2
20 TI1-L2(K)=ILEI(K,L)
DO 25 1=1,4
DO 25 J=1,NONCLD
DO 25 K=1,NCANC
RISK(NCANC+1,J,I,L)=R1SK(K,J,I,L)+RISK(NCANC+1,J,I,L)
25 CONTINUE
DO 40 11=1,3
A-84
-------�
IDO=.FALSE.
IF(ILEI.EQ.l) GO TO 35
DO 30 K=l,7
ITAB(K)=0
IF GO TO 30
IDO=.TRUE.
ITAB(K)=1
30 CONTINUE
35 CONTINUE
ORG=CAN
DRISK(1)=RRISK
IFdt.EQ.3) DRISK(1)=RRISK/AGEX
DRISK(2)=DftISK(l)
IF (IDO) CALL MULTdT.FACDd,II).RISKd,l,l.L),NCANC + l,CANC,TITLE,
> TITLAd,IT),ITAB,TIIL2,NOTE,NUN(l,II>,DRISK,CREP,NCREP,20,IFLAG)
IFdDO.AND. GENEFF) CALL MULTdT.FACGd, IT) .GRISKd.1,1 ,L),
> l,GEN<3),TITLE,TIILGd,IT>,ITAB,TITL2,NOI2,NOT2,0.,&.,0,3,IFLAG>
l£dT.EQl2) GO TO 38
IF(NTLOC.EQ.O) GO TO 38
DO 45 LL=1.NTLOC
IF(FALOC.NE.2) GO TO 45
IF(HLLOC(LL).EQ.l) GO TO 45
IF(LTABLE(LL).NE.IT .AND. LTABLE(LL).NE.4) GO TO 45
CALL LOCTABdT.RNLOC(LL) .PILOC(LL) .OGLOC(LL) .FACDd, IT),
> RISKd,l,l,L).TITLE,TITLAd,IT>.TITL2,CANC.NCANC,20.3>
IF(GENEFF) CALL LOCTAB(IT,RNLOC(LL).PTLOC(LL),OGLOC(LL),
< EACGd, IT),GRISK(lfl,l,L),IITLEfTITLG(lf IT)fTITL2,
< GEN(3)!lf3 3)
45 CONTINUE
38 CONTINUE
IF (INDPOP.NE.l) GO TO 50
40 CONTINUE
50 CONTINUE
CAAA COMBINE HIGH AND LOU LET USING INPUT QUALITY FACTORS
DO 70 1=1,4
DO 70 J=1.NONCLD
RISK(NCANC+l,J,Irl>=0.0
DO r/0 K=1,NCANC
SRISK(K,J.Ifl) = RISK(K.J,I,1)
RISK(K.J.I.l)=RISK(K.J,I.mRISK(K,3,I,2)
RISK(N£ANC+l,J,I,l5=filSK(NCANC+l J,1,l)+RISK(KrJf1,1)
IF(K.GX.l) Gfi TO 70
SGISK(K,J,I,1) = GRISK(K,J,I.l)
GRISK(K'j|lIl)=GRISK(K,J,I,l)+GRISK(K,J,I,2)
70 CONTINUE
CANC(NCANC+1)=LAST
DO 80 K=l,2
TITL2(K)=TLET(K,3)
80 CONTINUE '
DO 100 11=1,3
IDO=.FALSE.
IFdLEl.EQ.O) GO TO 95
DO 90 K=l,6
ITAB(K)=0
IF
-------�
DRISK(1)=RRISK
IF(11-.EQ.3) DRISK(1)=RRISK/AGEX
DRISK(2)=DRISK(1)
ORG=CAN
IF (IDO) CALL MULt(IT,FACD(l, IT).RISK,NCANC+1,CANC,TITLE. TITLAd,
> II).ITABfTIIL2,NOIE,NUNd, II),DRISK,CR£P,NCREP,20,IFLAG)
ORG=GON
IF(IDO.AND.GENEFF) CALL HULK Il.FACGd , IT) .GRISK, 1 ,GEN<3) ,
> TITLE.TITLG(1,IT),IIAB,TITL2,NOl2,NOI2f0.,0.,0,3,IFLAG)
IF(It!EQ.2) Gfi 1-0 138
IF(NTLOC.£Q.O) GO TO 138
DO 135 LL=1,NTLOC
IF(fALOC(LL).N£.2) GO TO 135
IF(HLLOC(LL).EQ.O) GO TO 135
IF(LIA6LE(LL).NE.rr .AND. LTABLE(LL).NE.4) GO TO 135
CALL LOClAB RISK.TITLE,IITLAd.IT>.TITL2,CANC.NCANC.20,3)
IF(GtNEFF) CALL LO^TAB!IT.RNLOC(LL).PTLOC(LL).OGLOC(LL),
> FACGd. II),GRISK,IITLE,TIILG(1,II),IITL2,GEN<3),1|3,3)
135 CONTINUE
138 CONTINUE
IF (INDPOP.NE.l) GO TO 105
100 CONTINUE
105 DO 170 1 = 1,4
DO 170 J = 1,NONCLD
DO 170 K = 1,NCANC
RISK(K,J.I,1> = SRISK(K,J,I,1)
IF < K .EG. 1 ) GKISK(K,J,1,1) = SGISK(K,J,1,1)
170 CONTINUE
RETURN
END
C
C
C
C
SUBROUTINE PREPRF(TABLE.TITLE.GSCFAC,IFLAG)
CAAA PREPARE HEALTH EQUIVALENT FACTORS TO BE OUTPUT.
REALA8 CANC,NUCLID,TOTAL,RNLOC,OGLOC,ORC,CAN,GEN,OREP,RREP,CREP.
> GON
COMMON/COHRN/OREP(20).RREP(20),CREP(20),ULRN(20,20),
A RRISK.RREF(2),RYRLL,NOREP,NRREP,NCREP
LOGICAL GENEFF
COMMON/HEAD/ORC
DATA CAN/8H CANCER /,GON/8H GONAD /
DATA TOTAL/8HU. BODY /
INTEGER TABLE,FALOC,HLLOC,PTLOC
LOGICAL IDO
COHhON/COHLOC/RNLOC(10).OGLOC(10),PTLOC(10),FALOC(10),
> HLLOC(10).LTABLE(10)rNTLOC
COHMON/COI!lGENrGEN(3),NGEN.GDOSE<3.40,4,2),GRISK(3.40,4,2),
> GENEEF.GRFAC(2).REPPER.GLLET(3).GHLET(3),Gf ITAB(7),NOTE(20).TIILG(10,3).FACG(4.3),NOTA(20),DREF(2) NUN(8,3)
DATA NUN/4H(MRE,4HM/YR,4H) ,5A4H .4H(HRE.
> 4HH/YR,4H) ,5A4H ,4H(PER,4HSON ,4HREM/,4HYR) ,
> 4A4H /
DATA N01E/4HRAD0.4HN DA.4HUGHT.4HER E, 4HXPOS.4HURE ,
> 4HRISK.4H EQU.4HIVAL,4HENI:,10A4H /,NOTA/20A4H /
DATA EACD/l.,l.,l.E6,l.E8fl.,l.,l.E6,l.E8,.001,
A ,001,1.E3,1.E5/
A-86
-------�
DATA FACG/l.yl.,l.,100.yl.yl.,l.y100.,.001y.001y.001,.l/
DATA IKP/0/
DATA 11TLA/4HIND1,4HVIDU.4HAL R,4HISK ,4HEQ. .4HRATE. 4H (MR,
> 4HEM/Y,4HEAR),4H ,4HHEAN,4H IND, 4HIVID, 4HCIAL . 4HRISK,4H EQ-,
> 4H RAT 4HE(MR 4HEM/Y 4HEAR) 4HCOLL 4HECTI, AWE ft,4HISK ,4HEQ Rf
> 4HATE(,4HPERS!4HON R 4HEM/Y, 4HEAR)/
DATA 1ITLG/4HINDI.4HVIDU.4HAL G,4HENEI,4HIC R,4HISK ,
A 4HEQ. .4H(HRE.4HM/YE,4HAR> ,
A4HMEAN,4H IND,4HIVID,4HUAL ,4HGENE, 4HTIC ,4HRISKy
A4H EQ.,4H(HRE,4HM/Y>,
A4HCOLL,4H. GE,4HNETI,4HC RI,4HSK E,4HQ. (,4HPERS,
A4HON R,4HEh/Y,4HEAR)/
DATA TITL2/4H .4H /
COMHON/COhCA/CANC(20).NCANC,RELABS(20)rRISK(20,40y4y2)
COMMON/COhRF/REF(20.40,4).FTABLE(7)
COhMON/COMNU/NUCLID(40),NONCLDfPSIZE(40)fRESP(40)yGIABS (4,40),
> INDPOP
CANC(NCANR)=TOTAL
CREP(NLREP+1)=101AL
IF (IKP.EQ.l) GO TO 6
IKP = 1
DO 5 J=1.3
FACD(4,J)=FACL(4,J)AGSCFAC
FACG(4.J)=FACG(4,J)AGSCFAC
5 CONTINUE
6 DO 20 IT=1,3
IDO=. FALSE.
DO 10 K=l,7
ITAB(K)=0
IF (1ABLE(K).NE.I1.AND.TABLE(K).NE.4) GO TO 10
ITAB(K)=1
IDO=.TRUE.
10 CONTINUE
NCRR=NCREP+1
IF(NCREP.EQ.O) NCRR=0
ORC=CAN
FAC=1.
IF(1T.EQ.3)FAC=.001
DO 12 J=1,NCRR
12 DREF( J)=RREF( J) AFAC
IF (IDO) CALL HULl-(lT.FACD(l,IT),REF.NCANRyCANC,TITLE, TIILA(1,IT)
> fITAB.TITL2,NOTE,NUN(l,IT),DR£F,CREP,NCRR,20,IFLAG)
ORC=GON
IF(IDO.AND.GENEFF) CALL HULK IT,FACG( 1 , IT) .GREF. 1 ,GEN(3) .
> TITLE, TITLGd, IT), ITAB,TITL2,NOIA,NOTA 0. ,6. ,0,3, iFLAG)
IF(I1.EQ.2) Gfi TO 38
IF(NTLOC.EQ.O) GO TO 38
DO 3b LL=1.NTLOC
IF(FALOC(LL)1NE.3) GO TO 35
IF(LTABLE(LL).NE.IT .AND. LTABLE(LL) .NE.4) GO TO 35
CALL LOCTAB(IT.RNLOC(LL),PTLOC(LL).OGLOC(LL),FACD(1,IT),
A REF.TITLE.TirLA(l.IT).IITL2.CANC.NCANR.20.2)
IF(GENEFF) CALL LflCTABt IT.RNLOC(LL) ,PTLOC(LL) ,OGLOC(LL) ,
A FACGd. IT), GREF, TITLE, TIILGd, IT) ,TITL2,GEN(3) ,1 ,3,2)
35 CONTINUE
38 CONTINUE
IF (INDPOP. NE.l) RETURN
20 CONTINUE
RETURN
A-87
-------�
END
C
C
C
C
SUBROUTINE DRTAB(ARRAY,NORGN,ORGN,TITLE,TITL1 ,DTABLE, TULA,NOTE,
A NUN.RFAC.CREP.NCREP,IFLAG)
CAAA THIS ROUTINE OUTPUT THE APPROPRIATE TABLES.
REALA8 ORGN.NUCLID,ORC,SUM,CREP,OREP,RREP,CFAK,RADON
DATA RADON/8HRN-222 /
COHMON/COMRN/OREP(20),RREP(20),CFAK(20),ULRN<20,20),
A RRISK,RREF(2),RYRLL,NOREP,NRfiEP,NFREP
COhhON/HEAD/ORC
COMMON/PDCF/DCFCTR(4,40)
JIMENS10NTARfeAY(20.40.4),ORGN(l),TITLE(20).TITLA(2).PATH(4,7).
> DTABLE(1)1TITL1(10),NOTE(20),CREP(1),WLSUH(4).RFACINCREP),NUN(8)
DATA PATH/4HINGE.4HSTI0.4HN .4H .4HINHA.4HLATI.4HON .
> 4H ,4HAIR ,4HIMME,4HRSIO,4HN .4HGROU.4HND S, 4HURFA,4HCE ,
> 4HINIE 4HRNAL 4H ,4H , 4HEXTE,4HRNAL,4H ,4H ,
> 4H ,4H ,4H ,4H /
DATA SUM/8HTOTAL /
COMHON/COMNU/NUCLID<40),NONCLD,PSIZE<40),RESP<40),GIABS (4,40),
> INDPOP
COMMON/COMUS/SUMX(40,7),SUMY(40,3),PERX(40)rPERY(40),TVAL(40),
> FACO(20 4)
CAAA SUM 0\>h ALL NUCL1DES FOR EACH ORGAN AND PATHUAY
CAAA PATHUAY 5 IS INTERNAL, 6 IS EXTERNAL, AND 7 IS ALL PATHWAYS
DO 10 1=1,7
DO 10 K=1,NORGN
10 SUHX(K,1)=0.0
DO 30 1=1,4
DO 20 K=1,NORGN
DO 20 J=1,NONCLD
SUMX(K.I)=SUMX(K.I)+ARRAY(K,J,I)
IF (I.LE.2) SUhX(K,5)=SUMX(K,5)+ARRAY(K,J,I)
IF (1.GE.3) SUMX(K,6)=SUMX(K.6)+ARRAY(K,J.I)
SUMX(K.7)=SUHX(K,7))-ARRAY(K,J,I)
20 CONTINUE
30 CONTINUE
C
C IE DOSE FACTOR CALCULATION TRANSFER TO STATEhENT 350
C
IF (IFLAG.EQ.l) GO TO 350
C
CAAA TABLE 1
IF (DIABLE(l).EQ.O) GO TO 80
DO 70 1=1.4
WRITE(G,10000) JITLE.TITL1.TITLA
URITE(6,10200) '(PAXHtN. I) ,N=1,4)
WRITE(6,10300) ORC,(ORGN(K),K=1,NORGN)
WRITE(6,10400)
DO 60 J=1,NONCLD
DO 40 K=1,NORGN
PERX(K)=0.0
40 IF (SUMX(K.I).NE.O.O) PERX(K)=ARRAY(K.J.I)/SUHX(K.I)A100.
WRITE(6,10500) NUCLID(J).(ARRAY(K.J,I),K=1,NORGN)
WRITt(6,10600) (PATH(N,1),N=1,4),(P£RX(K).K=1.NORGN)
DO 50 K=1,NORGN
11=5
A-88
-------�
IF (I.GT.2) 11=6
PERX=0.0
50 IF A100.
WRITE(6,10600) ORC,(CREP
WRITE(6.20400)NUN,(RFAC(JJ).JJ=lfNCREP)
115 CONTINUE '
110 CONTINUE
CAAA TABLE 3
120 IF (DTABLE(3).EQ.O) GO TO 170
WRITE(6,10000) TITLE,11111,TULA
WRITE(6f10900)
WRITE(6,10300) ORC,(ORGN(K),K=1,NORGN)
WRIIE(6,10400)
DO 160 J=1,NONCLD
DO 130 K=1.NORGN
130 TVAL(K)=0.0
A-89
-------�
DO 150 K=1,NORGN
DO 140 1=1,4
IVAL NOTE
IF(RFACd).EQ.O.O) GO TO 165
WRITE(6,10300)ORC, (CREP(K),K=1,NCREP>
WRITE(6,20400)NUN, (RFAC SUHX(K.I)
DO 210 J=1,NONCLD
11=1
IF (I.G1.2) 11=2
PERX(J)=0.0
IF (SUMY(J.II).NE.O.O) PERX(J)=ARRAY(K,J,I)/SUMY(J,IDA100.
PERY(J)=0.0
IF (SUHY(J,3).NE.O.O) PERY(J)=ARRAY(K,J,I)/SUMY(J,3)A100.
210 CONTINUE
WPP=0.0
IF (SUHX(K,4+1^1).NE.0.0) WPP=SUMX(K, I)/SUHX(K,4-HI)A100.
IF"(SUHX(K,7).NE.O.O) WP=SUMX(K.I)/SUHX(K.7)A100.
WRITE(6,11500) (PAIH(N.4+II),N=1.4),(PERX(J),J=l,NONCLD)fUPP
URITE(6 11600) (PERY(J),J=1,NONCLD),WP
WRITE(6'l0100)
220 CONTINUE
DO 240 1=1.2
WRIl;E<6,11400) (PATH(N,I+4),N=1,4),
-------�
230 IF PERX WP=SUMX(K,4+I)/SUMX(K,7)A100.
URITE(6,ll6oO> NUN, fiFAC(JJ)
255 CONTINUE
245 CONTINUE
250 CONTINUE
CAAA TABLE 5
260 IE (DTABLE(b).EQ.O) GO TO 350
DO 340 J=1.NONCLD
URIIE(6,10000) TITLE,TITL1,TULA
URIIE(6,11800) NUCLID(J)
DO 270 1=1,3
DO 270 K=1.NORGN
270 SUMY(K?I)=0.0
DO 280 1=1,4
DO 280 K=1.NORGN
IF (I.LE.2I SUMY(K,1)=SUMY
IE (I.GE.3) SUHY(K.2)=SUMY(K,2)+ARRAY(K,J,I)
SUMY(K,3)=SUHY(K,3)+ARRAY(K,J,I)
280 CONTINUE
URIIE(6,11900) ORC,(ORGN(K),K=1,NORGN)
URI1£(6,11300)
DO 300 1=1,4
URIT£(6,11400) (PATH(N,I),N=lF4),(ARRAY(K,J,I)fK=l,NORGN)
IF (I.GE.3) 11=2
DO 290 K=1.NORGN
PERX(K)=0.0
IF (SUHY(K.II).NE.O.O) PERX=0.0
IF (SUMY(K,3).NE.O.O) PERY(K)=ARRAY
-------�
PERX(K)=0.0
330 IE ,K=1,NCREP)
335 CONTINUE
340 CONTINUE
CAAA TABLE 6
350 IF (DTABLE(G).EQ.O) GO TO 500
DO 360 1=1.7
TVAL(I)=0.0
DO 360 J=1.NONCLD
SUMX(J.I)=6.0
360 CONTINUE
390 DO 400 1=1,4
DO 400 J=1.NONCLD
SUMXU, I)=ARRAY(NGRGN. J, I)
IF(I.GE.3) GO TO 40l
SUHX(J.5)=SUMX(J.5)+ARRAY
-------�
IF (IVALdD.NE.O.O) WP=TVAL. (P£RX(J),J=l,NONCLD),UP
WRITE(6 11600) (PERY(J),J=l,NONCLD),WPP
URim&'lOlOO)
430 CONTINUE
DO 450 1=5.6
WRIIE<6,11400)
-------�
WRITE (6, 11600) (PERYU>,J=1,NORGN)
WRIIE<6. 10100)
575 CONTINUE
DO 590 1=5.6
WRITE (6, 11400)
612 CONTINUE
WRITE* 6, 10300 >ORC, (CREP(L) .1=1 .NCREP)
URITE(6,20400)NUNf (ULSUH(L) ,L=1 , NCREP)
600 CONTINUE
RETURN
10000 FORHAT(lHlf20X,20A4/21X,10A4/21X,2A4)
10100 FORMAT(IX)
10200 FORMATCO^AA FOR PATHWAY: '.4A4//)
10500 EORMAT(lX.A8r23X.lP10G10.3/(33XFlP10G10.3))
10600 FORHATdlH X OF TOTAL, 1X.4A4.4X. 1P10G10.3/O3X. 1P10G10.3) )
10700 FORMATQ1H Z OF TOTAL.21X. IPIOGIO.3/ (33X, 1P10G10.3) )
10800 FORMATCOTOTAL ' ,21X.1P10G10.3/(33X,1P10G10.3) )
10900 FORMATCOAAA FOR ALL PATHWAYS:'//)
11000 FORMAT*' TOTAL' .26X, 1P10G10.3/O3X, 1P10G10.3) )
11100 FORMAT COAAAFORJ,A8,':'A8//)
11200 FORMATC NUCLIDES' ,23X, 10(2X, A8)/(33X, 10(2X.A8) ) )
11300 FORMATC PATHWAYS'/)
11400 FORMAT(1X,4A4,15X.1P10G10.3/(33X.1P10G10.3))
11500 FORMAH&H Z OF , 1X.4A4 .9X.1P10G10.3/ (33X, 1P10G10.3) )
11600 FORMATU8H Z OF ALL PATHWAYS, 14X. 1P10G10.3/ (33X. 1P10G10.3) )
11700 FORMAT(24H TOTAL OVER ALL PATHWAYS, 8X, 1P10G10.3/C33X, 1P10G10. 3) )
11800 FORMATCOFOR NUCLIDE: ' ,A8)
11900 FORMAT ( IX. A8,23X, 10 (2X, A8)/(33X.10(2X, A8) ) )
12000 FORMATU1H Z OF, TOTAL, 21X, 1P10G10.3/(33X, 1P10G10.3) )
12100 FORMAICOAAASUMMED 6vfcR ALL',A8)
12200 FORMAICOAAASUMMED OVER ALL NUCLIDES')
20100 FORMAT('0'/////10X,20A4)
20400 EORMA1-(1X,8A4,1P10G10.3)
END
C
C
C
C
SUBROUTINE CHLOC(PLOC.CONC.GSCFAC, IFLAG)
REALA8 CANC.NUC.NUCL ID, RADON. OREP,CREP,RREP,PNUC
DIMENSION CONC(4),FAC(4),IOR(4)
A-94
-------�
DATA FAC/2A1.E-5,10.,1000./
DATA IKP/0/
DATA BRTHRI/.83E6/
DATA RADON/8HRN-222 /
DATA IOR/3,4,1,2/
COHMON/COM£xMpP(20.20f40.4),POP(20f20),POPFAC,TOTFAC, NOL,NOU,
> NRL,NRU,IDIST(20>,ILOC.JLOC
COMMON/COMCA/CANC(20),NCANC,RELABS(20),RISK(20,40,4,2)f RTABLE(7)F
> AGEX.YRLL(20,40,4.2)
COHflON/COHRF/REF<20.40.4).FTABLt<7)
COhMON/COMNU/NUCLID(46),NONCLD.PSrZ£(40>.RESP<40),GIABS (4,40),IND
COHMQN/COMRN/OREP<20).RREP(20),CREP(20),WLRN(20,20)
A .RRISK.RREF(2),RYRLL.NOREP.NRREP,NCREP
COHMON/COMUS/IRISK<20, 20) .10(400)
COhMON/PASS/PNUC<40).PCONl<40>,PCON2(40>>PCON3<40),
& PCON4(40).PPOP.LLIND.LDIST
DIHENSION SRISK(400),ANGLE(1G)
DATA ANGLE/4HN .4HNNE ,4HNE .4HENE ,4HE ,
A 4HESE .4HSE , 4HSSE ,4HS ,4HSSW r4HSU ,4HUSU ,
B 4HU .4HUNU ,4HNU ,4HNNU /
EQUIVALENCE(TRISK(1.1),SRISK(D)
IF (IKP.EQ.O) FAC(4)=FAC(4)AGSCFAC
IKP = 1
DO 2 K=l,20
DO 2 1=1,20
POP(L,K)=1.0
ULRN
-------�
A CONC(L)AFAC(IOR(L)>
50 CONTINUE
DO 60 1=1,4
EXPP=0.0
DO 180 N=l,2
DO 180 K=1.4
DO 180 NC=1,NCANC
IRISK(JLO,ILO)=lRISK(aLOlILO)+RISK(NC,J>K,N)AEXPP(JLO,ILO,JfK)A
A FAC(K)
180 CONTINUE
ULRN(JLO,ILO)=WLEyEL
IRISK ' OR INGESTION RATE EXPOSURES FOR RN-222.')
90 CONTINUE
110 IE (1LOC.NE.O.AND.JLOC.NE.O) GO TO 130
LENO=NOU-NOL+1
LENR=NRU-NRL+1
NLOC=LENOALENR
J=0
DO 120 ILO=NOL,NOU
DO 120 JLO=NRL,NRU
IFdND.EQ.l .AND. POP( ILO. JLO) .NE.O.O)TRISK( JLO, ILO) =
< TRISK(JLO,ILO)/POP
-------�
140 T01POP=IOIPOP+POP(K2,K1)
IOIEAC=1./IOIPOP
150 ANG=ANGLE(HOD(17-ILOC.16)-t-l)
IF (IFLAG.GT.3) URITE(6, 10000) IDIST (JLOC) , ANG,SRISK(NOP>
RFTURN
10000 FORMATC1IHE LOCATION USED FOR THE SELECTED INDIVIDUAL',
C
C
C
C
C
C
C
C
C
C
C
C
C
C
> ' EXPOSURE IS ',17 ' hETERS 'A4,'FROM THE SOURCE.'/
> ' THE FATAL CANCER RISK AT THAT LOCATION IS ',G10.3)
END
SUBROUTINE VSORIP
-------�
60
C
C
C
C
C
C
70
80
GO TO 70
T1=A(L)
A=A TITL1<1).TIIL2<1),NAHNOC(1),TABLE(1>,NOIE<1),CREP(20),RFACI(2&>,
> RFACO(20).NUN(1)
GO TO (10,36,50),IM
10 DO 20 1=1 4
DO 20 J=1,NONCLD
DO 20 K=l'NOC
ARRAYO(K,J,I)=ARRAY1(K,J,I)AEXPP(JLOC,ILOC,J,I)ACONFAC(I)APOPFAC
20 CONTINUE
RFACO(1)=0.0
IF(NCREP.EQ.O) GO TO 80
DO 25 I=1,NCREP
25 RFACO( I)=RFACI( I)AWLRN( JLOC, ILOOAPOPFAC
GO TO 80
30 DO 40 1=1,4
DO 40 J=1,NONCLD
DO 40 K=l'NOC
ARRAYO(K,J.I)=O.ODO
DO 40 1I=NCIL,NOU
DO 40 JJ=NRL NRU
ARRAYO(K.J.I)=ARRAYO(K,J,I)+ARRAYI(K,J,I) AEXPP(JJ,II,J,DA
> CONFAC(I)ATOTFAC
40 CONTINUE
RFACO<1)=0.0
RFACO(2)=0.0
IF(NCREP.EQ.O) GO TO 80
DO 45 I=1,NCREP
DO 45 I1=NOL,NOU
DO 45 JJ=NRL,NRU
RFACO(1)=RFAC1(1)AULRN(JJ,II)ATOTFAC+RFACO(I)
45 CONTINUE
GO 10 80
50 DO 70 1=1,4
DO 70 J=1,NONCLD
TEXPP=0.0
DO 60 II=NOL,NOU
DO 60 JJ=NRL,NRU
TEXPP=TEXPP+EXPP(JJ,II,J,I)
60 CONTINUE »
DO 70 K=1.NOC
ARRAYO(K,J,I)=ARRAYI(K,J,I)ATEXPPACONFAC(I)
70 CONTINUE
RFACO(1)=0.0
IF(NCREP.EQ.O) GO TO 80
TULRN=0.0
DO 65 II=NOL,NOU
DO 65 JJ=NRL,NRU
TULRN=TULRN+HLRN(JJ,II)
65 CONTINUE
DO 75 I=1,NCREP
A-99
-------�
RFACO(I)=RFACI(I>ATWLRN
75 CONTINUE
80 CALL DRTAB
NAMELIST/ ORGANF/NORGB,ORGB,ORGDAI,IPATH
READ(26,ORGANF)
WRIIE(6,10000)
DO 10 J=1.NORGB
WRIIE<6,10100) ORGB(J),ORGDAT(J)
IF (IPATH(J).NE.5> WRITE<6,10200) IPAIH(J)
10 IF (IPAIH(J).EQ.S) WRIIE<6,10300)
DO 80 K=1,NORGN
DO 30 1=1 4
30 t'ACO(K.I)=0.0
DO 40 J=1.NORGB
IF
GO TO 80
60 DO 70 1=1,4
FACO(K,1)=ORGDAT(J)
70 CONTINUE
80 CONTINUE
RETURN
10000 FORMAK'OORGAN DOSE WEIGHTING FACTORS'//
A ' ORGAN FACTORS PATHWAYS'/)
10100 FORhAT (1X,A8.1X,F8.5)
10200 FORhAI('+' 19X,I2>
10300 FORMAK' + 'JigX,' 1234')
END
C
C
C
C
SUBROUTINE LOCIABt IT.RN,PT,OG,FACD, ARRAY,TITLE,TITL1,TULA,
< ORGN,NOfiGN,NDIM,NO)
8EALA8 RN,OGf3UH,NUCLID,ORGN,WLOPT(2)FOREP,RREP,CREP,PUL,
COMMON/COMRN/OREP(20),RREP(20),CREP(20),WLRN(20,20),RRISK,
A RREF(2),RYRLL,NOREP.NRREP.NCREP
COMMON/COMCA/DUM(6468),AGEX
INTEGER PT
DIMENSION IITLE(20),TIILA(2),TITLl(10),ARRAY(NDIM,40f4)f
< ORGN(1).FACD(1).TPATH(4.7>,IDIR(16)
COMHON/COMUS/OUTPUI(40.40),HOLDC(40),HOLDR(40)
DATA IDIR/1,16,15.14.13.12,11,10,9,8,7,6,5.4.3,2/
DATA 1PATH/4HINGE,4HSTIO,4HN ,4H ,4HINHA,4HLATI,4HON ,
A-100
-------�
> 4H ,4HAIR ,4HIhME,4HRSIO,4HN .4HGROU.4HND S, 4HUflFA,4HCE
> 4HINTE 4HRNAL 4H ,4H , 4HEXTE,4HRNAL,4H ,4H ,
> 4HALL .4H . 4H ,4H /
DATA £Uh/8HSUH /.ULOPT/8HWORKLEVLrSHULSUM /,
A PUL/8HPULhNARY/.TBEQ/8H60DY EQ./
COMMON/COMNU/NUCLlD(40),NONCLD,PSIZE(40),RESP<40),GIABS (4,40),
> INDPOP
COMhON/COMEX/LXPP(20.20,40,4),POP(20,20),POPFAC,TOTFAC, NOL,NOU,
> NRLJNRU,IDIST(20).ILOC.JLOC
COhMON/COMUOR/WT(20,4)
10000 FORhAT(lHl,20X,20A4/21X,10A4/21X,2A4)
DO 10 K=1.40
HOLDR(K)=6.0
HOLDC(K)=0.0
DO 10 L=l,40
10 OUTPU1(L,K)=0.0
TSUM=0.0
DO 12 J=l,2
IF(RN.LQ.WLOPT(J)) GO TO 1000
12 CONTINUE
14 CONTINUE
IF(RN.EQ.SUh) GO TO 75
IF(RN.EQ.WLOPT(2» GO TO 75
DO 50 J=1.NONCLD
IF(RN.EQ.NUCLIB(J» GO TO 70
CONTINUE
URITE(6.10500) RN
FORMATS RADIONUCLIDE ',A8.
' IS NOT IN LIST. TABLE WILL BE SKIPPED.')
RETURN
INE=J
GO TO 80
INB=1
INE=NONCLD
CONTINUE
IF(OG.EQ.SUM) GO TO 175
DO 150 J=1,NORGN
IF(OG.EQ.ORGN(J)) GO TO 170
CONTINUE
URITE(6,10600) OG
50
10500
70
75
80
150
10600
i
170
175
185
180
190
195
FORMAT^ ORGAN '.A8,' IS NOT IN LIST.',
' TABLE WILL BE SKIPPED.')
RETURN
IOB=J
IOE=J
GO TO 180
IOB=1
IOE=NORGN (
IF(IT.EQ.3) GO TO 180
IFdl.EQ.l) GO TO 185
IOB=NORGN
IOE=NORGN
GO TO 180
CONTINUE
GO TO 195
DO 190 1=1.4
DO 190 K=IOB,IOE
UT(K,I)=1.
CONTINUE
CONTINUE
A-101
-------�
IPT=PT
IPB=I?T
IPE=IPI
IF(IPI.LE.4) GO TO 184
177 CONTINUE
IPT=IPT-4
GO TO (181,182,183),IPT
181 IPB=1
IPE=2
GO TO 184
182 IPB=3
IPE=4
GO TO 184
183 IPB=1
IPE=4
184 CONTINUE
DO 300 1PT=IPB,IPE
DO 300 IN=INB,INE
DO 300 IO=IOB,10E
DO 300 II=NOL,NOU
DO 300 JJ=NRL,NRU
OUTPUt(JJ,II)=OUlPUT(JJ,II)+ARRAY(IO,IN,IPT)AFACD(IPT)A
> EXPP(JJ,II,IN,IPI)
300 CONTINUE
305 IF(IT.EQ.3) GO TO 500
DO 400 II=NOL,NGU
DO 400 JJ=NRL,NRU
IF(POP(1I,JJ).EQ.O.O) GO TO 375
OUTPUT(JJ,II)=OUTPUT(JJ,II)/PUP(II,JJ)
GO TO 400
375 OUIPUT(JJ,II)=0.0
400 CONTINUE
WRIIE<6,10000) TITLE,IITL1.TULA
WRITE(6'10100) RN,OG ,K=1,4)
DO 600 JJ=NRL.NRU
WRIIE<6,10200) ID1SH JJ), (OUIPUK JJ, IBIR< ID), 11=1,8)
600 CONTINUE
URIIE(6,10125)
DO 605 JJ=NRL.NRU
WRITE(6,10200) IDISK JJ), (OUIPUK JJ, IDIR( II)), 11=9,16)
605 CONTINUE
RETURN
500 WRIIE<6.10000) TITLE,TITL1,TULA
DO 680 11=1,16
DO 680 JJ=NRL,NRU
HOLDC<1I)=OUTPU1(JJ,II)+HOLDC(II)
HOLDR(JJ)=OUTPUT(JJ,II)+HOLDR(JJ)
680 TSUH=OUTPUT
-------�
1001
1100
1150
1200
1250
1300
1350
1400
1450
10100
/
10125
>
10175'
10200
10205
10250
C
C
C
C
IF(OG.EQ.TBEU) GO TO 1001
IF(J.EQ.l) GO TO 305
GO TO 14
CONTINUE
IF(NO.NE.l) GO 10 1200
DO 1150 II=NOL,NOU
DO 1150 JJ=NRL.NRU
OUTPUT(JJ,II)=WLRN(JJ,II)
CONTINUE
OG=SUM
PT=7
GO TO 305
IF(NO.NE.3) GO TO 1300
FAC=1.
IF(11.EQ.3) FAC=1./AGEX
DO 1250 II=NOL,NOU
DO 1250 JJ=NRL,NRU
OUTPU1UJ, II)=RRISKAULRN(JJ,II)AFAC
CONTINUE
IF(J.EQ.l) GO TO 305
GO TO 14
IF(OG.NE.PUL) GO 10 1400
EAC=1.
IF(I1.EQ.3) FAC=.001
DO 1350 II=NOL,NOU
DO 1350 JJ=NRL[NRU
OUIPUl(ja,II)=RREF(l)AWLRN(JJ,II)AFAC
CONTINUE
IF(J.EQ.l) GO TO 500
GO TO 14
IF(OG.NE.TBEQ) RETURN
FAC=1.
IF(I1.EQ.3) FAC=.001
DO 1450 II=NOL,NOU
DO 1450 JJ=NRL,NRU
QUIPUI(JJ,II)=RREF(2)AWLRN(JJ,II)AFAC
CONTINUE
IF(J.EGl.l) GO 10 305
GO TO 14
FORMATC FOR RADIONUCL1DE : ',A8/
' AND ORGAN/CANCER :',A8/
' AND PATHWAY : ',4A4/
' DIRECTIONS:' 3X,'N'12X.'NN£'.10X,'NE'Ai
'ENE',lOX.'E' m.'ESE' 10X 'SEJf11X,'SSE'/ '
' DISTANCE'/' (METERS):'/)
FORMA1(////15X,'S' 12X,'SSU'plOX/SU'.HX.'UBU'. lOX.'W
,12X.'UNU',10X,'NWr.llX.'NNW'/' DISTANCE*/' (MEIERS):')
FORMAT(////15X,/S'l2X.5SSU'10X'SU'llX,'USU'f10X,/U'
.^X.'UNW. 10X,.'NWJ,llXf'NNUSIOX/SUM'/' DISTANCE'/
1 (HETERSJ:')'
FORMAT(I10,1P8G13.3)
FORMAKI10.1P9G13.3)
FORMAT('OSUM',6X,1P9G13.3)
END
SUBROUTINE SUMMRY
-------�
A OREP,RREP,CREP,RN222
LOGICAL GENEFF,RNUR
REAL LLET
C
COMMON/COMEX/EXPP(20.20,40.4),POP(20,20),POFFAC,TOTFAC, NOL,NOU,
> NRL,NRU,IDIST(20).ILOC.JLOC
COMMON/COMOR/ORGN(20).NORGN.TIME(20).DOSE(20.40,4,2). DTABLE<7)
COMMON/COMRN/OREP<26>.RREP(20>.CREP<20>,WLRN(20,20),
A RRISK.RREF(2).RYRLL.NOREP,NRREP,NCREP
COHhON/LETFAC/HLET<20).LLEI<20)
COMMON/CO«NU/NUCLID(40),NONCLD,PSIZE(40)fRESP(40)fGIABS (4,40),
> INDPOP
COMHON/COMGEN/GEN(3),NGEN.GDOSE<3.40,4.2),GRISK<3.40.4,2),
> GENEFF,GRFAC(2).REPPER,GLLEr(3).GHLET(3).GREF(3.40,4)
COMMON/COHUS/STLOW(40),STHIG(40),SICOM(46),STGLO(46),
A STGHI(40),S'fGCO(40)
DIMENSION DOSFACU) ,GENFAC(4) ,TITLE(20)
DATA RN222/8HRN-222 /
DATA DOSFAC/1.,!..!.,100./,
< GENFAC/1..!.,!.,100./,101AL/8H1-01AL /jWISUM/SHUT.SUM /
DATA IKP/0/
COhMQN/COMWOR/DFAC(20.4)
IF (IKP.EQ.O) DOSFAC(4)=GSCEACADOSFAC(4)
IF (IKP.EQ.O) GENFAC(4)=GSCFACAGENFAC(4)
IKP = 1
RNUR=.FALSE.
DO 5 J=1,NONCLD
IF(NUCL1D(J).EQ.RN222) RNWR=.TRUE.
5 CONTINUE
HLC=0.0
DO 10 1I=NOL.NOU
DO 10 JJ=NRL,NRU
WLC=WLC-iWLRNAFACNEWAEXPP(JLOC.ILOC.J,KJAHLEi
-------�
100
c
c
c
c
c
c
c
c
c
20216
f
C
C
C
C
10100
A
B
10205
10206
t
10210
t
10211
10215
{
10216
t
10290
10220'
t
10221
I
10225
t
10226
t
10230
^
10231
t
C
C
c
c
c
: HLEKL)ADtAC(L.K)
IF(L.GT.NGEN) GO TO 100
SIGHIAFACNE2AEXPP(JLOC,ILOC,J,K)
SIGCO+GDOSE(L,JrK,2)AFACNE2AEXPP(JLOC,ILOC,J,K)AGHLET(L)
CONTINUE
WLI=WLRN(JLOC,ILOC)APOPFAC
IF MAXIMUM DOSE ORGAN BY NUCLIDE SUMMARY GO TO 11000
IF ( IFLAG .EQ. 3 ) GO 10 11000
WRITE<6,10100) IIILE.3))
FORMAIC HIGH LET (PERSON RAD)',3X,1P10G10.3/
(26X.1P10G10.3))
EORMATC DOSE EQUIVALENT
(26X.1P10G10.3))
EORMATC DOSE EQ. (PERSON
(26X,1P10G10.3)>
(MREM)',2X,1P10G10.3/
REM)',3X,1P10G10.3/
IF ANNUAL SUMMARY DOSE CALCULATION RETURN
IF ( IFLAG .EQ. 2 ) RETURN
A-105
-------�
150
200
C
10400
C
C
C
C
C
10590
>
C
C
C
350
IF(INDPOP.NE.l) GO TO 1000
DO 150 J=1F40
STH1G(J)=0.0
STLOW(J)=0.0
STCOM(J)=0.0
STGHI(J)=0.0
STGLO(J)=0.0
STGCO(J)=0.0
CONTINUE
SUML=0.0
SUHH=0.0
SUHC=0.0
DO 200 L=1,NORGN
DO 200 K=l,4
FACNEW=T01FACADOSFAC(K)
FACNE2=TOTFACAGENFAC(K)
DO 200 J=1.NONCLD
DO 200 II=NOL,NOU
DO 200 JJ=NRL,NRU
STH1G
-------�
403
400
10700
DO 400 K=l,4
DO 400 J=1,NONCLD
TEXPP=0.0
DO 403 1I=NOL.NOU
DO 403 JJ=NRL,NRU
TEXPP=IEXPP+EXPP(JJ,IlrJ,K)
CONTINUE
TEXPP=TEXPPA.001
DO 400 L=1,NORGN
SILOWATEXPPADOSFAC(K ) AOFAC(L.K)
SIHIG
SICOM(L)=SICOM
STGHI(L>=STGHI(L)+GDOSE
STGCO(L)=STGCO(L)+GDOSE(L. J.K.I ) ATEXPPAGENFAC(K) AGLLET(L) +
GDOSE(L,J,Kr2)AIEXPPAGENFAC(K)AGHLET(L)
CONTINUE
URIIE(6,10700)
TITLE, (ORGN(L).L=1.NORGN).WTSUM
20A4./.30X,'ORGAN DOSE/EXPOSURE SUMMARY' ,
c t/niiir AT Trm xxj./ / 'nnnct DATC-' / '
) EORHAK'I1./////.*. -, , - A . -
i 'OAAA COLLECTIVE POfUtAIlON AAA'./.'ODOSE RATE:
> 17X.' ORGANS:',10(2X.A8)/(26X.10(2X,A8)))
URItE(6,10206) (SILOW(L),L=1,NORGN),SUML
WRITE(6,10211) (SXHIG(L),L=1,NORGN).SUMH
URITE(6 10216) (STCOM(L).L=1,NORGN)fSUMC
IF(RNUR)URIT£(6,20416) ULC
20416 tORMAK'ORADON DAUGHTER EXPOSURE:'/
A ' (PERSON WORKING LEVEL)'.2X.1PG10.3)
URITE(6,10790) (GEN(L),L=1,NGEN)
10790 FORMATCOGONADAL DOSES:'/
> 17X,' GONADS:',10(2X,A8))
WRITE(6,10221) (STGLO(L),L=1,NGEN)
URITE(6,10226) (STGHKL),L=l ,NGEN)
WRITE(6,10231) (STGCO(L),L=1,NGEN)
CAAAA DOSE RATES BY PATHWAY
1000 DO 1050 J=1.40
STHIG(J)=0.6
STLOW(J)=0.0
STCOM(J)=0.0
STGHI(J)=0.0
STGLO(J)=0.0
STGCO(J)=0.0
1050 CONTINUE
DO 1199 K=1,4L
DO 1100 L=1.NDRGN
FACNEW=POPFACADOSFAC(K)ADFAC(L,K)
FACNE2=POPFACAG£NFAC(K)
DO 1100 J=1.NONCLD
STHIG(K)=STHIG(K)+DOSE(L,J,K,2)AFACNEWAEXPP(JLOC,ILOC.JrK)
STLOW(K)=STLOW(K)+DOSE(L,J,K,1)AFACNEWAEXPP(JLOC,ILOC.J.K)
STCOM(K)=STCOM(K)+DOSE(L.J.K.1)AFACNEWAEXPP(JLOC.ILOC.J.K)
< ALLET(L)+DOSE(L.J,Kf2)AFACNEWAEXPP(JLOC,ILOC,J,K)AHLET(L)
IF(L.NE.NGEN) GO TO 1100
SIGH1(K)=STGHI(K)+GDOSE(L,J,K,2)AFACNE2AEXPP(JLOC,ILOC.J,K)
STGLO(K)=STGLO(K)+GDOSE(L,J,K,1)AEACN£2AEXPP(JLOC,ILOC,J,K)
A-107
-------�
1100
1101
1102
1199
C
11100
STGCO
CONTINUE
IECK.GT.2) GO TO 1101
STHIG(5)=STHIG(5)<-STHIG(K)
STLOU(5)=SILOM(5)+SILOU(K)
STCOM(5)=SICOM(5)+STCOM(K)
SIGHK5)=STGHI<5)+SIGHI
-------�
DO 1200 II=NOL,NOU
DO 1200 JJ=NRL,NRU
SIHIG(K)=SIHIGAFACNEU
STCOM(K)=SICOM(K)+DOSE(L.J.K.1)AEXPP(JJ.II.J.K)AFACNEU
> ALLET(L)+DOSE(L,J,Kf2)AEXPP(ijfII,J,K)AFACN£HAHLET(L)
IF(L.NE.NGEN) GO TO 1200
SIGHI+GDOSE GO TO 1201
SIHIG(5)=SIH1G(&)+SIHIG(K)
STLOU(5)=STLOW(5)+STLOW(K)
SICOM(5)=STCOM(5)+STCOM
STGHK5)=STGHI(5>+STGHI(K>
SIGLO<5)=SIGLO(5)+SIGLO(K)
STGCO(5)=SIGCO(5)+SIGCO(K)
1201 IF(K.LI.3) GO TO 1202
STHIG(6)=SIHIG(6)+STHIG(K)
STLOU(6)=STLOW(6)+SILOW(K)
STCOh(G)=STCOM(6)+STCOM(K)
STGHI(6)=STGHI(6)+STGHI(K)
STGLO(6)=STGLO(6)+STGLO(K)
STGCO(6)=STGCO(6)+STGCO(K)
1202 STHIG(7)=SIHIG(7)+STHIG(K)
SILOW(7)=STLOU(7)+STLOU(K)
STCOH(7)=STCOM(7)+S1COM(K)
STGHI(7)=STGHI(7)+STGHI(K)
STGLO(7)=STGLO(7)+STGLO(K)
STGCO<7)=STGCO(7)+STGCO(K)
1299 CONTINUE
C WRI1E(6,11400)
11400 EORMAK/'OAAA MEAN INDIVIDUAL AAA'/
A 'ODOSE RATES:'/
< ' WEIGHTED SUMS OF ORGAN DOSE RATES'/
< ' PATHWAYS: INGESTION ',
< 'INHALATION AIR GROUND'
< ' INTERNAL EXTERNAL TOTAL'/
< 45X ' IMMERSION SURFACE')
C URITE(6,10205) (STLOW(L),L=1,7)
C WRITE(6f10210) (STHIG(L),L=lf7)
C URIIE(6.10215) (STCOH(L),L=lf7)
C IF(RNWR)WRIIE(6f20216) ULE
C URIXE(6.11590)
11590 FORMAI(;OAVERAGE GONADAL DOSES:'/
< ' j PATHWAYS: INGESTION ',
< 'INHALATION AIR GROUND'
< ' INTERNAL EXTERNAL TOTAL'/
< 45X ' IMMERSION SURFACE')
C URITE(6,10220) (SIGLO(L),L=1,7)
C URITE(6,10225) (S1GHKL) ,L=1,7)
C URHE(6r 10230) (SIGCO(L) ,L = 1,7)
DO 1350 K=1.40
STLOW(K)=0.0
STHIG(K)=0.0
STCOM(K)=0.0
SIGLO(K)=0.0
STGHI(K)=0.0
A-109
-------�
1350
STGCO(K)=0.0
CONTINUE
1404
DO 1499 K=l,4
DO 1400 J=1,NONCLD
TEXPP=0.0
DO 1404 1I=NOL,NOU
DO 1404 JJ=NRL,NRU
IEXPP=IEXPP+EXPP
STCOM(K)=STCOM(K)+DOSE(LiJ.K,l)ATEXPPADOSFAC(K)ALLET(L)A
> DFAC(L,K)+DOSE(L.J,K.2)ATEXPPADOSFAC(K)AHLEI(L)ADFAC(L,K)
IF(L.NE.NGEN) GO TO 1400
STGLO(K)=SIGLOATEXPPAGENFAC(K)
SIGCO GO TO 1401
STLOW(5)=STLOW(5)+STLOW(K)
STHIG(5)=STHIG(5)+STHIG(K)
SICOM(5)=SICOH(5)+SICOM(K)
STGLO(5)=STGLO(5)+STGLO(K)
SIGHI(5)=STGHI(5)+STGHI(K)
STGCO(5)=SIGCO(5)+STGCO(K)
GO TO 1402
1401 STLOW(6)=SILOW(6)+STLOU(K)
STHIG(6)=STHIG(6)+SIHIG(K)
STCOM(6)=STCOM(6)+STCOM(K)
STGLO(6)=STGLO(6)+STGLO(K)
STGHI(6)=STGHI(6)+STGHI(K)
SIGCO(6)=STGCO(6)+STGCO(K)
1402 STLOW(7)=STLOU(7)+STLOW(K)
STHIG(7)=STHIG(7)+STHIG(K)
STCOM(7)=STCOM(7)+STCOM(K)
STGLO(7)=STGLO(7)+STGLO(K)
STGHI(7)=STGHI(7)+STGHI(K)
STGCO(7)=STGCO(7)+STGCO(K)
1499 CONTINUE
11700 FORMATC1' /////.20A4./.30X 'PATHWAY DOSE/EXPOSURE SUMMARY',/,
S 'OAAA COLLECTIVE POPULATION AAA' / 'ODOSE RATES:',/,
< ' WEIGHTED SUMS OF ORGAN DOSE RATES'/
< ' PATHWAYS: INGESTION ',
< 'INHALATION AIR GROUND'
< ' INTERNAL EXTERNAL TOTAL'/
< 45X ' IMMERSION SURFACE')
URIT£(6,11700J TITLE
WRITE(6,10206) (SILOW(L),L=1,7)
WRITE(6,10211) (STHIG(L) L=l,7)
WRIIE(6.10216) (STCOM(L).L=1,7)
IE(RNWR)WRITE(6,20416) WLC
HRITE(6.11790)
11790 FORMAK'OAVERAGE GONADAL DOSES:'/
< ' PATHWAYS: 1NGES1ION ',
< 'INHALATION AIR GROUND'
< ' INTERNAL EXTERNAL TOTAL'/
< 45X,' IMMERSION SURFACE')
A-110
-------�
WRIIE<6,10221>
SUMGH=SUMGH+STGHI(J)
SUMGC=SUHGC+STGCO(J)
CONTINUE
URITE(6,12100) TITLE.(NUCLID(L).1=1.NONCLD).TOTAL
FORMAiri',20A4/30X, JNUCLIDE DOSE/EXPOSURE SUMMARY'//
2109
C
12100
A
A
A
A
C
C
C
C
C
12290
C
C
C
C
C
C
»UI\!inX\ X «*iVrlT/JV/\» ItlfwuXVl* i
'OAAA SELECTED INDIVIDUAL AAA'/
'GOOSE RATES:'/
' WEIGHTED SUMS OF ORGAN DOSE RATES'/
15X ' NUCLIDES:'.10(2X.A8)/(26Xr10(2X.A8)»
WRITE(6.10205) (STLOW(L),L=1,NONCLD),SUML
WRITE(6,10210) (STHIG(L),L=1,NONCLD),SUMH
WRITE(6.10215) (STCOM(L),L=1,NONCLD),SUMC
IF(RNWR)URIXE(6.20216) ULI
URI1E(6.12290) (NUCLID(L),L=1.NONCLD),TOTAL
FORMATrOAVERAGE GONADAL DOSES:'/
A 15X' NUCLIDES:' 10(2X.A8)/<26X.10(2X,A8)))
URIIE(6.10220) (STGLO(L),L=1FNUNCLD),SUMGL
URI1E(6 10225) (S1GHKL) ,L=1FNONCLD) ,SUMGH
URITE(6,10230) (STGCO(L),L=1,NONCLD),SUMGC
IF MAXIMUM DOSE ORGAN BY NUCLIDE SUMMARY RETURN
IF ( IFLAG .Ed. 3 ) RETURN
A-lll
-------�
c
c
2150
2200
2209
C
12400
A
A
c
c
c
c
c
12590
s
/
C
C
c
IF(INDPOP.NE.l) GO TO 21000
DO 2150 J=1.40
STH1GU)=0.6
STLOH(J)=0.0
SICOM(J)=0.0
STGLO(J)=0.0
SIGHI(J)=0.0
STGCO(J)=0.0
CONTINUE
SUML=0.0
SUMH=0.0
SUhC=0.0
SUMGL=0.0
SUMGH=0.0
SUMGC=0.0
DO 2209 J=1,NONCLD
DO 2200 K = 1.4
FACNE2=TOIFACAGENFAC(K)
DO 2200 L=1.NORGN
FACNEW=IOTFACADGSFAC(K)ADFAC(L,K)
DO 2200 II=NOL,NOU
DO 2200 JJ=NRL.NRU
STHIG(J)=STHIG(J)+DOSE(LFJFKF2)AEXPP(JJ,IIFJ,K)AFACNEU
STLOW(J)=SILOU(J)+DOSE(LFJFK,1)AEXPP(JJ,II,JFK)AFACNEU
SICOM(J)=STCOM(J)+DOSE(L.J,K,1)AEXPP(JJ,II.J.K)AFACNEU
ALLET(L)+DOSE(L,J,K,2)AEXPP(JJFIIFJFK)AFACNEUAHLET(L)
IF(L.NE.NGEN) GO TO 2200
STGLO(J)=STGLO
-------�
SIGLO(K)=0.0
STGHI(K)=0.0
SIGCO(K)=0.0
2350 CONTINUE
SUML=0.0
SUMH=0.0
SUMC=0.0
SUMGL=0.0
SUHGH=0.0
SUhGC=0.0
DO 2409 J=1,NONCLD
DO 2400 K=l,4
TEXPP=0.0
DO 2403 II=NOL,NOU
DO 2403 JJ=NRL.NRU
IEXPP=TEXPP+EXPP(JJ,II,J,K)
2403 CONTINUE
TEXPP=1EXPPA.001
DO 2400 L=1.NORGN
STLOW(J)=STLOW(J)+DOSE(L,J,K,1)ATEXPPADOSFAC(K)ADFAC(L,K)
SIHIG(J)=STHIG(J)+DOSE(L,J,K,2)ATEXPPADOSFAC(K)ADFAC(L.K)
SICOH(J)=STCOh(J)+DOSE(LtJ,K,l)ATEXPPADOSFAC(K)ALLET(L)A
> DFAC(L,K)+DOSE(L,J.K.2)ATEXPPADOSFAC(K)AHLET(L)ADFAC(L,K)
IF(L.NE.NGEN) GO TO 2400
SIGLO(J)=STGLO(J)+GDOSE(L,J,K,1)ATEXPPAGENFAC(K)
STGHI(J)=STGHI(J)+GDOSE(L,J,K,2)ATEXPPAGENFAC(K)
STGCO(J)=STGCO(J)+GDOSE(L.J,K.1)ATEXPPAGENFAC(K)AGLLET(L)+
A GDOSE(L,J,K,2)ATEXPPAGENFAC(K)AGHLET(L)
2400 CONTINUE
SUML=SUMLHSILOU(J)
SUMH=SUMH+STHIG(J)
SUHC=SUMC+SICOH(J)
SUHGL=SUMGL+STGLO(J)
SUMGH=SUMGH+STGHI(J)
SUHGC=SUMGC-i-STGCO(J)
CONTINUE
WRITE(6,12700) TITLE,(NUCLID(L),L=1.NONCLD).TOTAL
2409
WRITE (G, , ,. .
12700 FORHATCl' /////, 20A4./ .30X 'NUCLIDE DOSE/EXPOSURE SUhMARY',//,
COLLECTIVE POPULATION
&
A
OAAA COLLECTIVE POPULATION AAA' ./, 'ODOSE RATES:',/,
' WEIGHTED SUMS Of ORGAN HOSE RATES'/
15X ' NUCLIDES:'.10(2X.A8)/(26X.10(2X,A8)))
WRITE (6, 10206) (STLOU(L) ,L=1 ,NONCLD) ,SUHL
WRITE (6, 10211) (STHIG(L),L=1,NONCLD).SU«H
WRITE (6, 10216) (STCOM(L) .L=l ,NONCLD) ,SUMC
IF(RNWR)URITE(6. 20416) ULC
WRITE (6. 12790) tNUCLID(L) ,L=1 .NONCLD) , TOTAL
12790 FORMAK'OAVERAGE GONADAL DOSES:'/
> 15X ' NUCLIDES:' 10(2X, A8)/(26X,10(2X, A8) ) )
WRITE(6,1022J) (STGLO(L) f L=lf NONCLD) f SUMGL
21000
C
C
C
C
WRITE(6 102Z6) (STGHKL) L = l ,NONCLD) ,SUMGH
WRITE(6,10231) (SIGCO(L) ,L=1,NONCLD),SUHGC
CALL SUHhR2(IITLE,RNWR,GSCFAC)
RETURN
END
SUBROUTINE SUhhR2(TITLE,RNUR.GSCFAC)
REALA8 NUCLID,ORGN,CANC,TOTBOD,RNLOC,OGLOC,GEN,TOTAL,
A-113
-------�
A OREP,RREP.CREP.PUL
DATA PUL/8HPULHNARY/
LOGICAL GENEFF,RNWR
REAL LLET
C
COMHON/COHEX/EXPP<20.20,40,4),POP<20,20),POPFAC,IOTFAC, NOL,NOU,
> NRLFNRU,IDIST(20),ILOCfJLOC
COMMON/COHRN/OREP(20).RREP<20).CREP<20),WLRN<20,20),
A RRISK.RREF(2).RYRLL,NOREP,NRREP,NCREP
CO«HON/COMCA/CANC(20),NCANC,RELABS(20),RISK(20,40,4,2), RTABLE(7),
> AGEX.YRLL(20,40.4.2)
COMMON/COMRF/REF(20.40,4),FTABLE<7)
COMMON/COMNU/NUCLID(40),NONCLB,PSIZE(40>,RESP(40>,GIABS (4,40),
> INDPOP
COHMON/COMGEN/GEN(3),NGEN.GBOSE(3.40,4.2).GRISK(3.40.4,2),
> GENEFFfGRFAC(2).REPPER,GLLET(3).GHLET(3).GREt'(3.46.4)
COMMON/COMUS/STLOW(40),STHIG(40).STCOM(46).STRE(3(46),
A STGLO(40),SIGHI(40),STGCO(40),STLLL(40),STHLL(40)fSTCLL(40),
B STGRQ(40)
COMHON/ACCMOB/FICAN(40).CCNR(40).POPIK40),GNR(40),
S TFIC.TCCNR.TPOPD.TGNR
DIMENSION RISFAC(4),REQFAC(4),GENFAC(4),TITLE(20)
DATA RISFAC/2A1.£-5,10.,1000./,
< REQFAC/1.,!.,!.£6.1.E8/,
< GENFAC/1..!.,!.,100./,IOIAL/8HIOTAL /
DATA IKP/0/
CAAAA RISK RATES BY CANCER
IF (IKP.EQ.O) RISFAC(4)=RISFAC(4)AGSCFAC
IF (IKP.EQ.O) REQFAC(4)=REQFAC(4)AGSCFAC
IF (IKP.EQ.O) GENFAC(4)=GENFAC(4)AGSCFAC
IKP = 1
LP=1
DO 25> K=1.NCANC
IF(CANC(K).EQ.PUL)LP=K
25 CONTINUE
DO 50 J=1.40
STHIG(J)=0.0
STLOW(J)=0.0
STCOM(J)=0.0
SIGLOU>=0.0
STGHI(J)=0.0
SIGCO(J)=0.0
STREQ(J)=0.0
STGRQ(J)=0.0
STLLL(J>=0.0
SIHLL(J)=0.0
STCLL(J)=0.0
50 CONTINUE
SUML=0.0
SUMH=0.0
SUMC=0.0
SUMLLL=0.0
SUMHLL=0.0
SUMCLL=0.0
TBEQ=0.0
RLL=0.0
YRP=RYRLLAULRN(JLDC,ILOC)APOPFAC
RR=RRISKAULRN(JLOCfILOC)APOPFAC
IF(ULRN(JLOC,ILOC).NE.O.O)RLL=RYRLL/RRISK
RP=RR
A-114
-------�
DO 10S L=1,NCANC
DO 100 K=l,4
FACNEW=POPFACARISFAC(K)
FACNE2=POPFACAGENFAC(K)
DO 100 J=1.NONCLD
STHIG(L)=stHIG(L)+RISK(L,J,K,2)AFACNEUAEXPP(JLOC,ILOC,J,K)
STHLL(L)=STHLL(L)+YRLL(L,J,K,2)AFACNEUAEXPP(JLOC,ILOC,J,K)
STLOW(L)=STLOW(L>+RISK(L,J,K,1)AFACNEUAEXPP(JLOC,ILOC,J,K)
SILLL(L)=STLLL(L)+YRLL(L,J,K,1)AFACNEWAEXPP(JLOC,ILOC,J,K)
STCOM
-------�
10205
10210
10215
C
30100
C
C
C
C
C
20218
(!
C
20219
20220
f
10250
10255
10260
C
30200
C
C
C
10220
10221
FORMAK' LOU LET ', 16X, 1P10G10.3/(26X( 1P10G10.3))
EORMAK' HIGH LET' 16X.1P10G10.3/C26X,1P10G10.3))
FORMAK' TOTAL',18X,1P10G10.3/(26X,1P10G10.3))
URn£< 6.30100)
FORMAK;OAVERAGE LIFE LOSS PER PREMATURE DEATH:')
URITE(6,10102) (CANC(L).L=1.NCANC).TOTAL
WRITE(6,10250) (SILLL(L),L=1,NCANC),SUMLLL
WRITE(6.10255) (STHLL(L),L = 1,NCANC),SUMHLL
WRITE(6.10260) (STCLL(L).1=1,NCANC),SUMCLL
IF(RNWR)WRITE(6,20218) RLL
FORMAK'OAVG LIFE LOSS FROM RADON DAUGHTER EXPOSURE '
'FOR LUNG'.3X.1PG10.3)
IE(RNWR)WRITE(6,20219)YRP
EORMAK' AVG LIFE LOSS FROM ALL EXPOSURES FOR LUNG',
13X.1PG10.3)
IF(RNWR)WRITE(G.20220) YRT
FORMAK' AVG LIFE LOSS FROM ALL EXPOSURES (TOTAL) ',
12X,1PG10.3)
FORMAK' LOU LEI (YR)' . 12X, 1P10G10.3/(26X.1P10G10.3))
EORMAK7 HIGH LET
FORMAK' COMBINED
WRIXE(6.30200)
FORMAK'OEAIAL
WRITE(6,10102)
WRITE(6,10220)
WRITE(6,10221)
iA/ • J. M A • 1 1 AVJ-LV«»J/ \ jj U A • A. 1 XVUXV«U/ /
(YR)J,11X,1P10G10.3/(26X,1P10G10.3))
(YR)',11X,1P10G10.3/(26X,1P10G10.3))
CANCER RISK EQUIVALENT:')
(CANC(L).L=1.NCANC).TOTAL
(STREQ(L),L=I,NCANC),TBEQ
TBEQ
FORMAK' (MREM/YR)',15X.1P10G10.3/(26X,1P10G10.3))
FORMAK'OWHOLE BODY FATAL CANCER RISK EQ(MREM/YR)',
> 24X.1PG10.3)
RQ=RREF(l)AULRN(JLOCrILOC)APOPFAC
RT=RREF(2)AWLRN(JLOC,ILOC)APOPFAC
TTP=RQ+STREQ(LP)
TTQ=RT+TBEQ
C IF(RNWR)WRITE(6,20221) RQ
C IF(RNWR)URITE(6,20222) RT
C IF
-------�
c
10235
*>,
C
30300
150
206
(26X.1P10G10.3))
WKITE(6F10235) SIGCO(l)
FORHATC COMBINED (EFFECTS/BIRTH)
(2GX.1P10G10.3))
URITE(6.30300> STGRQ(l)
FORhAK'OGENEIIC
IF(INDPOP.NE.l)
DO 150 J=l,40
STHIG(J)=0.0
STLOW(J)=0.0
STCOM(J)=0.0
STGLO(J)=0.0
STGH1(J)=0
STGCO(J)=0
SIREQ(J)=0
STLLL(J)=0
STHLL(J)=0
STCLL(J)=0
STGRQ(J)=0
CONTINUE
TBEQ=0.0
SUHL=0.0
SUhH=0.0
SUHC=0.0
SUhLLL=0
SUMHLL=0
SUHCLL=0
RRM=0.0
.0
.0
.0
RISK EQUIVALENT:'/
1P10G10.3/(26X,1P10G10.
" TO 1000
GO
3))
.0
.0
.0
.0
.0
.0
.0
.0
.0
0
RLL=0
RQM=0
RTM=0
YRP=0.0
DO 206 II=NOL,NOU
DO 206 JJ=NRL.NRU
RQM=RQH+RREF(1)AWLRN
-------�
200
209
C
C
10400
A
B
10402
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
C
10590
C
C
IBEG=rBEG+kEnNCANC+l,J.K)AEXPP(JJ.II,J,K)ATGTFACAREQFAC+GREF(L.J.K)AEXPPUJ. II,J,K>ATOTEACAG£NFAC=STGHKL)+GRISKAFACNE2
STGCO(L)=STGCO SIGLO(l)
WRITE(6F10230) SIGHK1)
A-118
-------�
C URITE(6,10235) STGCO(l)
C HRITE<6.30300) SIGRQ(l)
DO 350 K=1.40
STLOU(K)=0.0
STHIG(K)=0.0
SICOM(K)=0.0
SIGLO(K)=0.0
SIGHI(K)=0.0
STGCO(K)=0.0
STREQ(K)=0.0
STLLL(K)=0.0
S1HLL(K)=0.0
STCLL(K)=0.0
STGRQ(K)=0.0
350 CONTINUE
SUhL=0.0
TBEQ=0.0
SUMH=0.0
SUHC=0.0
SUhLLL=0.0
SUMHLL=0.0
SUHCLL=0.0
ULT=0.0
DO 401 II=NOL,NOU
DO 401 JJ=NRL,NRU
WLT=UL1-H,|LRN(JJ,II>
401 CONTINUE
RRC=RRISKAULT/AGEX
RQC=RREF(1)AULTA.001
RIC=RREF(2)AULTA.001
DO 400 K=1.4
DO 400 J=1,NONCLD
TEXPP=0.0
DO 403 II=NOL,NOU
DO 403 JJ=NRL,NRU
TEXPP=TEXPP+EXFP RISK(L.J,K,2)ATEXPPARISFAi:(K)/AGEX
STCLL(L)=STCLt(L)+YRLL(LfJ,K,DATEXPPA
> RISFAC(K)/AGEX+
> YRLL
-------�
STGHI(L)=SIGHI(L)+GRISK(L,J,K,2)ATEXPPAGENFAC(K)AREPPER
STGCO(L)=STGCO(L)+GRISK(L.J,K.1)ATEXPPAGENFAC ' EXPOSURE' 8X.1PG10.3)
20317 FORMAIC TOTAL FATAL CANCER RISK(DEATHS/YR) FROM ALL',
> ' EXPOSURE' 12X.1PG10.3)
CURITE(6,10750) (STLLL(L),L=1,NCANC),SUMLLL
,10755) (STHLL(L),L=1,NCANC),SUMHLL
'10760) (STCLL(L) L=l.NCANC),SUMCLL
FORMATC LOST LOU LET'.12X,1P10G10.3/(26X,1P10G10.3))
FORMAIC LIFE LOST HIGH LET',6X,1P10G10.3/(26X,1P10G10.3))
FORMATC LIFE LOST COMBINED' "" "
TOTAL (DEATHS/YR)'
CURITE(6
CURIIE<6
10750
10755
10760
10715
A
10719
10321
10720
1
A
10790
10725
10730
10735
CAAAA
,6X, 1P10G10.3/(26X, 1P10G10. 3) )
6X,1P10G10.3/
FORMAI
(26X.1P10G10.3))
URITE(6,30200)
URITE(6,10102) (CANC(L).L=1. NCANC). TOTAL
WRITE (6, 10719) (STREQ(L) ,L=I , NCANC) .TBEQ
FORMAIC (PERSON REM/YR) ' ,9X, !P10Gl6.3/(26X, 1P10G10.3) )
URITE(6.10321) TBEQ
FORMAK'OUHOLE BODY FATAL CANCER RISK EQ(PERSON REM/YR)
18X.1PG10.3)
IF(RNHR)URI1E(6, 20321) RQC
' RTC
IF(RNWR)URITE(6;20322)
TTPC=RQC+STREQ(LP)
IE(RNWR)WRITE(6,20324)
TTQC=RTC+TBEQ
IF(RNWR)WRITE(6,20323)
EORMATCOGENETIC RISK
' (PERSON REM/YR)
(26X.1P10G10.3))
URITE(6.10790J
FORMAT(JOGENETIC RISKS:')
URITE(6.10725) STGLO(l)
FORMATC LOU LET(EFFECIS/YR)',5X,1P10G10.3/
(26X.1P10G10.3))
TTPC
TTQC
EQUIVALENT:',
,9X,1P10G10.3/
\ £t)J J\ m ± I AVUXv«w/ /
URITE(6.10730) STGHK1)
FORMAT(J HIGH LEKEFF1
:(EFFECIS/YR)',4X,1P10G10.3/
(26X.1P10G10.3))
URITE(6.10735) STGCO(l)
FORMAT(J COMBINEDCEEEECTS/YR)',4X,1P10G10.3/
URIIE(6.10720) STGRQ(l)
RISK RATES BY PATHWAY
A-120
-------�
1000
1050
1100
1103
1101
1102
1199
C
C
11100
DO 1030 J=1.40
STHIG(J)=0.0
STLOW(J)=0.0
STCOM(J)=0.0
STREQ(J)=0.0
STGRQ(J)=0.0
STGLO(J)=0.0
STGHI(J)=0.0
STGCO(J)=0.0
CONTINUE
DO 119
+RISK(L,J.K.2)AFACNEWAEXPP(JLOC,ILOC,J,K)
IF(L.NE.l) GO TO 1100
SIREQ(K)=STREQ(K)+REF
-------�
11102
C
C
C
C
C
C
C
C
C
20422
\
C
C
C
10290
C
C
C
C
1150
1200
1203
'OLIFET1ME FATAL CANCER RISK:'/)
FORMAT* ' PATHWAYS: INGESIION ',
'INHALATION AIR GROUND'.
INTERNAL EXTERNAL TOTAL'/
45X.' IHHERSION SURFACE')
URITE<6,10205) (STLOU(L),L=lf7)
WRIIE<6,10210) URITE(G,20217)II
WRITE(6,30200)
WRIIE<6,11102)
UR1TE(6.10220) (S1RECKL) ,1=1,7)
IF(RNUR)URITE(6.20422) RT
FORMAK'OUHOLE BODY RISK'EQi-»•••••
CONTINUE
IF(K.GT.2) GO TO 1201
STHIG(5)=SIHIG(5)+SIHIG(K)
STLOW(5)=STLOW(5)+STLOU(K)
A-122
-------�
STCOM<5)=STCOM(5)+STCOh=STREG(6)+STREG(K>
STGLO 2CJX./PA1HUAY RISK/RISK EQUIVALENT SUMMARY'//
A 'OAJkAMEAN INDIVIDUAL AAAV
B O.IFETIME FATAL CANCER RISK:'/)
C URiXE(6,10205) (STLOW(L),L=1,7)
C URIIE(6 10210) (STHIG(L),L=1,7)
C URIT£(6.10215) (S'f COM(L) ,L=1,7)
C IF(RNUR)WRITE(6,20216) RRM
C IF^RNUR)URIIE<&,20217) TTM
C URITE<6,30200)
C URIIE<&,11102)
C l..iKiTE(6.10220) (STREQ(L) ,L=1,7)
C IF(RNUR)URITE(6,20422) RTh
C lt(RNUR)WRITE(6,20223) ITQM
C UBIIE(6,11590)
C HRIIE(6f11102)
11590 FORMAT('OGENEIIC RISKS:'/)
C WRITE(6f10225) (SXGLO(L),L=l,7)
C URITE(6,10230) (SIQHI(L),1=1,7)
C WklIE(6ll023b) (S1GCO(L),L=1,7)
C URIIE(6,30300) (StGRQ(L),L=1,7)
DO 1350 K=l,40
CT:,OU(K>=O.K>
STHI6(K)=0.0
5TCOM(K)=0.0
3Ii3LO
-------�
DO 1404 II=NOL,NOU
DO 1404 JJ=NRL.NRU
TEXPP=TEXPP+EXPP RISK(L.J.K.2)AIEXPPARISFAC(K)/AGEX
IF(L.GI.I) GO TO 1400
SIREQATEXPPAGENFAC(K)A.001
STGLO(K)=STGLO(K)+GRISK(L,J,Kfl)ATEXPPAGENFAC(K)AREPPER
SI6HI(K)=STGHI(K>+GRISK(L,J,K,2)ATEXPPAGENFAC(K>AREPPER
STGCO+GRISK
1402 STLOU(7)=STLOW(7)+STLOW(K)
STHIG(7)=STHIG(7)+STHIG(K)
STCOH(7)=STCOM(7)+STCOM(K)
STGRQ(7)=STGRQ(7)+STGRG(K)
STREQ(7)=STREQ(7)+STREQ(K)
STGLO(7)=STGLO(7)+STGLO(K)
STGHI(7)=STGHI(7)+STGHI(K)
STGCO(7)=STGCO(7)+STGCO(K)
149-3 CONTINUE
WRITE(6f11700)TIILE
URITE(6.11102)
11700 EORMAK'l;f/////,20A4,/.30X,
S 'PATHWAY RISK/RISK EQUIVALENT SUMMARY',//.
'OAAA COLLECTIVE POPULATION AAA'/
'OCOLLECTIVE FATAL CANCER RISK:'/)
URITE(6,10705) (STLOU(L),L=l,7)
WRITE(6f10710) (SIHIG(L),L=1,7)
URITE(6 10715) (STCOM(L) 'l=l,7)
IF(RNUR)WRIIE(6f20316) RRC
IF(RNWR)URITE(6,20317) TIC
WRITE(6,30200)
URIIE(6,11102)
WRITE(6 10719) (STREQ(L),L=1,7)
IF(RNUR)WRriE(6.20522) RIC
20522 FORMATCOWHOLE BODY RISK EQ(PERSON REM/YR) FROM RADON ',
A
6
A-124
-------�
> 'DAUGHTER EXPOSURE',2X,1PG10.3)
WRIIE(G,20323) TTQC
WRITE(G,11790)
WRIIH(6,11102)
11790 EORHAH'OGENEIIC RISKSCPERSON REM/YR):'/)
UR HE (6,10725) (SIGLO(L),L=1.7)
WRIlL(6f10730) (STGHHL),L=1,7)
URITE(6,10735) (SIGCO(L) .L=l .7)
WRITE(6ll0720) (SIGRQ(L).1=1 7)
CAAAA RISK RATES BY NUCLIDE
11000 DO 2050 J=l,40
STHIG(J)=0.0
STLOW(J)=0.0
STCO«(J)=0.0
STGLO(J)=0.0
STGHI(J)=0.0
STGCO(J)=0.0
STR£Q(J)=0.0
SIGRQ(J)=0.0
2050 CONTINUE
SUML=0.0
SUMH=0.0
SUHC=0.0
SUMGL=0.0
SUMGH=0.0
SUHGC=0.0
SUMRG(=0.0
SUhGQ=0.0
DO 2109 J=1,NONCLD
DO 2100 K=1.4
EACNEW=POPFACARISfAC(K)
FACNE2=POPFACAGENEAC(K)
DO 2100 L=1.NCANC
SIHIG(J)=STH1G(J)+RISK(L,J,K,2)AFACNEWAEXPP(JLOC,ILOC,J,K)
STLOU(J)=STLOU(J)+RISK(L,JfK,l)AFACNEUAEXPP(JLOC,ILOC,J,K)
STCOM(J)=STCOM(J)+RISK(L,J.K.l)AFACNEWAEXPP(JLOC,ILOCfJ,K)
< +RISK
-------�
C
C
12100
12102
C
C
C
C
C
C
C
TFIC=SUMC
URIIE(6,12100) TITLE
MR HE < 6.12102 MNUCL ID
-------�
> GENFAC(K)
SUMGQ=SUMGQ+GREF(L,JfK)AEXPP GENFAC(K)
STGHl(a)=STGHI(J)+GRISK(L,J,K,2)AEXPP(JJfII,JrK)AFACNE2
STGLO(J)=STGLO(J)+GRISKAEXPP
SUMGH=SUMGH+STGHKJ>
SUMGC=SUMGC+STGCO(J)
2209 CONTINUE
C WRITE(6,12400)I1TLE, (NUCLID(L),L=1,NONCLD),TOTAL
12400 FORMATCl' 20A4/
> 30X.'NUCLlliE RISK/RISK EQUIVALENT SUMMARY'//
A 'OAAA MEAN INDIVIDUAL AAA'/
B 'OLIFE1IME FATAL CANCER RISK:'/
A 15X ' NUCLIDES:'.10(2X.A8)/(26X.10(2X,A8)))
C WR1TE(G,10205) (STLOU(L),L=1,NONCLD),SUML
C URIT£(6,10210) (STHIG(L),L=1,NONCLD),SUMH
C URITE(6.10215) (STCOM(L).L=l,NONCLD),SUMC
C IF(RNUR)URIIE(6f20216) RRM
C IF(RNWR)WRITE(6,20217) ITH
C U8ri£(6,30200)
C WRITE(6,12102) (NUCLID(L),L=1.NONCLD).TOTAL
C WRITE(6.10220) (STREQ(L),L=1,NONCLD),SUMRQ
C IF(RNUR)WRITE(6r20422) RTM
C IF(RNUR)URITE(6.20223) TTQM
C URITE(6.12590)(NUCLID(L),L=l,NONCLD),TOTAL
12590 FORMAT*'OGENEXIC RISKS:'/
A 15X,' NUCLIDES:'F10(2X,A8)/(26X,10(2X.A8)))
C URITE(6,10225) (SIGLO(L),L=1,NONCLD),SUMGL
C URITE(6,10230) (SIGHKL) ,L=1,NONCLD) ,SUMGH
C WRITE<6,10235) (STGCO(L),L=1,NONCLD),SUMGC
C WRITE(6f30300) (SIGRQ(L)rL=l,NONCLD),SUMGQ
DO 2350 K=1.40
STLOW(K)=0.0
STHIG(K)=0.0
STCOH(K)=0.0
STGLO(K)=0.0
STGHI(K)=0.0
SIGCO(K)=0.0
SIREQ(K)=0.0
STGRQ(K)=0.0
2350 CONTINUE
SUML=0.0 »
SUMH=0.0
SUMC=0.0
SUMGL=0.0
SUMGH=0.0
SUMGC=0.0
SUHRQ=0.0
SUMGQ=0.0
DO 2409
DO 2400
TEXPP=0.
DO 2403
J=l,NONCLD
K=lf4
0
II=NULtNOU
A-127
-------�
2403
DO 2403 JJ=NRL,NRU
TEXPP=IEXPP+EXPP(JJ,II,J,K)
CONTINUE
DO 2400 L=1.NCANC
SILOM(J)=SltoU(J)+RISK(LfJFK,l)AIEXPPARISFAC(K)/AGEX
STHIG(J)=STHIG(J)+RISK(L,J,K,2)AIEXPPARISFAC(K)/AGEX
SICOM(J)=STCOM(J)+RISK(L.JfK.l)AIEXPPARISEAC(K)/AGEX+
RISK(L.J.K,2)A1EXPPARISFAC
-------�
APPENDIX B
SAMPLE PROBLEM OUTPUT
-------�
A* IHPUl DATA AS READ IN A*
SITE ARtA
SITE AREA
1000 33
-1
0.2
C
C
C MIL AR
C
C S/9/87
C
C
O.b
0.0
31.45
7.3 32;:0.
1.0
0.4040 1
1 4
250.
0.39
100.
0.6?
0.
50.
0.0
2.
H-3
H-3
H-3
C-14
C-14
C-14
CR-51
CR-51
CR-51
HN-54
HN-54
MN-S4
FE-55
FE-55
FE-55
CO-58
CO-58
CO-58
NI-59
NI-59
NI-59
CO-60
E8-1!
NI-63
NI-63
NI-63
SR-90
SR-90
SR-90
NB-94
PkL RUN
?. ]
0.3
} A
2.6
0.26
20.
' 'o.oi
.OOOE-11
0.23
1 • f >
0.29
0.65
2160.
6.
0.0
0.40
10.
o!oi
0.20
0.99
0.01
0.20
0.99
200.
0.2
0.99
150
0.20
0.99
6000
0.20
0.99
55.
0.20
0.99
J50
0.20
0.99
55
0.20
0.99
150
0.20
0.99
150
0.20
0,99
200 -1
20
0.0
SANITARY
0.6
0.0
27.0
2. 01
l.Ot-6
0.27
3.57E>5
240.
24.
40.
0.015
]].
'o.oi
0.25
l.OE-2
0.01
0.25
l.OK-2
200.
0.25
l.OE-2
ISO.
0.25
].OE-2
6000.
0.25
I.OE-2
55.
0.25
1.0L'-2
150.
0.25
l.OE-2
55.
0.25
l.OE-2
150.
0.25
l.OE-2
]50.
0.25
l.OE-2
SANITARY LANDFILL
0
0.5
LANDFILL,
0.25
0.
30.5
O.I
-0.15
0.30
1003.
0.0021
1440.
96.
60.
0.
0
0.0]
4.0L-0
0
0.01
5.5IJ-0
0.
200.
2.5E-4
0.
150.
2.5K-1
0.
6000.
4.0t-3
0
55.
2.0E--2
0
]50
6.0E-2
0
55
2.0E-2
0
150.
6.01-2
0
150
2.SE+0
0
1000 100
1.0
SUBURBAN SET
0.09
0.
0.3
1.77E-I4
I. OK-11
0.30
0.1
:33G.
400.
0.0
9.
0
0.01
4.0L-0
0
0.0]
5.5E-0
0.
200.
5.0E-2
0.
150.
5.0E-2
0.
6000.
l.OE-3
0
55.
7.0E-3
0
150.
6.0E-2
0
55
7.0E-3
0
150.
6.0E-2
0
20
2.5E-1
0
0 0
0.0
TING
0.
] 0
0.39
300.
4.0L-4
1.0
720.
336.
9.9
50.
370.
5. 651J-2
0.90
l.OE-2
1.21E-4
0.75
1.2K-2
9.] 4
0.005
2.2E-3
8.09E-1
0.005
3.i)E-4
2.57E-1
0.005
2.5E-4
3.55
0.005
2.0E-3
0.66E-6
0.005
l.OE-J
].32F;-1
0.005
2.0E-ii
7.53E-3
0.005
].OE-3
'o.oos
l.bL-3
3.47E-5
1 1
0.0
0
0.35
0.01
0.24
M40.
1.0
1.0
0000.
0
1.7E-1
0
l.OE-l
0.
l.OE-3
0
2.5E-4
0.
1.3E-4
100.
l.OE-3
0
6.7E-3
100
l.OE-3
0
6.7E-3
0
1.4E-2
0
]000
0.0
0.43
2.2
0.83
25.
0
1.2E-2
0.
3.1E-2
0.
2.4E-3
0.
4.0E-4
0.
2.0E-2
0.
3.0E-2
0
6.0E-3
0
2.0E-2
0
6.0E-3
0
3.0E-4
0
-------�
CD
CO
NB-94
NB-94
TC-99
TC-99
IC-99
RU-106
RU-106
RU-106
SB-123
SB-125
SB-125
1-129
i-i2o
1-129
CS-134
CS-134
CS-134
CS-135
CS-135
CS-135
CS-137
CS-137
CS-137
CE-144
CE-144
CE-144
EU--154
EU-154
EU-154
U-234
U-234
U-234
U-235
U-235
U-235
NP-237
NP-237
NP-237
U-238
U-23R
U-238
PU-238
PU-23H
PU-238
PU-239
PU-239
PU-239
PU-240
PU-240
PU-240
PU-241
PU--241
PU-241
AH-241
AH-241
AM-24]
PU-242
PU-242
PU-242
Ah-243
AM-243
AM-243
CM-24U
CM-243
3bO
0.20
0.99
0.5
0.20
0.99
220
0.20
0.99
45
0.20
0.99
'J
0.20
0.99
1000
0.20
0.99
1000
0.2
0.99
1000
0.20
0.99
1100
0.20
0.99
4000
0.20
0.99
750
0.20
0.99
750
0.20
0.99
b
0.20
0.99
750
0.20
0.99
3SOO
0.^0
0.99
3bOO
0.20
0.99
3500.
0.20
0.99
3500
0.20
0.99
8.00E+4
0.20
0.99
3500
0.20
0.99
8.00EI4
0.20
0.99
3300
350.
0.25
] .OE-2
0.5
0.25
l.OE-'J
220.
0.25
l.OE-2
45.
0.25
l.OE-2
3.
0.25
l.OE-2
JOOO.
0.25
l.OE-2
1000.
0.25
l.OE-2
1000.
0.25
l.OE-2
1100.
0.25
l.OE-2
4000.
0.25
).0f>2
750.
0.25
l.OE-'J
750.
0.25
l.OE-2
5.
0.25
l.OE-2
750.
0.25
l.OE-J
3500.
0.25
l.OE-2
3500.
0.25
l.OE-2
3500.
o.:-:5
J.OE-2
3500.
0.25
l.Ofc-2
8.00E+4
0.25
l.OR-2
3500.
0.25
l.OE-2
U.OOE+4
0.25
l.OG-2
3300.
350
2.0E-2
0
0.5
9.5LHO
0
220
7.5E-2
0
45
2.0E-1
0
3
l.OE+0
0
1000
O.OE-2
0
1000
8. OE-2
0
1000
D.OE-2
0
1100
i .OF;- 2
0
0409°'
£j m J Lt~ «J
0
750
H.5E-vi
0
750
8.5K--3
0
5
4.3G-3
0
750
P.5E-3
0
3500
4.5K-4
0
3500
4.5E-4
0
3500.
4.5E--4
0
3500
4.5H--4
0
8.00E+4
5.51-3
0
3500
4.5E-4
0
U.OOEH-4
5.5E-3
0
3300
350
s.oe-j
0
0.5
l.bE-fO
0
220
2. OE-2
0
45
3.0L-2
0
0.5
l.OE+0
0
500
3.0E-^i
0
500
3. OE-2
0
500
3. OE-2
0
1100
4.0E-H
0
4000.
J.5E-3
0
750
4. OK- 3
0
750
4.0L-3
0
5
4.3E-3
0
750
4.0E--3
0
3500
4.5E-5
0
3500
4.5E-5
0
3500.
4.5E-4
0
3500
4.5E-5
0
8.00E>4
2.5E-4
0
:J500
4.5E--5
0
O.OOE+4
2.5E-4
0
3300
0.005
2. OE-2
3.25E-6
0.01
J.OE-2
6.09E-1
0.01
6.0E-7
2.50E-1
0.005
l.OE-4
4.08E-U
0.1
l.OE-2
3.36E-L
0.005
7.0L'-3
VJ.JE-7
0.005
7.0E-3
2.31E-2
0.005
7.0E-3
8.90E-)
0.005
b.OE-G
4.33E-2
0.005
2.0E-5
3.fJ3E--6
0.005
6.0E-4
9.856-10
0.005
G.OE-4
3.3E-7
0.005
5.0E-6
1.55E-10
0.005
G.OE-4
7.90E-3
0.005
l.OE-7
2.87E-5
0.005
l.OE-7
) .06E-4
0.005
l.OE-7
5.25E-2
0.005
1 .OK-7
1.51E-3
0.005
4.0E-7
1.03E-G
0.005
l.OE-7
9.4E-5
0.005
4.0E--7
2.17E-2
0.005
2.56-3
0
2.5E-2
0
1.3K-4
0
J.5E-3
0
3.0E-]
300
3.0E-]
0
3.0E-]
300
3.0E-1
0
l.OE-4
0
2.0E--5
0
b.OE~4
0
5.0E-4
0
5.0G-G
0
5.0E-4
0
1.5E-6
0
1.5E-6
0
J.5L-G
0
1-!.5E-G
0
0
0
1.5E-6
0
0
0
2.5E-1
0
ti.5E-3
0
2.0E-3
0
l.OE-3
0
7.0E-3
0
2.OE-2
0
2.0E-2
0
2.0E-2
0
7.5K-4
0
4.8E-3
0
•!.Ot-4
0
2.0E-4
0
5.5E-5
0
2.0E-4
0
5.0E-7
0
5.0E-7
0
7.0E-7
0
5.0E-7
0
3.5E-G
0
b.OE-7
0
3.5E-6
0
-------�
DD
I
-p.
CM-243 0.20 0.25 6.5E-4 1.5E-5 2.0E-5
CM-244 0.9'J J.OE 2 0 0 3.1)W-';.
CM-244 3300 3300. 3300 3300 0.005
CM-244 0.20 0.25 0.5E-4 1.5L 5 2.0L-5
DARTAB INFO
S INPUT 1LOC=1,JLOC=1,ILET=1I1IDTABLE=0,0,0,0,0,3,3,RTABLL=0,0,0,0
OUTPUT=. FALSE. ,GSCFAC=0. 5, SEND
SORGAN NORGN=)1,ORGN='R MAR '.'ENHOST '.'THYROID ' 'BREAST ',
'S WALL '.'INI WALL', 'LIVER '.' PANCREAS1, 'KIDNEYS ' 'OTWiR
TIME=20A70 SEND
SQFAC1R HLE1=20A20.LLET=20A1 SEND
SCANLLk NCANC = 11.CANC = 'LLUKLMIA','BONE ' 'THYROID ', 'BREAST '
'STOMACH '.'BOWEL ', 'LIVER ' 'PANCREAS' 'URINARY ' 'OTHER
RELABL=20A1 SEND
&GENT1C GENtFl=.TRUL.,NGEN=3,GEN='TESIES '.'OVARIES '.'AVERAGE '
GRFAC=2G0.5200,GLLET=l,l,l,GHLEf=20,20f20,SEND
SRNUCLD NONCLD=33. NUCLID= 'H-3 ' 'C-1V, ' CR-51' ,'MN~54' ,'LE-55'.'CO
'CO -60', 'NI-G3','SR-90' . 'NB-^i', ' TC -«•>:>' ,'RU -lOG' 'SB- 125',
'I-129','CG-134','(J
-------�
IPA1H=20A5,SL'ND
1 PRESTO - A MODEL FOR PREDICTING THE MIGRATION OF RADIOACTIVE UASTES
FROh SHALLOW TRENCH BURIAL SITES
0
SHE AREA BRC RUN ..., SANITARY LANDFILL
AAA CONTROL INFORMATION AAA
0 THE BURIAL SITE IS LOCATED AT SITE AREA
THE SIMULATION WILL RUN FOR 1000 YEARS AND WILL INCLUDE 33 NUCLIDES
LEACHING OPTION NUMBER 2 WILL BE USED
IN YEAR 1 .0.20 OF THE CAP WILL BE ASSUMED '10 FAIL
THIS WILL CONTINUE UNTIL 0.30 HAS FAILED IN YEAR 200
CAP MAY ALGU FAIL HY SURFACE EROSION
LENGTH OF VERTICAL SATURATED ZONE WILL BE SET TO THE TRENCH TO AQUIFER DISTANCE
BRCULATION INDICATOR IS 1
GENERAL BRCULATION EXPOSURE WILL BE USED TO CALCULATE HEALTH EFFECTS
0.000 OF IRRIGATION WATER WILL BE GOTTtN FROM WELL
0.500 OF DRINKING WATER FOR ANIMALS WILL BE GOTTEN FROM WELL
1.000 Of DRINKING HATLR FOR HUMANS WILL BE GOTTEN FROM WELL
0.000 OE IRRIGATION WATER WILL DE GOTTEN FROM STREAM
0.000 Of DRINKING WATER FOR ANIMALS WILL BE GOTTEN FROM STREAM
CD 0.000 OF DRINKING WATER FOR HUMANS WILL BE GOTTEN FROM STREAM
^ 1 AAA TRENCH INFORMATION AAA
THE TRENCH HAS AN ARLA OF 0.5000E+00 SQUARE METERS AND A DEPTH OF 0.2600E+01 METERS
TRENCH POROSITY IS 0.25
ANNUAL INFILTRATION FOR THE WATERSHED IS 0.4300 METERS
AAA AGUIH.R INFORMATION AAA
THfc GROUND WATER HAS A VELOCITY OF 27.800 METERS PER YEAR
TRENCH 10 AQUIFER DISTANCE IS 7.3 METERS
TRENCH TO WELL DISTANCE IS 1610.00 METERS
WELL TO STREAM DISTANCE IS 3220.00METERS
THE AOUItf.R THICKNESS IS 30.50 METERS
THE AQUIFER DISPERSION ANGLE IS 0.3000 RADIANS
POROSITY OF THE AQUIFER REGION IS 0.39000
POROSITY BENEATH THE TRENCH IS 0.35000
PERMEABILITY BENEATH THE TRENCH IS 2.200 METERS/YEAR
1 AAA ATMOSPHERIC INFORMATION AAA
SOURCE HEIGHT IS 1.0 MEIERS
VELOCITY OF GRAVITATION PALL IS 0.01 METERS/SECOND
WIND VELOCITY IS 2.01 METERS/SECOND
DEPOSITION VELOCITY IS 0.10 METERS/SECOND
GAUGE DISTANCE FROM SOURCE IS 17700.00 METERS
LID HhlGHT Ib 300.00 MEIERS
HOSKER ROUGHNESS FACTOR IS 0.01
TYPK OF STABILITY FORMULATION IS 1
STABILITY CLASS IS 4
FRAUION OF TIME WIND BLOWS TOWARD BRCULATION IS 0.484000
RESUSPENSION FACTOR PARAMETERS 0.1000E-05 -0.1500E+00 0.1000E-10
FROM YEAR 0 TO YEAR 0 THE RESUSPENSION KATE DUE TO MECHANICAL DISTURBANCES WILL BE 4.0000E-04
THIS WILL OCCUR DURING 2.40 OF EACH YEAR
-------�
AAA SURFACE INFORMATION AAA
DO
I
cn
PARAMETERS tOK UNIVERSAL LOSS EQUATION
RAINFALL 250.00
ERODllilLlTY 0.23
STEEPNESS-SLOPE 0.27
COVER 0.30
EROSION CONTROL 0.30
DELIVERY RATIO 1.00
SOIL POROSITY IS 0.39000
SOIL BULK DENSITY IS 1.60000 G/CC
RUNOFF FRACTION IS 0.29000
STREAM FLOW RATE IS 3.5700E+05 CUBIC METLRS PER YEAR
CROSS SLOPE EXTENT Of SPILLAGE IS 1003.00 METERS
ACTIVE SOIL DEPTH IS 0.10 MtTLRS
AVERAGE DOWN SLOPE DISTANCE 10 STREAM IS 100.00 METERS
AAA A1R-FOODCHAIN INFORMATION AAA
AGRICULTURAL PRODUCTIVITY FOR GRASS O.G7 KG/MAA2
AGRICULTURAL PRODUCTIVITY FOR VEGETATION 0.65 KG/MAA2
SURFACE DENSITY FOR SOIL 240.00 KG/MAA2
WEATHER DECAY CONSTANT 0.00 I/HOURS
PERIOD PASTURE GRASS EXPOSURE GROWING SEASON 720.00 HOURS
PERIOD CROP/VEGETATION EXPOSURE GROWING SEASON 1440.00 HOURS
PERIOD BETWEEN HARVEST PASTURE GRASS AND INGESTION BY ANIMAL 0.00 HOURS
PERIOD BETWEEN STORED FEED AND INGESTION BY ANIMAL 2160.00 HOURS
PERUiU BETWEEN HARVEST LEAFY VEGETABLES AND INGESTION BY MAN(M.I.E.) 24.00 HOURS
PERIOD BETWEEN HARVEST PRODUCE AND INGESTION BY MAN(M.I.E.)
0.83
PERIOD BETWEEN HARVEST LEAFY VEG AND INGESTION BY MAN(G
PERIOD BETWEEN HARVEST PRODUCE AND INGESTION BY MAN(G.P.E
FRACTION OF YEAR ANIMALS GRAZE ON PASTURE 1.00
FRACTION OF DAILY FEED THAI 113 FRESH GRASS
AMOUNT OF FEED CONSUMED BY CATTLE 50.00 KG
AMOUNT OF FEED CONSUMED BY GOATS 6.00 KG
TRANSPORT TIME FEED-MILL-RECEPTOR FOR M.I.E.
TRANSPORT TIME tEED-MlLL-RECEPTOk FOR G.P.E.
TIME FROM SLAUGHTER OF MEAT TO CONSUMPTION
ABSOLUTE HUMIDITY OF THE ATMOSPHERE
FRACTIONAL EQUILIBRIUM RATIO FOR C-14
AAA WATLk-FOQDCHAIN INFORMATION AAA
P.E.
1440.00 HOURS
) 336.00 HOURS
336.00 HOURS
48.00 HOURS
%.00 HOURS
480.00 HOURS
9.90 G/MAA3
1.00
FRACTION OF YEAR CROPS ARE IRRIGATED 0.40
IRRIGATION RATE 0.015 L/(MAA2-H)
AMOUNT OF HATER CONSUMED BY COWS 60.00 L/D
AMOUNT OF WATER CONSUMED BY GOATS 8.00 L/D
AMOUNT OF WATER CONSUMED BY BEEF CATTLE 50.00 L/D
AAA HUMAN INGES11UN AND INHALATION RATE INFORMATION AAA
ANNUAL INTAKE OF LEAFY VEG
ANNUAL INTAKE OF PRODUCE
ANNUAL INTAKE OF COW'S MILK
ANNUAL INTAKE OF GOAT'S MILK
ANNUAL INTAKE OF MEAT
2.00 KILOGRAMS PER YEAR
13.00 KILOGRAMS PER YEAR
11.00 LITERS PER YEAR
0.00 LITERS PER YEAR
9.00 KILOGRAMS PER YEAR
ANNUAL INTAKE OF DRINKING HATER 370.00 LITERS PER YEAR
ANNUAL INHALATION RATE OF AIR 8000.00 CUBIC METERS PER YEAR
A BRCULAI10N OF
2b. WILL BE CONSIDERED
-------�
AAA NUCLIDC INFOPHAIION AAA
INFORMATION ON INDIVIDUAL NUCL1DES
CO
NUCLIHE
H-3
C-14
CR-51
HN-54
EE-5b
CO-58
NI-59
CO-GO
NI-G3
SR-90
NB-94
TC-99
RU-106
SB-125
1-129
CS-134
CS-135
CS-137
CE-144
EU-154
U-234
U-235
NP-23?
U-238
PU-230
PU-239
PU-240
PU-241
AM-241
PU-242
AH-24J
CM-243
Ch-244
1 IN TRENCH
CI
6.1017E-01
9.9000E-01
5.5223E+00
9.4212E-02
2.1833E-01
1.3281E-01
9.9000E-01
3.7227E--01
9.9000E-01
7.9438E-01
9.9000E-01
00
O.OOOOE+00
O.OOOOEi-00
O.OOOOKtOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOK+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE^O
O.OOOOE+00
O.OOOOEi-00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
AIR CONCEN
CI/HAA3
O.OOOOK+00
O.OOOOE+00
O.OOOOE+00
O.OOOOL+00
o.oooot+oo
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOtMOO
O.OOOOE+00
O.OOOOL+00
O.OOOOlM-00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOL'+OO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
0.00001-+00
O.OOOOb'-iOO
O.OOOOE+00
DECAY CONST
1/Y
5.6500E-02
1.2100E-04
9.1400L+00
D.0900E-01
2.5700E-01
3.5500E+00
8.6GOOE-06
1.3200E-01
7.5300E-03
2.4200L-02
3.4700E-05
3.2&OOE--06
6.8900E-01
2.5000E-01
4.0800E-OB
J.3GOOE-OI
2.3000E-07
2.3100E-02
8.9000E-01
4.3300E-02
2.8300E-06
lJ.8bOOE-10
3.3000E-07
1.5500E-30
7.9000E-03
2.8700E-Ob
1.0600E-04
5.2500E-02
1.5100C-03
1.83001! --06
9.4000E-05
2.1700t-02
3.9400E-02
SOLUBILITY CONST DECAY C
G/HL
o.ooooi:+oo
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
l.OOOOE+02
O.OOOOE+00
l.OOOOE+02
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
3.0000E+02
O.OOOOE+00
3.0000E+02
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEHOO
O.OOOOGi-00
6.1633E-01
l.OOOOE+00
t..5781E+00
9.bl64t-02
2.20b4E-01
1.3415E-01
l.OOOOE+00
3.7G03E-01
l.OOOOE+00
8.0241E-01
l.OOOOE+00
l.OOOOE+00
1.0445E-01
2.2569E-01
l.OOOOE+00
1.7665E-01
l.OOOOE+00
8.1014E-01
9.0S90L-02
6.8372E-01
l.OOOOE+00
l.OOOOE+00
l.OOOOE+00
l.OOOOE+00
l.OOOOE+00
l.OOOOE+00
l.OOOOE+00
6.3565E-01
l.OOOOE+00
l.OOOOEHOO
l.OOOOE+00
8.2014E-01
7.057&E-01
NUCLIDE
H-3
C-14
CR-51
MN-54
FE-55
CO-58
NI-59
CO-GO
NI-63
SR-90
NB-94
TC-99
RU-10G
SB-125
1-129
CS-134
CS-135
DISTRIBUTION COEFFICIENTS ML/G
TRENCH VERTICAL AQUIFER
l.OOE-02
l.OOE-02
2.001N02
l.bOE+02
G.OOH^S
5.50E+01
5.50E+01
1 .bOK+02
l.t>OE+02
3.50E+02
5.00E-OJ
2.20E+02
4.50E+01
3.00G+00
l.OOH+03
l.OOE+03
l.OOE-02
l.OOE-02
2.00E+02
1.50E+02
6.00E+03
5.50E+01
1.50E+02
5.50E+01
1.50E+02
1.50H+02
3.50E+02
b.OOK-01
2.20H+02
4.50H+01
•J.OOEi-00
l.OOK+03
i.OOE+03
l.OOE-02
i.OOE-0'2
2.00E+02
1.50E+02
G.OOE+03
5.50G+01
1.50E+02
S.50E+01
l.bOE-l-02
l.bOE+02
3.5012^2
5.00H-01
2.20E+02
4.50E+01
3.00E+00
l.OOU+03
i.ooe+03
l.OOE-02
l.OOE-02
2.00L+02
] .bOE+02
6.00E+03
5.50E+01
l.bOE-i-02
5.50E+01
1.50E+02
2.00E+01
3.50E+02
b.OOH-01
2.20E+02
4.50E+01
5.00E-01
&.OOE+02
5.00E+02
-------�
CD
I
00
CS-137
CE-144
EU-154
U-234
U-235
NP-237
U-23E)
F'U-230
PU-239
PU-240
PU-241
AM--241
PU-242
Ah-243
CH-243
CH-244
NUCL1HE
H-3
C-14
CR-51
MN-54
FE-35
CO-50
NI-59
CO-GO
NI-G3
SR-90
NB-94
TC-9CJ
RU-10&
SB-125
1-129
CS-134
CS-135
CS-137
CE-144
EU-154
U-234
U-235
NP-237
U-238
PU-239
PU-239
PU-240
PU-24]
AM-241
PU-242
AM-243
CM-243
Ch-244
l.OOE+03
1.10E+03
4.00M03
7.50EI02
'/.bQlHQ?.
5.00£K)0
7.50E-<02
3.50E+03
3.bOE+03
3.50E+03
3.50E103
8.00E+04
3.bOtM03
H.OOEi-04
3.30L-I03
3.30L+03
RETENTION
IN AIR
2.00E-01
2.00E-01
2.00E-01
2.00E-01
2.00E-01
2.00E-01
2.00E-01
2.00K-01
2.00E-01
2.00E-0]
2.00E-01
2.00E-01
2.00E-01
2.00K-01
2.00E-01
2.00E-01
2.00E-01
2.00E-01
2.00K-01
2.00E--01
2.00E-01
2.00E-01
2.00E-01
2.00E-01
2.00E-01
2.00E-01
2.00E-01
2.00E-01
2.00E-01
2.00E-01
2.00E-01
2.00E-01
2.00E-01
l.OOK+03
1.10E+03
4.00E+03
7.50E>003
3.501H03
3.50E>03
3.50L't03
8.00E>04
3.50Ei03
8.00E>04
3.30t^3
3.30K-I03
RE1ENIION
(N HATER
2.50E-01
2.50E-01
2.50E-01
2.&OK-01
2.50E-01
2.50E-01
2.50E-01
2.&OII-01
2.50E-01
2.50E-01
2.50E-01
2.bOE-01
2.50E-01
2.50E-01
2.50L-01
2.50E-01
2.50L-01
2.SOE-01
2.bOE-01
2.50E-01
2.50E-01
2.50E-01
2.50E-01
2.50C--01
2.50E-01
2.50E--01
2.50L-01
2.bOE-01
2.50E-01
2.50E-01
2.50E-01
2.bOE-01
2.50E-01
l.OOE+03
1.10EKVJ
4.00H+03
7.50EH02
7.bOE+02
S.OOE^OO
'/.50E + 02
3.50E+03
3.50E+03
3.50E+03
3.50E+03
8.00E+04
3.50E+03
U.OOE-i-04
3.30Ei03
3.30E+03
TRANS COEEF
SOIL-y CROP
D/KG
4.00E+00
S.^OEiOO
2.50E-04
2.bOf-01
4.00E-03
2.00E-02
G.OOE-02
2.00E--02
G.OOE-02
2.50E+00
Vi.OOE-02
O.b'OE+00
7.50E-02
a.OOE-01
l.OOL-i-00
8.00E-02
8.00E--02
U.OOE-02
1 .OOE-02
2.50E-OJ
0.50L-03
0.50E-03
4.30E-03
8.50E-0:j
4.50E-04
4.50E--04
4.50E-04
4.50E-04
5.50E-0:J
4.bOt-04
5.50E-OJ
8.50H--04
0.50E-04
5.00Ei02
1.10E+03
4.00H+03
7.50E+02
7.bOEH-02
5.00E+00
7.bOEi02
3.50E+03
3.bOE^3
3.50E+03
3.bOE+03
B.OOE+04
3.50E-I03
8.00E+04
3.30E+03
3.30E1-03
TRANS COEtF
SOIL-R CROP
L/K(i
4.hJOE:-00
5.bOE+00
5. OOE-02
5. OOE-02
1.0013-03
7.00E-03
G.OOE-02
7.00E-03
G.OOE-02
2.50E-01
5.00E-03
1.50E+00
2. OOE-02
3. OOE-02
l.OOEiOO
J. OOE-02
3. OOE-02
3. OOE-02
4.00K-03
J.SOE-03
4.00E-03
4.00E-03
4.30E-03
4.00E-03
4.50K-Ob
4.50E-05
4.!:IOE-04
4.50E-OS
2.50E-04
4.50L-05
2.50E-04
l.SOE-Ob
1.50E--05
TRANS COEFF
VEG-COW MILK
U/L
1. OOE-02
1.20E-02
2.20E-03
3.50E-04
2.50E-04
2.00E--03
l.OOE-03
2.00E- 03
l.OOE-03
l.bOE-03
2. OOE-02
l.OOL-02
G.OOE-07
l.OOE-04
1. OOE-02
y.OOE-03
7.00E-03
7.00E-03
5.00E-OG
2.00G-03
G.OOE-04
&.OOE-04
b.OOE-06
G.OOE-04
l.OOE-07
l.OOE-07
l.OOE-07
l.OOK-07
4.00E-07
l.OOE-07
4.00E-07
2.00E-OS
2.00E-05
TRANS COEFF
TRANS COEFF
MEG -GOAT MILK VEG-MEAT
U/L
1.70E-01
I.OOE-01
l.OOE-03
2.SOE-04
1.30E-04
l.OOE-03
G.70E-03
l.OOE-03
G.70E-03
1.40E-02
2.50E-03
2.tiOE-02
1.30E-04
l.bOE-03
3.00E-01
•J.OOE-01
3.00E-01
3.00E-01
l.OOK-04
2.00E-05
b.OOE-04
b.OOK-04
5.00E-06
5.00E-04
1.50E-06
1.50E-0&
1.50E-OG
2.50E-OG
o.ooe-voo
l.bOE-06
O.OOE+00
O.OOEHOO
O.OOE+00
IN111AI. CALCULATIONS
NUCLIDE
H-3
C-14
CR-51
HN-b4
MASS
3.
14.
51.
54.
l.i /KG
1.20E-02
0.10E-02
2.40E-03
4.00E-04
2. OOE-02
3. OOE-02
6.00E-03
2. OOE-02
G.OOE-03
3.00E-04
2.50E-01
8.50E-03
2.00E-03
l.OOE-03
7.00E-03
2. OOE-02
2. OOE-02
2. OOE-02
7.50E-04
4.80E-03
2.00L-04
2.00E-04
5.50E-05
2.00E-04
b.OOE-07
5.00E-07
7.00E-07
5.00E-07
3.50E-0&
5.00E-07
3.50E-06
3.50E-06
3.50E-OG
-------�
1
<-O
OUTPUT
*******
INPUT
FROM SUBROUTINE INFIL
*********************
DATA AS READ IN
30.500 0.010 0.020 0
DAILY
DAILY
.250 0.
240 1
.200 0.
E£-55
CO-50
NI-59
CO-GO
NI-63
SR-90
NB-94
TC-99
RU-106
SB-125
1-129
CS-134
CS-135
CS-137
CE-144
EU-154
U-234
U-235
NP-237
U-238
PU-238
PU-239
PU-240
PU-241
AM-241
PU-242
AM-243
CM-243
CM-244
350E-03
0.140E-
05
55.
58.
59.
60.
63.
90.
94.
99.
]06.
125.
129.
134.
135.
137.
144.
154.
234.
235.
237.
238.
238.
239.
240.
241.
241.
242.
243.
243.
244.
0.100
1.2
00
SUNSHINE DY MONTH (HOURS)
10. H 11.2 12.0
TEMPERATURES (DEGREES
MONTH= JAN FEB MAR
DAY
1
2
3
4
5
6
7
8
9
8.88 10.16 6.00
8.48 6.81 8.76
7.05 7.79 12.65
15.27 1:3.93 14.35
6.13 12.14 17.74
8.84 13.12 16.25
15.54 6.94 10.90
15.54 9.23 4.41
15.54 13.06 7.93
12.8
CELSIUS)
APR
20.92
19.34
20.61
16.68
11.78
12.02
8.20
8.60
12.57
13.4
I
MAY
17.80
19.45
20.04
20.37
11.90
20.78
20.90
21.38
20.27
13.
JUN
25 . 34
26.79
25.34
23.45
25.40
24.17
23.86
26.07
27.60
7 13.
•HIL
26.30
25.79
27.73
28.48
25.39
22.78
18.01
12.58
21/33
(. 13
ALIG
24.99
25.92
25.28
26.23
23.77
23.70
25.78
25.85
25.12
.0
21
22
22
18
16
15
15
16
18
12.3
SE?
.89 13.
.43 19.
.71 20.
.00 18.
.67 20.
.04 22.
.87 22.
.54 21.
.09 22.
(id
96
38
17
79
95
37
63
47
77
11.6
10.9
NOV
39.89
19.56
19.56
19.56
19.56
19.56
19.56
19.56
19.56
19.77
19.15
19.73
19.23
20.96
13.86
11.56
11.70
13.60
10.6
DEC
-------�
DO
I
10
11
12
13
14
15
1G
17
19
19
20
21
22
23
24
25
26
27
28
29
30
31
MONTH,
1
1
1
1
1
1
1
1
1
2
2
2
2
2
1
3
4
13
14
19
20
23
31
1
2
3
9
12
15.
15,
15,
15,
15,
15,
15,
15,
8
12
36
15
6
8
5
7
2
-I
5
7
11
16
DAY,!
0.
0.
0.
0.
23.
0.
0.
0.
0.
0.
0.
0.
0.
0.
,54
,54
.54
.54
.54
.54
.54
.54
.78
.54
.73
.27
.46
.4]
.96
.04
.14
.54
.18
.55
.00
.16
8.44 13.33 11.21
8.13 17. 02 12.79
4.59 18.87 15.35
7.46 21.13 17.93
U.97 19.19 20.56
14.71 19.25 20.36
19.33 12.33 20.93
16.27 17.60 21.36
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UMKLT
23 .
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0.
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23.
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0. 0.
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23. 0.
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23. 0.
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0. 0.
0. 0.
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23. 0.
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0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
0.
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0.
0.
0.
0.
0.
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0.
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0.
0.
0.
THICKNESS OF TRENCH COVER = 1.20 M
TOTAL WIDTH OF TRENCH COVER = 30.50 M
AVERAGE SLOPE OF TRENCH COVER = 0.01 H/M
PERMEAbLITY OF TRENCH CAP = 0.200K-01M/HR
POROSITY FOR PELL1C WATER = 0.24 (UNITLESS)
POROSITY FOR GRAVITY UATKR = 0.25(UNim:SS)
EQUIVALENT UPWARD DIFFUSIVITY = 0.35E--03 MAA2/HR
EQUIVALENT UPWARD HYDRAULIC CONDUCTIVITY = 0.14E-05 H/HR
TIHE STEP FOR MODEL = 1.00 HOURS
YEAR= 1
PRECIP
l.llE-i-00
PELLICULAR
DEFICIT
JLAT1VE ANNUAL VALUES 1
EVAP RUNOFF
B.99E-01
GRAVITY
DEFICIT
3.48E-02
SNOW
;M)*AAAAAAAAAAA
INFIL
1.48E-01
1.03E-03 1.20E+00 O.OOE+00
CHANGE OF TOTAL ANNUAL INFILTfiATION= 1.48E-01
YEAR= 2
-------�
DO
(—•
CO
AAAAAAAAAAAACUMULAT1VE ANNUAL VALUES (M)AAAAAAAAAAAA
PSECIP EVAP RUNOi?F INFIL
1.11E+00
PELLICULAR
DEHCIT
8.99E-01
GRAVITY
DEFICIT
3.48E-02
SNOW
1.72E-01
1.03E-03 1.20E+00 O.OOE+00
CHANGE OF TOTAL ANNUAL INFILTRATION 2.38t-02
YEAR = 3
AAAAAAAAAAAAlUhULATIVE ANNUAL VALUES (M)AAAAAAAAAAAA
PRfcCH' EVAP RUNOFf INFIL
i.m+oo
PELL1CULAK
DEFicrr
1.03E-03
8.99E-01
GRAVITY
DEFICIT
1.20E+00
tiNOW
O.OOE+00
1.72E-01
CHANGE OF TOTAL ANNUAL INFILTRAT ION= O.OOE+00
NUCLHiE
H-3
C-14
CR-51
MN-54
FE-5lj
CO-!5B
NI-59
CO-GO
NI-63
SR-yo
NB-94
TC-99
RU-106
SB-125
ATURATION =
TURATION =
0.901
0.743
INITIAL CALCULATIONS
VERTICAL
RETALIATION
l.ObOtiE-iOO
] .OSOOL^OO
1.01G1EH03
7.6233EH02
3.0454EH04
2.0015£t02
7.h:.f3-)E(0',:
2.8015EV02
7.f.i!33E + 02
7.b2:33E + 02
1.7774E+03
3.5378E+00
1.1176E^3
2.^J40E+02
VERTICAL
TIME Y
7.7455EI-00
7.74bbE-iOO
7.4rJ01E + 03
b.6194E^3
2.2449Kt05
2.0G51li^J
S.61
B..'J051E^1
] .43C.'JL'+03
J.0513E+00
9.0356E+02
1.85G2E+02
HORIZONTAL
TIME Y
G.02'jOE + 01
6.0290E+01
4.7577E-I04
3.5G97E-I04
] .42561: -<06
1.312GE+04
3.5G97EI04
L.312GG-I-04
3.5G97L+04
4.0098E+OJ
8.32I6E+04
1.7G71E+02
5.2329E+04
1.0750E+04
HORIZONTAL
DDETA
l.OOOOE+00
l.OOOOE+00
l.OOOOEi-00
l.OOOOE-iOO
l.OOOOE+00
i.ooooe+oo
l.OOOOEHOO
l.OOOOE+00
l.OOOOE+00
l.OOOOG+00
l.OOOOE+00
i.ooooe+oo
l.OOOOE+00
1.0000EK)0
DDLTA
1.0077E+00
l.OOOOE+00
l.OOOOE+00
l.OOOOE+00
l.OOOOLiOO
l.OOOOK+00
l.OOOOE+00
l.OOOOE+00
l.OOOOE+00
l.OOOOE+00
l.OOOOE+00
l.OOOOE+00
l.OOOOE+00
l.OOOOE+00
BREAK THRU
TIME Y
G.8035E+01
G.8035E401
1.0001E+04
1.0001E+04
1.0001E*04
1.0001E+04
1.0001E+04
1.0001E+04
l.OOOJK+04
1.0001E+04
1.0001E+04
'^.0279E + 02
1.0001E+04
1.0001E+04
-------�
1-129
CS-134
CS-135
CS-137
CE-144
EU-154
U-2J4
NP-237
U-230
PU-23S
PU-2.39
PU-240
PU-241
AM-241
PU-24.-!
AM-243
CM-243
CM-244
1 . 6I-!S7E + 01
5.07G5E+03
5 .0765E i-03
5.07G5E+03
5.5841EH03
2.0303E+04
3.B076E+03
'1.807GEi<03
2.6J78EH01
H.H07GH03
1.7765E+04
1.7765E*04
1.776bEM04
1.77G5E+04
4.0604E+05
1.7765E+04
4.0G04EI-05
1.G750EH04
1.6750EH04
1.19G1E+02
3.7421E+04
3.7421Ef04
3.7421E+04
4.11G2E+04
2.'l)OG7E + 04
2.80671H04
1.9444E+02
2.8067E104
1.309bE'22fc-01
9.t^5GE-01
7.7538F.-0)
9.8996E-01
9.t(775E-01
5.I919E-02
1.V400E-01
9.8947E-01
l.:-!497E-01
9.9000E-01
7.U372E-01
3.G829E-02
TRENCH
OVERFLOW
U
O.OOOOE^O
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE-iOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEfOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEVOO
O.OOOOEHOO
O.OOOOE+00
TRENCH
DRAINAGE
CI
3.5079E-03
G.021GE-03
5.234BE-09
4.9401E-07
4.9798E-08
1.2212E-07
1.1657E-05
1.0443E-05
1.1570E-05
9.1304E-OG
5.0012E-06
2.2434E-03
4.1708E- 07
6.8003E-OG
5.3397E-04
2.2109E-07
1.7514E-OG
1.3865K-OG
5.9233E-08
AMOUNT AT
WELL
CI
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOK+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOH+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
-------�
co
i
EU-lb4
U-234
U-235
NP-237
U-238
PU-230
PU-239
PU-240
PU-241
AM-241
PU-242
AM-243
CM-243
CM-244
NUCL1DE
11-3
C-H
CR-51
hN-54
FE-55
CO-5CI
NI--59
CO-GO
NI-G3
SR-90
NB-94
TC-99
RU-10G
SB-125
1-129
CS-134
CS-13b
CS-137
CE-144
EU-154
U-234
U-2;j5
NP-237
U-238
PU-230
PU-239
PU-240
PU-241
AM-241
PU-24i!
Ah-243
CM-243
CM-244
1
6.4&20E-01
9.8999E-01
9.9000E-01
9.8%7E-01
9.9000E-01
9.U221E-01
9.8997E-01
9.8989E-01
5.9710E-01
9.&851E-01
9.9000L-01
9.8991E-01
7.94t.lE-01
6.7170E-01
SURFACE
SOIL CONG
CI/KG
7.1H37E-13
1. 23 3 IE- 12
3.bi619E-]3
2.502JE--11
1.03T3E-10
H.lbGGE-12
5.9043E-10
1.K442F-10
5.0G01E-10
4.6245E--10
6.0J37E-10
5.&102E-11
3.12821: 11
9.&&OOE-11
2.30b7E~10
7.6G09E-11
C..06B7E-10
4.8042E-10
2.258GE--]]
3. 988 IE- 10
&.ObU8E-10
&.050BE-10
3.0692E-10
&.05B8E-10
6.0422E-10
G.OtWE-10
&.OH94E-10
3.&731E-10
6.0B9JE-10
6.0901E-10
G.0977E-10
4.8871E-10
4.1317E-10
O.OOOOE^O
O.OOOOE+00
O.OOOOEi-00
O.OOOOH+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE^O
O.OOOOE+00
O.OOOOE-iOO
O.OOOOEi-00
O.OOOOE-iOO
O.OOOOE+00
SURFACE
WATER CONC
CI/hAA:)
7.26GOE-OQ
1.2473E-07
1.803&E-12
1.6873E-10
1.75221^-11
3.9GG3E-1]
3.981&E-09
3.39UIE-09
3.9510E-09
3.110bE-0'J
1.7300E-0'J
1.1J50E-07
1.4383E-10
2.1714E--09
7. 774 1L- 00
7.7493E-11
6.13H7E-10
4.B59GE--10
2.0770E-11
1.00fabE-10
0.17)bE-10
8.1715E-10
G.20CJ2E-OU
8.1715E-10
1.74G2E-10
1.7GOOE-10
1.7599E-10
1.0G1GE-10
7. 699 ]E- 12
1.7G01L-10
7.7100L-12
1.4980E-10
1.2665E-10
2.8674E-07
2.3350i:-OG
2.3350E-OG
3.3174L-04
2.3350E-OG
4.9656E-07
b.0049E-07
b.004bE-07
3.0187E-07
2.18G6E-08
&.0050E-07
2.1897E-08
4.2G01E-07
3.G016E-07
SOLUBLE 10
STREAM
CI
2.33G8H-03
4.0114E-03
5.7937L-08
b.42G5E-06
5.G352E-07
l.r/bGK-OG
1.2805E-04
1.090UE-04
1.2709E-04
1.0029E-04
5.5896E-05
3.G502E-OJ
4.G257E-OG
G.9835E-05
2.b002i:-03
2.4922E-OG
1.9743E--0&
1.5G29E-05
6.G790E-07
3.2435E-OG
2.62t)OE-Ob
2.G280E-05
1.9969E-03
2.G280E-05
5.G1G1E-06
5.GG04E-06
&.GGOOE-OG
3.4141E-06
2.4761E-07
b.GGOGE-06
2.4796E-07
4.8177E-06
4.0731E-06
O.OOOOL'+OO
O.OOOOK+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
SOLUBLE 10
DEEP LAYERS
CI
3.1338E-03
5.J795E-03
7.769GE-08
7.2771E-OG
7.IJ570E-07
].7)06E-06
1.7172E-04
1.4G28E-04
1.7044E-04
].3450L'-04
7.49bOL'-05
4.U951E-03
G.2032E-06
9.3G51E-05
3.3b29E-03
3.3422E-OG
2.G47Gt'-Ob
2.0959E-OS
8.9579E-07
4.3497E-06
3.5243E-Ob
3.5243E-05
2.G779K-03
J.S243E-05
7.5313E--06
7.5909E-0&
7.&903E-06
4.b7C4K-06
3.3206E-07
7.5911E-OG
3.3253E-07
6.4G07E-OG
5.4G21E-06
A1MOSPHEKE
AT SPILLAGE
C1/MAA3
4.2147E-1S
7.2349E-15
2.0899E-15
1.4G81E-13
G.0901E-13
1.2G54E-14
3.4G4JE-12
1.0821E-12
J.4;JfJ3E-12
2.7133E-12
3.b284E-12
J.2917E-13
1.8354E-13
5.GG79E-13
1.3&2CE-12
4.4950E-13
3.5G07E-12
2.C180E-12
1.3252E-13
2.3400E-12
3.5549E-12
3.5549E-12
1.0008E-32
3.SIJ49E--12
3.b452E-li!
3.5732E-12
3.5729E-12
2.15b2E-li!
3.5727E-12
3.b733E-12
3.5778E-12
2.1]674E-12
2.4242E-12
ATMOSPHERE
DOWN WIND
CI/MAA3
2.2031E-2G
3.7818E-26
1.0924E-26
7.6739E-2b
J.IU7GE-24
6.6143E-26
1.8109E-23
b.GbG2E-24
1.7973E-23
1.4183E-23
1.8444E-23
1.7207E-24
9.5941E-25
2.9G27E-24
7.0714E-24
2.3496E-24
1.8613E-23
L.4/-J4E-23
6.9273E-2b
J.2232E-23
].Ob82E-23
1.B502E-23
9.4132E-24
1.8b>32E-23
1.8b31E-23
1.8G78E-23
1.867GE-23
1.12G6E-23
1.8675E-23
1.C678E-23
1.8702E-23
1.4989E-23
1.2672E-23
UELL UATER
CONC
CI/MAA3
O.OOOOE+00
O.OOOOE+00
O.OOOOEiOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
ANNUAL SUMMARY FOk YEAR 100 Uf THE SIMULATION
THE TRENCH CAP HAS HAD 24.97 PER CENT FAILURE
THE MAXIMUM POSSIBLE UATER DEPTH IN TRENCH DURING 'IHE YEAR
2.02G5E-01 CUBIC MEIERS OF WATER LEFT BOTTOM OF TRENCH
O.OOOOE+00 CUBIC METERS OF WATER OVERFLOWED TRENCH
IS 1.62E-01 METERS
-------�
NUCLIDE TRANSPORT INFORMATION
TO
I
NUCL1HE
H-3
C-14
CR-51
MN-S4
EE-55
CO-58
NI-59
CO-60
NI-63
SR-90
NB-94
TC-99
RU-106
SB-125
1-129
CS-134
CS-135
CS-137
CE-144
EU-1S4
U-234
U-235
NP-237
U-238
PU-238
PU-239
PU-240
PU-241
AM-241
PU-242
AM-243
CM-243
CM-244
NUCLIDE
H-3
C-14
CR-51
MN-54
FE-55
CO-58
NI-59
CO-60
NI-G3
SR-90
NB-94
TC-99
RU-10G
SB-125
1-129
AMOUNT IN
TRENCH
CI
1.0734E-03
4.8918E-01
O.OOOOE+00
6.9038E-37
l.ei05GE-12
O.OOOOE+00
9.8782E-01
G.f+640E-07
4.G562E-01
7.0b'42E-Oi!
9.8GOOE-01
7.M97E-01
1.2338E-31
3.0K92E-12
9.3119E-01
4.4704E-1G
9.JJ977E-01
7.9593E-02
1.9972E-40
8.9122E-03
9.{J':)45E-01
9.8973E-01
9.5301E-01
9.U973E-01
4.4928E-01
9.!.<710E-Oi
9.7950E-01
3.3019E-03
8.5124E-01
9.097GE-01
9.0073E-01
9.:,'697E-02
].;+b07E-02
SURFACE
SOIL CONC
CI/KG
O.OOOOE+00
O.OOOOE+00
O.OOOOL+QO
1.9S13E-47
t:.S219E-22
O.OOOOE+00
;!.7'J19E-11
1.2108E-19
1.31b9E-ll
l.(J(J3SE-12
].b947E-10
O.OOOOE^O
g.r/29E-42
9.K016E-2G
7.8970E-49
TRENCH
OVERFLOW
Cl
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOL'+OO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOH+00
O.OOOOE^O
O.OOOOE+00
O.OOOOE+00
O.OOOOH+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOL+00
SURFACE
HATER CONC
C1/MAA3
O.OOOOE+00
O.OOOOE^OO
O.OOOOE+00
1.3008E-4G
1.4203E-22
O.OOOOE+00
1.&612K-10
2.2014E-18
8.7730E-11
1.3292E-1]
4.^5G3E-10
O.OOOOE^O
4.1G9SE-41
2.17U1F.-24
2.6324E-46
TRENCH
DRAtNAiJE
Cl
8.3944E-06
3.8255E-03
O.OOOOE+00
1.0370E-41
5.6641E-19
O.OOOOE+00
1.4837E-05
2.8028E-]]
6.9937E-OG
] .Ob9GE-OG
6.3539E-06
2.2176E-03
1.2643E-3G
1.5400E-1S
G.4109E-04
1.008tiE-21
2.2335E-OG
1.79G1E-07
4.0972E-4G
5. 02892-09
2.9768E-06
2.9777E-OG
4.0752E-04
2.9777E-OG
2.8973E-07
6.3G56E-07
6.31G6E-07
2.1293E-09
2.4018E-08
G.3827E-07
2.7G72E-08
6.3400E-08
9.2931K-09
tULUBLF: TO
STREAM
Cl
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
4.183GE-42
4.5679E-10
O.OOOOE+00
5.9859E-OG
7.0798E-14
2.8215E-OG
4.2748E-07
1.4654E-05
O.OOOOE+00
1.3410E-36
7.0051E-20
8.4G59E-42
AMOUNT AT
WELL
CI
1.1701E-05
5.2918E-03
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOH+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOK+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOL+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+-00
O.OOOOE+00
SOLUBLE 10
DEEP LAYERS
Cl
O.OOOOK+00
O.OOOOE+00
O.OOOOE+00
5.6104E-42
G.12b7L'-18
O.OOOOE+00
8.0273E-OG
9.4943E-34
I3.7037E-OG
5.732GE-0'/
1.9G51E-05
O.OOOOE+00
1.7983E-36
9. 394 IK- 20
1.1353E-41
A1MOSPHERE
AT SPILIAI3I-
CI/HAA3
O.OOOOK+00
O.OOOOE^OO
O.OOOOE+00
1.9874E-53
U.G797E-28
O.OOOOEfOO
2.843bE-17
1.2332E-25
1.3403E-17
2.0307E-1U
1.G242E-1G
O.OOOOE+00
9.3428E-48
9.9831E-32
8.0432E-55
ATMOSPHERE
DOWN WIND
CI/MAA3
O.OOOOE+00
O.OOOOE^OO
O.OOOOE+00
1.0388E-G4
4.5370E-39
O.OOOOE+00
1.4cJG4E-28
6.44GOE-37
7.0061E-29
1.0G1&E-29
8.4902E-2S
O.OOOOE+00
4.883GE-59
5.2184E-43
4.2044E-66
HELL WATER
CONC
CI/MAA3
7.2G01E-11
3.3035E-08
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
-------�
CS-134
CS-135
CS-137
CE-144
EU-154
U-234
U-2J5
NP-237
U-238
PU-238
PU- 23')
PU-240
PU-241
AM-241
PU-242
AM-243
CM-243
CM-244
1
1.7133K-25
3.7932E-10
3.0505E-11
7.9862E-50
4.6507E-12
3.2460F-10
3.2470E-10
l.Oi'JOE-37
3.2470E-10
2.4046E-10
5.2U34E-10
5.2427E-10
1.7G73E-12
5.1792K-10
3.297&E-10
5.9670E-10
4.9214E-11
7.213UE-12
1.7133E-25
3.7932E-10
3.0SObE-ll
7.2602E-50
1.2127E-12
4.3280E-10
4.3293E-10
2.0380E-35
4.3293E-LO
&.&702E-11
1.I5095E-10
1.4CJ79E-10
5.0496E-13
&.474JE-12
1.513&E-10
7.4588E-li>
1.49KJE-11
2.1BGOE-~li!
ANNUAL SUMMARY
5.5102E-?!
1.2199E-05
CJ.810GE-07
2.3350E-45
3.CJ001E-0(J
1.39]cJt-OB
1.3924E-05
G.b545E-31
1.3'J24E-05
2.201J5E-OG
4.Q548E-OG
4.8175E-OG
1.G240E-00
2.0821E-07
4.8G79E-06
2.3908E-07
4.79G3E-07
7.0304E-00
FOR YEAR 200
7.3894E-21
1.G360E-05
1.3156E-06
I3.1313E-45
5.2302E-08
1.8GG6E-05
1.8G72E--05
8.7897E-31
1.U672E-05
2.9G31E-OG
G.5105E-OG
G.4G04E-OG
•2.1778E-08
2.7922E-07
G.52U1E-06
3.2169E-07
6.4320E-07
9.4280E-08
1.7451E-31
3.0G34E-1G
3.10G9E-17
13.1341E-5G
4.940bL'~lU
3.3061E-16
3.3071E-1G
1.0379K-43
3.J071E-IG
2.4491E-1G
S.JI312E-IG
&.3398E-16
1.8001E-10
S.2751E-16
b.J9b7E-l&
6.077&E-1G
5.0125E-17
7.3473K-10
9.1217E-43
2.0195E-27
1.6241E-20
4.2518E-&7
2.5825E-2(J
1.72tl2L'-27
1.7287E-27
5.4252E-55
1.72U7E-27
1.2002E-27
2.B129E -27
2.7912E-27
9.4093E-30
2.7574E-27
2.G204E--27
3.1768E-27
2.G202E-28
3.840GE-29
O.OOOOL'+OO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE-tOO
O.OOOOIMOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
OF THE SIMULATION
U3
I
THE TRENCH CAP HAS HAD 30.00 PER CENT FAILURE
THE MAXIMUM POSSIBLE WATER DEPTH IN TRENCH DURING THE YEAR IS
2.2&11E-01 CUBIC METERS OF WATER LEFT BOTTOM OF TRENCH
O.OOOOE+00 CUBIC MEIERS OF WATER OVERFLOUED TRENCH
1.B1E-01 METERS
NUCLIDE TRANSPORT INFORMATION
NUCLIDE
H-3
C-14
CR-51
MN-54
FE-5b
CO-58
NI-59
CO-GO
NI-&3
SR-90
NB-94
TC-99
RU-10G
SB-125
1-129
CS-134
CS-135
CS-137
CE-144
EU-1S4
U-234
U-23b
NP-237
U-238
PU-238
PU-239
PU-240
AMOUNT IN
TRENCH
CI
1.5755E-06
2.01G7E-01
O.OOOOK+00
5.0573E-72
] .0383E-23
O.OOOOE+00
9.8b30E-01
1.2644E-12
2.1891E-01
6.2G20E-03
9.8187K-01
5.b270E-01
1.4718E-G1
4.2662E-23
8.G201E-01
1.1427E-30
9.8950E-01
7.tJtJ[(2E-03
O.OOOOE^OO
1.1734E-04
9.B884E-01
9.8940E-0]
9.0836E-01
9.8940E-01
2.0388E-01
9.0420E-01
9.G010E-01
TRENCH
OVERFLOW
CI
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEvOO
O.OOOOE+00
O.OOOOE+00
O.OOOOEhOO
O.OOOOE+00
O.OOOOE+00
O.OOOOEHOO
O.OOOOE^O
O.OOOOE+00
O.OOOOEHOO
O.OOOOEHOO
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOEHOO
O.OOOOE^O
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEi-00
TRENCH
DRAINAGE
CI
1.53G7E-00
1.9G70E-03
O.OOOOEHOO
9.45G5E-77
4.8G25E-30
O.OOOOE+00
1.8424E-0!)
6.4275E-17
4.0-333E-06
1.1709E-07
7.87G8E-OG
1.9960E-03
1.8775E-66
2.647GE-27
7.3892E-04
3.2101E-3G
2.7797E-OG
2.2188E-08
O.OOOOE+00
t).242GE-ll
3.7035E-OG
3.70iiGE-06
4.8360E-04
3.70b6E-OG
1.G368E-07
7.90J1E-07
7.7799E-07
AMOUNT AT
WELL
CI
2.4712E-08
3.1393E-03
O.OOOOEHOO
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOEH-00
O.OOOOEiOO
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
-------�
CD
I
CO
PU-241
AM-241
PU-242
AM-243
CM-243
CM-244
NUCL1LE
H-3
C-14
CR-51
MN-54
FE-55
CO-58
NI-59
CO-GO
NI-G3
SR-90
NB-94
TC-99
RU-106
SB-12S
1-129
CS-134
CS-137
CE-144
EU-1&4
U-234
U-235
NP-237
U-2313
PU-238
PU-239
PU-240
PU-24J
AM-241
PU-242
AM-243
CM-243
CM-244
1
1 .732bE-Ob
7.3193E-01
9.8950E-01
9.7J54E-01
1.0583E-02
2.6422E-04
SURFACE
SOIL CONC
CI/Klj
O.OOOOE+00
O.OOOOE+00
O.OOOOE-iOO
O.OOOOfciOO
5.4339E-33
0.0000E+00
1.2882E-12
6.4607fc--29
2.1JG21G -13
0.1074E-15
4.1993E-11
O.OOOOK+00
1.3307E-72
7.0tlbt-41
O.OOOOE+00
2.7427E--40
2.374bE-10
1.8957E-12
O.OOOOE+00
5.6789K-14
J.7391E-10
1.7402E-10
1.79b4E-6b
1.7402E-10
9.5422E-1]
4.GOG3E-10
4.M356t-10
6.1089E-J5
4.42G2E-10
4.G311E-10
5.0751E-10
4.(J734E-12
1.21GI3E-13
o.oooot+oo
O.OOOOE+00
O.OOOOE+00
O.OOOOL+00
O.OOOOE+00
O.OOOOE+00
SURFACE
HATER CONC
C1/MAA3
O.OOOOL+00
O.OOOOE+00
O.OOOOL+00
O.OOOOL+00
9.05G5E-34
O.OOOOE+00
8.5880E-12
1.1747L-27
1.9081E-12
5.4583E-14
1.1998E-10
O.OOOOEHOO
6.0487E-72
1 .5692E- 39
O.OOOOEfOO
2.7427E-40
2.374bE-10
1.8958E-12
O.OOOOh'HOO
1.4197E-14
2.3188E-10
2.3203E-10
3.5'J09E-63
2.3203E-10
2.7263K-11
l.:3161E-10
1.29b'JL-]0
2.3168E-lb
5.5327E-12
1.323HL-10
7.3439E-12
1.476t)E-12
3.6872E-14
J.3909E-]!
2.b709E-08
7.9436E-07
3.4125E-08
9.0107E-09
2.2497E-10
SOLUBLE TO
STREAM
LI
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOK+00
2.912GE-29
O.OOOOE+00
VJ.7G20E-07
3.7779E-23
G.1365E-08
1.7554E-09
3.I3SB7E-06
O.OOOOE^OO
1.9453E-G7
5.04GUE-35
O.OOOOE+00
ti.820t)E-3G
7.G36GE--OG
G.09G-JE-08
O.OOOOEHOO
4.&G60E-10
7.4576E-06
7.4622E-OG
l.lb49E-b8
7.4G22E-OG
0.7G82E-07
4.232GE-OG
4.1G77E-OG
7.4511E-11
1.7794E-07
4.2b54E-06
2.3Gl'JE-07
4.7495E-OCI
1.1858E-09
O.OOOOE+00
O.OOOOL+00
O.OOOOE+00
O.OOOOE-iOO
O.OOOOE+00
O.OOOOL+00
liOLUBLE 10
DEEP LAYERS
CI
O.OOOOK+00
O.OOOOE+00
O.OOOOE+00
O.OOOOL+00
I3.90GOE-29
O.OOOOE+00
3.7039E-07
5.06G3E-23
8.2293E-00
2.3541E-09
S.174GE-OG
O.OOOOE+00
2. 6007 E -67
6.7679K-3b
O.OOOOEfOO
l.lE)29L-3b'
1.0241L-05
U.17G2E-08
O.OOOOE+00
G.1231E-10
1.0001E-05
1.0007E-05
l.b4G7E-brd
1.0007E-05
1.1758E-06
5.G7G1E-OG
5.b'J(JOE-06
9.9922E-11
2.3862E-07
5.70&7E-06
3.1674E-07
6.3693E-08
1.5902E-09
ATMOSPHERE
AX SPILLAGE
C1/MAA3
O.OOOOE+00
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
5.3345E-39
O.OOOOE+00
L.3120E-10
G.bti03E-3b
2.9151E-19
8.33Q9E-2]
4.2770E-17
O.OOOOE+00
O.OOOOEHOO
7.1923E-47
O.OOOOE+00
2.7935K-46
2.418bE-16
1.930I3E-10
O.OOOOE+00
5.7Q40K-20
1.7713E-16
1.7724E-1G
1.8287E-71
1.7724E-1G
9.71&9E-17
4.G915E-1G
4.G196E-1G
8.2590E-21
4ib'08LE-lG
4.7168E-16
S.'JOJ'JE-IG
4.9636L-18
1.2393E-19
ATMOSPHERE
DOWN WIND
CI/MAA3
O.OOOOEHOO
O.OOOOE+00
0.0000fc<00
O.OOOOE+00
2.I.I030E-50
O.OOOOE<00
G.8I583E-30
3.4397E-46
1.5238E-30
4.3b09E-32
2.2357E-28
O.OOOOE+00
O.OOOOE+00
3.7595E-5B
O.OOOOE+00
1.4(i02E-57
1.2642E-27
1.0093E-29
O.OOOOE+00
3.0234E-31
9.2bcJOE-28
9.2648E-2B
O.OOOOE+00
9.2648E-28
b.0802E-2t)
2.4524E-27
2.4147K-27
4.3171E-32
2.35G5E-27
2.4G56E-27
J.1279E-27
2.5946E-29
6.4780E-31
HELL WATER
CONC
C1/MAA3
1.5334E-13
1.9479E-OB
O.OOOOfeiOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOK+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
ANNUAL SUMMARY FOR YEAR 300 OF THE SIMULATION
THE TRENCH CAP HAS HAD 30.00 PER CENT FAILURE
THE MAXIMUM POSSIBLE WATER DEPTH IN TRENCH DURING THE YEAR IS
2.2611E-01 CUBIC METERS OF HATER LEFT BOTTOM OF TRENCH
O.OOOOE+00 CUBIC METERS OF WATER OVERFLOWED TRENCH
1.81E-01 MEIERS
NUCLIDE TRANSPORT INFORMATION
NUCLIDE
AMOUNT IN
TRENCH
TRENCH
OVERFLOW
TRENCH
DRAINAGE
AMOUNT AT
WELL
-------�
CO
I
H-3
C-14
CR-51
MN-54
EE-55
CO-58
NI-59
CO-GO
NI-63
SR-90
NB-94
TC-99
RU-106
SB-125
1-129
CS-134
CS-13S
CS-13?
CE-144
EU-154
U-234
U-235
NP-237
U-238
PU-238
PU-239
PU-240
PU-241
AM-241
PU-242
AM-243
CM-243
CM-244
CI
2.0994E-09
7.5475E-02
O.OOOOEiOO
O.OOOOE^O
7.1G01E-3b'
O.OOOOE+00
9.B2GOE-01
2.3280E-18
1.0290E-01
b.5577E-04
9.7768E-01
3.852BE-01
O.OOOOEiOO
5.8880E-34
7.9I22E-01
2.9208E-45
9.U1J19E-0]
7.8374E--04
O.OOOOE+00
].b449E-06
9.8818E-01
9.8902E-01
8.6124E-01
-------�
U-2.313
PU-238
PU-239
PU-240
F'U-241
Ah-241
PU-242
AM-243
CM-24J
CM-244
1
9
3
4
3
3
4
5
.3271E-11 1.
.7HG5E-11 1.
.0159E-10 1.
!7ii05E-17 l!
.7820.E-10 4.
.0404E-IO 1.
.7CI4GE-10 7.
ANNUAL'
243GE-10
oai'jK-n
1474E-10
1211E-10
OG30E-17
7202E--12
15G7E-10
2300E-12
4G24E--13
2192E-16
SUMMARY
3.999GE-OG
3.4794E-07
3.G902E-OG
J.G05GE-OG
3.41U7E-13
1.520GE-07
3.7200E-OG
2.3255E-07
4.7032E-09
2.0001E-11
FOR YEAR 400
5
4
4
4
4
2
4
3
G
2
OF
.3G3GE-OG 9.4998E-17
.GGGOE-07 3.85GGE-17
.9486E-OG 4.0902E-1G
.8352E-OG :3.9%!5E--1G
.504&E-13 3.7EI94E--23
.0392K-07 3.8b2GE-16
.rJ887E-06 4.1234E-16
. 1106E-07 5.8917E-H)
.3071E-09 4.91S2E-19
.G023E-H D.0903E-21
THE SIMULATION
4
9
2
2
2
3
2
.9G57E-28
.0159E-28
.138JE-27
.OU90E-27
.9U08E-34
.0138E-27
.1554E-27
.0797E-27
.5G93E-30
.092GE-32
0
0
0
0
0
0
0
0
0
0
.OOOOE+00
.OOOOEHOO
.OOOOE+00
.OOOOE+00
.OOOOEHOO
.OOOOE+00
.OOOOE+00
.OOOOE+00
.OOOOE+00
.OOOOE+00
THE TKL'NCH LAP HAS HAD 30.00 PKK CENT FAILURE
THE MAXIMUM POSSIBLE UATEk DEPTH IN TRENCH DURING THE YEAR IS
2.2&11E-01 CUBIC hETERS OF WATER LEt'l BOTTOM OF TRENCH
0.OOOOE+00 CUBIC METERS Of WATER OVERFLOWED TRENCH
1.81E-01 METERS
CO
I
o NUCLIOE
H-3
C-14
CR-51
MN-54
FE-55
CO-58
NI-59
CO-GO
NI-G3
SR-90
NB-94
IC-99
RU-106
SB-125
1-129
CS-134
CS-135
CS-137
CE-144
EU-154
U-234
U-235
NP-237
U-238
PU-238
PU-23'J
PU-240
PU-241
AM-241
PU-242
AM-243
CM-243
CM-244
NUCIJUE TRANSPORT INFORMATION
AMOUNT IN
TRENCH
CI
2.7974E-12
2.fi/l48L-02
0. OOOOE+00
0. OOOOE+00
4.937GE-4G
0. OOOOE+00
9.7991E-01
4.28G2E-24
4.B368E-02
4.9327E--05
9.7H51E-01
2.6850E-01
0. OOOOE+00
0.]?G4E-4b
7.2624E-01
7.4656E-60
9.8889E-01
7.7771E-05
0. OOOOEHOO
2.0341E-08
9.8753E-01
9.8864E-01
8.1656E-01
9.88G4E-01
9i7b40E-0]
9.4862E-01
4.7697E-10
5.4113L?-01
9.H09GE-0]
9.5343E-01
1.3793E-04
9.'J'J13E-08
TRENCH
OVERFLOW
CI
0. OOOOE+00
0. OOOOE+00
0. OOOOE+00
0. OOOOEHOO
0. OOOOE+00
0. OOOOE+00
O.OOOOEi-00
0. OOOOE+00
0. OOOOE+00
0. OOOOE+00
0. OOOOEHOO
0. OOOOEHOO
0. OOOOE+00
0. OOOOE+00
O.OOOOfihOO
0. OOOOE+00
0. OOOOE+00
0. OOOOE+00
0. OOOOE+00
0. OOOOE+00
0. OOOOE+00
0. OOOOE+00
0. OOOOE+00
O.OOOOE^O
0. OOOOE+00
0. OOOOE+00
0. OOOOE+00
0. OOOOEHOO
0. OOOOE+00
0. OOOOE+00
0. OOOOE+00
0. OOOOE+00
O.OOOOE-tOO
TRENCH
DRAINAGE
CI
2.7286E-14
2.7552E-04
0. OOOOE+00
0. OOOOE+00
2.3123E-52
0. OOOOE+00
1.032JE-05
2.1788E-28
9.0441E-07
9.2234E-10
7.8097E-OG
9.G995E-04
0. OOOOE+00
5.0433E-4rJ
G.2253E-04
2.0973E-G5
2.7780E-OG
2.1848E-JO
0. OOOOE+00
1.4289E-14
3.G98GE-OG
3.7027E-OG
4.3473E-04
3.7027E-OG
3.3705E-00
7.8S45E-07
7.G154E-07
3.8291E-16
1.9007E-08
7.9393K-07
3.3489E-08
1.1744E-10
8.5070E-14
AMOUNT AT
WELL
CI
S.3200E-14
S.3313E-04
0. OOOOE+00
O.OOOOL' + OO
0. OOOOE+00
0. OOOOE+00
0. OOOOE+00
0. OOOOE+00
0. OOOOE+00
0. OOOOE+00
0. OOOOE+00
2.0008E-03
0. OOOOE+00
0. OOOOE+00
6.4526E-04
0. OOOOE+00
0. OOOOE+00
0. OOOOE+00
0. OOOOE+00
0. OOOOE+00
0. OOOOE+00
0. OOOOE+00
0. OOOOE+00
0. OOOOE+00
0. OOOOE+00
0. OOOOE+00
0. OOOOE+00
0. OOOOE+00
0. OOOOE+00
0. OOOOE+00
0. OOOOEHOO
0. OOOOE+00
O.OOOOli+OO
-------�
NUCLIHE
H-3
C-14
CR-51
MN-54
FE-55
CO-58
NI-59
CO-GO
NI-63
SR-90
NB-94
IC-99
RU-106
SB-125
1-129
CS-134
CS-135
CS-137
CE-144
EU-154
U-234
U-235
NP-237
U-238
PU-238
PU-239
PU-240
PU-241
AM-241
F'U-242
AM-243
CM-243
CM-244
GUK'FACE
SOIL CONC
CI/KG
O.OOOOE+00
O.OOOOEHOO
O.OOOOEHOO
O.OOOOE+00
2.2093E-55
O.OOOOE+00
2.7426E-15
1.839GE-47
1.3530E-1G
1.3007E-19
2.9U7E-12
O.OOOOE+00
O.OOOOE+00
3.6G52E-71
O.OOOOEHOO
'/.02U5E-70
9.3084E-11
7.HiU7E-15
O.OOOOEHOO
7.783GE-18
4.9930E- 11
4.9990E-11
O.OOOOE+00
4.9990E-11
1 . ti 0 '*! 5 E - 1 1
3.5010E-10
3. 3944E-10
1.7070L-19
3.2324E-10
3.538&F.-]0
5.G95GE-10
4.77SH8E-14
•J.4G17E-17
SURFACE
HATER CONC
CI/MAA3
O.OOOOE^O
O.OOOOEHOO
O.OOOOb' + OO
O.OOOOE+00
3.G822E-5G
O.OOOOE^O
1.8284E-14
3.3448E-46
9.025GE-1G
9.2045E-19
8.3192E-12
O.OOOOE+00
O.OOOOE+00
8.1449E-70
O.OOOOE+00
7.0205E-70
9.3084C--H
o!p6opE+oo
&'.G574E-11
G.GG54E-11
O.OOOOfc+00
G.GG54E-11
l!o003£-10
9.G904F;-!!
4.8773E-20
4.0405E-12
1.0J11E-10
7.1195E-12
1.44K1E-14
1.0490E-17
SOLUBLE TO
STREAM
Cl
O.OOOOE+00
O.OOOOEHOO
O.OOOOEHOO
O.OOOOE+00
1.1842E-51
O.OOOOE^O
5.8Q03E-10
1.0757E-41
•4.0027E-11
2.9603E-14
2.G755E-07
O.OOOOE+00
O.OOOOE+00
2.G195E-G5
O.OOOOE+00
2.2G04E-65
2.9937E-OG
2.3547E-10
O.OOOOEHOO
6.2582E-14
2.1411E--OG
2.1437E-OG
O.OOOOE+00
2.1437E-OG
1.3806E-07
3.2171E-OG
3.1191E-OG
1.5686E-15
1.2995E-07
3.251tlE-Ofi
2.2897E-07
4.G573E-10
3.3737E-V3
SOLUBLE 10
DEEP LAYERS
Cl
O.OOOOE+00
O.OOOOEHOO
O.OOOOEHOO
O.OOOOE+00
1.5881E-51
O.OOOOEi-00
7.885GE-10
1.442GE-41
3.892GE-U
'J 9698 E -14
3.5880E-07
O.OOOOE+00
O.OOOOEHOO
3.512BE-G5
O.OOOOEHOO
3.0313E-65
4.014GE-OG
3.157UL-10
O.OOOOE+00
0.092SE-14
2.8713K-06
2.8747E-06
O.OOOOE+00
2.8747E-OG
1.8515E-07
4.3142E-OG
4.1820E-06
2.1035E-15
1.74'^GE-07
3i070GE-07
G.24&6E-10
4.5242E-13
ATMOSPHERE
AT SPILLAGE
C1VMAA3
O.OOOOE+00
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
2.2502E-61
O.OOOOE+00
2.7934E-2]
1.8737E-53
1.J709E-22
1.4062E-25
2.965GE-1G
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
7.1506E-76
9.4807E-17
7.4573E-21
O.OOOOE+00
7.9278E-24
1 0055E-17
b!o916E-17
O.OOOOEHOO
b.O'JIGE-r;
1.5303E--17
3.5G59E-1G
3.4573E-36
1 7 3 0 6 F ~ 'J b
3.2-J22E-1G
3.6044E-16
5.D010E-1G
4.8672E-20
3.52S8E-23
ATMOSPHERE
DOWN RIND
C1/MAA3
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
1.17G2E-72
O.OOOOE+00
1.4G01K-32
9.7941E-6B
7.2078E-34
7.3507E-37
1.5S02E-29
O.OOOOEHOO
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
4.95b8E-2G
3.8901E--32
O.OOOOE+00
4.1440E-35
2.G503E-28
2.6G15E-211
O.OOOOEHOO
2.661bE-28
7.9992E-29
1.0639E-27
1.0072E-27
9.0Q82E-37
1.7209E-27
1.8041K-27
J.0323E-27
2.5442E-3]
1.I3430E-34
WELL WATER
CONC
C1/MAA3
3.3010E-19
3.3080E-09
O.OOOOE+00
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOEHOO
O.OOOOEHOO
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
1.24J5E-08
O.OOOOEHOO
O.OOOOE+00
4.0038E-09
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
ANNUAL SUMMARY FOR YEAR 500 OF THE SIMULATION
THE TRENCH CAP HAS HAD 30.00 PER CENT FAILURE
THE MAXIMUM POSSIBLE WATER DEPTH IN TRENCH DURING THE YEAR IS
2.2G11E-01 CUBIC METERS OF WATER LEFT BOTTOM Of TRENCH
O.OOOOE+00 CUBIC METERS OF WATER OVERFLOWED TRENCH
1.81E-01 METERS
NUCLIHE TRANSPORT INFORMATION
NUCL1HE
H-3
C-14
CP-51
MN-54
FE-55
CO-5&
NI-59
AMOUNT IN
TRENCH
Cl
3.727&E-15
1.0572E-02
O.OOOOEiOO
O.OOOOE+00
3.40&OE-57
O.OOOOE+00
9.7723E-01
TRENCH
OVERFLOW
Cl
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
TRENCH
DRAINAGE
Cl
3.G359E-17
1.0312E-04
O.OOOOE+00
O.OOOOEHOO
1.5CJ46E-G3
O.OOOOEHOO
1.0273E-05
AMOUNT AT
WELL
Cl
7.0B90E-17
1.9953E-04
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
-------�
NUCLIDE
H-3
C-14
CR-51
MN-54
FE-5&
CO-58
NI-59
CO-60
NI-63
SR-90
NB-94
IC-99
RU-10G
SB-12b
1-129
CS-134
CS-135
CS-137
CE-144
EU-154
U-234
U-235
NP-237
U-238
PU-238
PU-239
PU-240
PU-241
AM-241
PU-242
AM-243
7.D'J1GE-30
2.273GE-02
4.3779E-OG
9.6935E-01
1.8722E-01
O.OOOOEHOO
1.121GE-55
G.6659E-01
1.9083E-74
9.8859E-01
7.7172E-OG
O.OOOOE+00
2.G782L-10
9.8G88E-01
9.fcl827E-01
7.7420E-01
9.fJf(27E-01
l.'J053E-02
9.7551E-01
9.3f(53E-01
2.502GE-12
4.G529E-01
9.88G9E-01
9.44SOE-01
1.5747E-05
1.9429E-09
SURFACE
SOIL CONC
CI/KG
O.OOOOEHOO
O.OOOOEHOO
O.OOOOEHOO
O.OOOOE+00
1.4087E-66
O.OOOOEHOO
1.2655E--16
9.8164E-57
2.944bF-]tl
5.GG97E-22
7.6G70E-13
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
5.8277E-11
4.5502E-16
O.OOOOE+00
9.112GE-20
2.6753E-11
2.6793E-11
O.OOOOE+00
:•!.(. 793E-H
5.9G24E-12
3.0&22E-10
2.
-------�
CM-243 4.7322E-15 1.4340E-lb 4.G119E-1] 6.18471;- ] ]. 4.H19UE-2] 2.5194E-32 O.OOOOE+00
CM-244 5.83B8E-19 1.7693E-19 5.G904E-15 7.6310E-15 5.9469E-25 3.1086E-36 O.OOOOE+00
1 ANNUAL SUMMARY FOR YEAR 600 OF THE SIMULATION
THE TRENCH CAP HAS HAD 30.00 PER CENT FAILURE
THE MAXIMUM POSSIBLE WATER DEPTH IN TRENCH DURING THE YEAR IS
2.2611E-01 CUBIC METERS OF WATER LEFT BOTTOM OF TRENCH
O.OOOOE+00 CUBIC METERS OF WATER OVERFLOWED TRENCH
1.81E-01 METERS
NUCLlDi: TRANSPORT INFORMATION
NUCLIDE
DO
1
ro
CO
H-3
C-14
CR-51
MN-54
CO-58
NI-59
CO-GO
NI-63
SR-90
NB-94
IC-99
RU-106
SB-125
1-12-3
CS-134
CS-135
CS-137
CE-144
EU-154
U-234
U-235
NP-237
U-238
PU-238
PU-239
PU-240
PU-241
AM-241
PU-242
AM-243
CM-243
CM-244
NUCLIDE
H-3
C-14
CR-51
AMOUNT IN
TRENCH
CI
4.%70E-18
3.95G7E-03
O.OOOOE-iOO
O.OOOOE+00
2.3401E-G8
O.OOOOE+00
9.745&E-0]
1.4530E-35
1.0G87E-02
3.8C55E-07
9.6522E-01
I .3051E-01
O.OOOOE+00
1.5479E-66
&.1185E-01
O.OOOOEHOO
9.ti8?.OE-01
7.G578E-07
O.OOOOtHOO
3.52&2E-12
9.fH623F-01
9.d7ft9E-01
7.3404E-01
9.8709F-01
8.64GOE-03
9.72&3E-01
9.285GE-01
1.3131E-14
4.0007E-01
9.8842E-01
9.3tJGGE-01
1.7977E-06
3.77blE-ll
SURFACE
SOIL CONC
CI/KG
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
TRENCH
OVERFLOW
CI
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE-iOO
O.OOOOE+00
O.OOOOE-iOO
O.OOOOE+00
O.OOOOE+00
0.00001^00
o.oooomoo
O.OOOOE+00
O.OOOOEKOO
O.OOOOE+00
O.OOOOE+00
O.OOOOt'HOO
O.OOOOE+00
O.OOOOEvOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE^O
O.OOOOE-iOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE-iOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE-iOO
SURFACE
HATER CONC
C1/MAA3
O.OOOOE-iOO
O.OOOOE+00
O.OOOOE-iOO
TRENCH
DRAINAGE
CI
4.G448E-20
3.U593E-05
O.OOOOE+00
O.OOOOEtOO
1.099GE-74
0.00001UOO
1.8223E-05
7.3860E-40
1.9984E-07
7.2653E-12
7.7431E-OG
4.7132E-04
O.OOOOE+00
9.60&7E-71
5.244t)E-04
O.OOOOEiOO
2.77G3E-06
2.1512E-12
O.OOOOE+00
2.4769E-18
3.G937E-06
3.G999E-06
3.9080E-04
3.6999E-OG
6.9410E-09
7.8082E-07
7.4544E-07
1.0542E-20
1.4052E-08
7.9350E-07
3.2865E-08
1.5;J07E-12
3.2169E-17
SOLUBLE TO
STREAM
CI
O.OOOOE^O
O.OOOOE+00
O.OOOOE+00
AMOUNT AT
WELL
CI
9.4462E-20
7.4679E-05
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE-iOO
O.OOOOE+00
O.OOOOE+00
9.7G35E-04
O.OOOOE+00
O.OOOOE+00
G.7592E-04
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
o.oooot;+oo
O.OOOOH+00
O.OOOOE+00
o.oooot+oo
O.OOOOE+00
O.OOOOE-iOO
O.OOOOE+00
O.OOOOE+00
O.OOOOEiOO
O.OOOOE+00
O.OOOOE-iOO
O.OOOOE+00
O.OOOOE+00
SOLUBLE TO ATMOSPHERE
DEEP LAYERS AT SPILLAGE
Cl L1/MAA3
O.OOOOE+00 O.OOOOE+00
O.OOOOE+00 O.OOOOEhOO
O.OOOOE+00 O.OOOOE+00
ATMOSPHERE WELL WATER
DOWN HIND CONC
CI/MAA3 U1/MAA3
O.OOOOE+00 5.8G13E-25
O.OOOOEi-00 4.6338E-10
O.OOOOE+00 O.OOOOE+00
-------�
CO
I
ro
HN-54
FE-55
CO-5G
NI-59
CO-GO
NI-G3
SR-90
NB-94
TC-99
RU-10G
SB-125
1-129
CS-134
CS-135
CS-137
CE-144
EU-154
U-234
U-235
NP-237
U-238
PU-230
PU-239
PU-240
PU-241
AM-241
PU-242
AM-243
CM-243
CM-244
1
O.OOOOEK)0
8.9fi:il9E-78
O.OOOOE+OO
5.0391E-18
b.:.:3aiE-66
6.4039E-20
2.:J28'JE-24
2.01U9E-13
O.OOOOE+00
O.OOOOEHOO
Q.OOOOE+00
O.OOOOEHOO
O.OOOOE>00
3.G487E-11
2.8277E-17
O.OOOOEHOO
1.0GG9E--2L
] .4333E-11
1.4359E-11
O.OOOOE+00
1.4359E-1]
2.3G60E-12
2.&G08E-10
2.&401E-10
3.5935E-24
2.3603E-10
2.7040E--10
S.5218E-10
4.&8&1E-1&
9.8484E-21
O.OOOOE+00
1.4973E--'/&
O.OOOOEHOO
3. 8927 E- 17
9.5239E-&5
4.2G93E-19
1.5522E-23
b.7G84K-13
O.OOOOEi-00
O.OOOOE+OO
O.OOOOE+00
O.OOOOEHOO
O.OOOOEHOO
3.6487E-11
2.B27HE-17
O.OOOOEHOO
2.G&71E-22
] .9111E--11
1.9145E-11
O.OOOOH+00
1.9145t-ll
6.7GOOE-13
7.G023E-11
7.2b76E-ll
1.0267E-24
2.9S04E-12
7.725BE-11
G.9022E- 12
1.4200E-1G
2.9844E-21
ANNUAL SUMMARY
O.OOOOE+00
4.B155E-74
O.OOOOK+00
1.2519E-12
3.0G30K-GO
].3730E-14
4.9920E-19
] .85b2E-08
O.OOOOE+00
O.OOOOE400
O.OOOOE-tOO
O.OOOOE+00
O.OOOOE+00
1.1735E-06
9.0943E- 13
O.OOOOEHOO
8.577I3E-UJ
G.14G1E-07
G.1573E-07
O.OOOOE+00
G.1573E-07
2.1741E-08
2.4450E-06
2.3341E-OG
3.3021E-20
9.4887E-OU
2.4047E-OG
2.2198E-07
4.5GG9E-12
9.5980E-17
FOR YEAR 700
O.OOOOE+00
6.4570E-V4
O.OOOOE+00
1.G789E-12
4.107GE-GO
1.8413L-14
6.6944E-19
2.4879F-08
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOE'+OO
O.OOOOE+00
1.5737E-OG
1.219GE-12
O.OOOOE+00
1.1503E-17
8.2422E--07
8.2572E-07
O.OOOOE+00
8.2572E-07
2.9155E-08
3.278BE-OG
3.1301E-06
4.4282E-20
I.2725E-07
3.3321E-0&
2.97G9E-07
G.1244E-12
1.2871E-16
o.ooooe^o
O.OOOOE+00
O.OOOOEHOO
5.9472E-24
e,.335]E-72
6.522SI;- H6
2.3714E-30
2.0SG3E-19
O.OOOOE+00
O.OOOOEHOO
O.OOOOEHOO
O.OOOOEHOO
O.OOOOE^O
3.71G3E-17
2.8801E-23
O.OOOOE+00
1.08G6E-27
1.4590E-17
1.4&25E-17
O.OOOOH+00
1.4G25E--17
2.40cJtlE-18
•
-------�
CO
I
ro
01
NULL IDE
H-3
C-14
CR-51
MN-54
FE-5&
CO-58
NI-59
CO-GO
NI-63
SR-90
NB-94
TC-99
RU-106
SB-125
1-129
CS-134
CS-135
CS-137
CE-144
EU-154
U-234
U-235
NP-237
U-238
PU-238
PU-239
PU-240
PU-241
Ah-241
PU-242
AM-243
CM-243
CM-244
1
O.OOOOE+00
9.f.r/9UE-oi
7.5988E-08
Q.OOOOFHOO
4.642GE-14
9.8558E-01
9.87b2E-01
6.9596E-01
9.B752E-01
3.9234E-03
9.G97GE--01
9.1Q&9E-01
G.8899E-17
3.4399E-01
9.881&E-01
9.2&G9E-01
2.0*.24E-07
7.3469E-13
SURFACE
SOIL CONC
CI/Kls
O.OOOOE+00
O.OOOOE+00
O.OOOOE-iOO
O.OOOOEfOO
O.OOOOE+00
O.OOOOE+00
2.Grj42E-l'J
2./954E--75
1.3928F--21
9.J&11E-27
5.31&2E-14
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOFHOO
O.OOOOE+00
2.2(J43E-11
l.Vj73L-18
O.OOOOEi-00
1.2490E-23
7.6800E-12
7.G9&2L-12
O.OOOOE+00
'/.69G2E- 12
9.3883E-13
2.3]'J5E-10
2.19/ME-10
].G4iJbE-2&
2.017,IE-10
2.3634E-10
5.4370E-10
4.6403E-17
1.G&11E-22
/, UUI
O.OOOOE+00
O.OOOOE+00
O.OOOOEi-00
O.OOOOE+00
O.OOOOE^O
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEhOO
O.OOOOFHOO
O.OOOOE+00
O.OOOOIHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOIHOO
0.00001^00
SURFACE
WATER CONC
CI/MAA3
o.oooot+oo
O.OOOOE+00
O.OOOOE-iOO
O.OOOOE+00
O.OOOOKiOO
O.OOOOE^O
1.7961E-18
5.0a26E-74
9.2853K-21
6.3743E-26
1.5189E-13
O.OOOOE+00
O.OOOOE-iOO
O.OOOOE+00
O.OOOOEiOO
O.OOOOE^O
2.284::L'-1]
].7d73E-l{!
O.OOOOE+00
3.122&E--24
1.0240E-11
1.0262E-]]
O.OOOOE^O
1.0262E-11
2.G824E-13
6.G273E-13
6.2784E-11
4.710BK-27
2.5216E-12
G.752'/L-11
G.7962E-12
1.4062E-17
5.0337E-23
IAI OIIUUADV t'
O.OOOOE+00
2.7754E-06
2.1347E-13
O.OOOOENOO
3.2612E-20
3.&913E-0&
3.6905E--OG
3.7052E-04
3.6985E-06
3.1497E-09
7.7052E-07
7.3752E-07
5.5:illE-23
1.2083E-OU
7.9328E-07
3.;;b57E-08
1.7475E-13
6.2555E-I9
SOLUBLE TO
STREAM
Cl
O.OOOOE+00
O.OOOOE^O
O.OOOOE+00
O.OOOOE+00
O.OOOOM+00
O.OOOOE+00
5.77G6E-14
1.6346E-69
2.90G2E-1G
;i.0&00b'-21
4.8850E-09
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
7.34G5E-07
&.G518E-14
O.OOOOE+00
1.0042E-19
3.2933E-07
3.3002E-07
O.OOOOE+00
3.3002L-07
8.G2G7E-0-J
2.1314K-06
2.0192E-OG
1 .5150E-22
8.1096E-08
2.1717E-OG
2.1857E-07
4.5224E-13
1.G189E-.18
fill V L- A D fj f\ t
O.OOOOE+00
O.OOOOFHOO
O.OOOOE+00
O.OOOOK+00
O.OOOOE-iOO
O.OOOOE+00
O.OOOOE^O
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOFHOO
O.OOOOE+00
O.OOOOFHOO
O.OOOOE+00
O.OOOOE-iOO
O.OOOOK+00
O.OOOOE+00
SOLUBLE TO
DEEP LAYERS
(:]
O.OOOOE-i-00
O.OOOOEi-00
O.OOOOE-iOO
O.OOOOE+00
O.OOOOE+00
O.OOOOEfOO
7.74G.GE-14
2.1921E-69
4.0047E-16
2.7491K-21
6.5510E-0'j
O.OOOOFHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOIH-OO
O.OOOOE+00
y.85)9L'-07
7.5792E-14
O.OOOOEi-00
1.34G7E- 19
4.41G4E-07
4.42b7E-07
O.OOOOEi-00
4.4257E-0'/
1.15G9E-01)
2.8b83E-06
2.7070E-OG
2.0317E-22
1.0875E-07
2.9124E-06
2.9311E-07
6.064GE-13
2.1710E-10
^ frl? TUf r 1 Ul ll
ATMOSPHERE
AT SPILLAGE
CI/MAA3
O.OOOOEiOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
2.7441E-2ti
O.OOOOEHOO
].418GF:-27
9.7381E-33
5.414GE-20
O.OOOOE-iOO
O.OOOOE+00
O.OOOOE+00
O.OOOOFHOO
O.OOOOEK>0
2.32GGE-17
1 .7899E-24
O.OOOOE+00
1.2721L- 29
7.8222E-18
7.8307E-38
O.OOOOEfOO
7.B387E-18
9.b&21C-19
2.3625E-1G
2.-2I381E-1G
1.G793E-32
2.0S4GE-16
2.4072E-1G
5.537GE-1G
4.7262E-23
1.6919E-28
i A n- Tnn
ATMOSPHERE
DOWN WIND
C1/MAA3
O.OOOOE+00
O.OOOOE+00
O.OOOOE-iOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
] .4344E-36
O.OOOOE+00
7.4152E-39
5.0903E-44
2.B303E-31
O.OOOOE+00
O.OOOOE-iOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE i-OO
1.2361E-28
9.35GOE-3G
O.OOOOE+00
G.G496E-4]
4.080UE-29
4.0974E-29
O.OOOOE+00
4.0974E-29
4.9983E-30
1.2349E-27
1.1699E-27
8.778JE-44
1.0740E-27
1.2583E-27
2.&946E-27
2.4'/Ob'E-34
B.8438E-40
WELL WATER
CONC
UI/HAA3
7.8102E-28
1.7342E-10
O.OOOOE+00
O.OOOOE+00
O.OOOOFHOO
O.OOOOE+00
O.OOOOK+00
O.OOOOE+00
O.OOOOK+00
O.OOOOE+00
O.OOOOE+00
4.2231E-09
O.OOOOE+00
O.OOOOE+00
3.849GE-09
O.OOOOE+00
O.OOOOK+00
O.OOOOE-iOO
O.OOOOE+00
O.OOOOFHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE-f 00
O.OOOOE+00
O.OOOOE-iOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE-iOO
O.OOOOE+00
THE TRENCH CAP HAS HAD 30.00 PER CENT FAILURE
THE MAXIMUM POSSIBLE WATER DEPTH IN TRENCH DURING THE YEAR IS
1.81E-01 METERS
-------�
2.2G11E-01 CUBIC METERS OF WATER LEFT BOTTOM OF TRENCH
O.OOOOE+00 CUBIC METERS Of WATER OVERFLOWED TRENCH
NUCL3DE TRANSPORT INFORMATION
DO
I
cn
NUCL1UE
H-3
C-14
CR-51
MN-54
EE-55
CO-53
NI-59
CO-60
NI-G3
SR-90
NB-94
TC-99
RU-106
SB-125
1-129
CS-134
CS-135
CS-137
CE-144
EU- 1 54
U-234
U-235
NP-237
U-238
PU-23Q
PU-23'3
PU-240
PU-241
AM-241
PU-242
AM-243
CM-243
CM-244
AMOUNT IN
IRtNCH
CI
B.t094E-24
5.3424E-04
O.OOOOE+00
O.OOOOE+00
O.OOOOE-iOO
O.OOOOEtOO
9.G923L-01
4.9253E-47
2.3G14E-03
3.060GE-09
9.5699E-01
G.3414E-02
O.OOOOE+00
O.OOOOL<00
5.1547E-01
O.OOOOE+00
9.8767E-01
7.5404E-09
O.OOOOE+00
6.112GE-16
9.B493E-01
9.8715E-01
6.598GE-01
9.8715E-01
1.7&05E-03
9.G691E-01
9 0 & 'j 3 E - 0 1
3.6151E-19
2.9577E-01
9. tf'/'89E-01
9.1821E-01
2.3431E-08
1.4287E-14
TRENCH
OVERFLOW
CI
O.OOOOE-iOO
O.OOOOEi-00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE^O
O.OOOOE-iOO
O.OOOOE+00
O.OOOOh'-iOO
O.OOOOE+00
O.OOOOE-iOO
O.OOOOE^O
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOK-iOO
O.OOOOE+00
O.OOOOE^O
O.OOOOb'+OO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
o.ooootuoo
O.OOOOEiOO
O.OOOOE+00
O.OOOOE^O
O.OOOOE-iOO
O.OOOOE+00
O.OOOOE^O
O.OOOOE+00
TRENCH
DRAINAGE
CI
8.G023E-2G
5.40GOE-OG
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
3.8123E-05
2.5037E-51
4.4154E-OI3
5.7230E-14
7.G772E-OG
2.2901E-04
O.OOOOE+00
O.OOOOF-iOO
4.4187K-04
O.OOOOEiOO
2.774GE-06
2.13B3E-14
O.OOOOE+00
4.2938E-22
3.GBB8E-06
3.6972E-OG
3.5130E-04
3.6972E-OG
1.4293E-09
7.7G23E-07
7.2968E-07
2.9021E-25
1.0389E-08
7.9307E-07
3.2252E-08
1.9950E-14
1.2164E-20
AMOUNT AT
WELL
CI
KG772K-25
1.0460E-05
O.OOOOli+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE-iOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
4.7444E-04
O.OOOOE+00
O.OOOOE-iOO
5.G946E-04
O.OOOOE-iOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE-iOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE-iOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE-iOO
O.OOOOE+00
NUCL1HE
H-3
C-14
CR-51
MN-54
FE-55
CO-58
NI-59
CO-GO
NI-G3
SR-90
NB-94
SURFACE
SOIL CONC
CI/KG
O.OOOOE+00
0.00006+00
O.OOOOFNOO
O.OOOOFHOO
O.OOOOE+00
O.OOOOE+00
1.2431E-20
O.OOOOE+00
3.0292E-23
3.'J263E-2
-------�
TC-99
RU-10&
SB-125
1-129
CS-134
CS-13J.
cs-ij-;
CE-144
EU-154
U-234
U-23b
NP--237
U-238
PU-23G
PU-239
PU-240
PU-241
AM-241
PU-242
AM-243
CM-243
CH-244
1
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE^O
O.OOOOE^O
1.4299E-11
1.0921E-19
O.OOOOE^O
1.4623E-25
4.I150K-12
4.1249E-12
O.OOOOEi-00
4.1249E-12
3.7256E-13
2.0224E-10
1.9012E-10
7.5G49E-29
1.7241E- 10
2.0GG2E-10
5.3b35E-10
4.5951E-18
2.U019E-24
O.OOOOE^O
O.OOOOE+00
O.OOOOE^O
O.OOOOE-fOO
O.OOOOE+00
1.4299E--11
1.0921E-19
O.OOOOHOO
3.GS56E-26
5.4867E-12
5.499'JE-12
O.OOOOEVOO
b.4999E-];i
1.064bE-13
5.'/7l;4E-ll
5.4321E-11
2.1614E-29
2.1S51E-1?.
5.9035E-11
6.6'J]8E-12
1.3925E-18
8.4(JObE-^!5
ANNUAL SUMMARY
O.OOOOE+00
O.OOOOEiOO
O.OOOOE+00
O.OOOOE^OO
O.OOOOE+00
4.5(JGOE-07
3.5124E-15
O.OOOOEHOO
1.1757E-21
1.7646E-07
1.76BtlE-07
O.OOOOE+00
1.7688E-07
3.4234K-09
1.8504E-06
1.7470E-06
6.9S13E-25
6.930CJE-OU
1.8986E-06
2.1522F-07
4.4783E-14
2.7306E-20
EGR YEAR 900
O.OOOOE+00
O.OOOOE+00
O.OOOOE^O
O.OOOOE+00
O.OOOOE+00
6.1672E-07
4.7102E-15
O.OOOOE+00
1.5766E-21
2.3664E-07
2.3720E-01/
O.OOOOE+00
2.3720E-07
4.&909E-09
;;.4cJ22i:-06
2.3428E-06
9.3219E-25
9.294GE--OU
2.54G1E-OG
2.88G1E-07
G.0055E-14
3.GG19E-20
O.OOOOGfOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
].45G4E-]7
1.1123E-25
O.OOOOE+00
1.4d93E-31
4.19]?L'-18
4.2013E-18
O.OOOOE+00
4.2013E-1U
3.7946E-19
2.0599E-16
1.93G4E-16
7.7050E-35
1.7S60E-1G
2.1045E-1G
&.4526E-1G
4.GU02G-24
2.B537E-30
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
o.ooooe+oo
7.G129E-29
5.8144E-37
O.OOOOL+00
7.7850E-43
2.1908E-29
2.1961K-29
O.OOOOE+00
2.19G1E-29
1.9U3SE-30
1.0767E-27
].0]22E-27
4.0275E-4G
9.1788E-28
1.1000E-27
2.8502E-27
2.44G4E-35
1.4
-------�
U-238
PU-230
PU-239
PU-240
PU-241
AM-241
PU-242
AM-243
CM-243
CM-244
NUCL1DE
H-3
C-14
CR-51
MN-54
FE-55
CO-58
NI-59
CO-GO
NI-G3
SR-90
^ NB-94
rlo TC-99
03 RU-10G
SB-125
1-129
CS-134
CS-135
CS-137
CE-144
EU-154
U-234
U-235
NP-237
U-238
PU-230
PU-239
PU-240
PU-241
AM-241
PU-242
AM-243
CM-243
CM-244
1
9.8b78E-01
8.0797E-04
9.6406E-01
8.9fJ26E-01
1.89G8E-21
2.&431E-01
9.t)762E-01
9.09G1E-01
2.G749E-09
2.7782E-16
SURFACE
SOIL CONC
CI/KG
O.OOOOEHOO
O.OOOOEHOO
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOEHOO
5.7360E-22
O.OOQOFiHOO
G.5882E-25
1.1M23E-3J
3.(..OG2E-15
O.OOOOE^O
O.OOOOK+00
O.OOOOEHOO
O.OOOOEiOO
O.OOOOE+00
[I.9S31E-12
G.7I371E-21
o.oooot+oo
1.7119L-27
2.2049E-12
2.2108E-12
O.OOOOE^OO
2.2108E-12
1.4784E-13
1.7634E-10
1.6449E-10
3.4709E-31
1.4735E-10
1.0064E-10
&.271It-10
4.5503E-19
4.72S9E-26
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEHOO
O.OOOOEhOO
O.OOOOE400
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
SURFACE
WATER CONC
CI/MAAH
o.oooomoo
O.OOOOE^O
O.OOOOE^O
O.OOOOE'iOO
O.OOOOE+00
O.OOOOEHOO
3.8240E-21
O.OOOOh'iOO
4.3921E-24
1.074'JK-30
1.0532E-14
O.OOOOE^OO
O.OOOOE+00
O.OOOOE+00
O.OOOOE^O
O.OOOOE^O
G.9532E--12
6.7871E-21
O.OOOOE-iOO
4.2798E-28
2.930I-JE-12
2.947GE-12
o.oooomoo
2.9478E-12
4.2240E-14
5.0382E-11
4.6997E-11
9.9169E-32
1.8418E-12
5.1611E-11
6.5888E-12
1.3789E-19
1.432111-26
3.69b8E-0&
G.4863E-10
7.7394E-07
7.2192E-07
1.522-/E-27
0.932GE-09
'/.92Q5E-07
3.1950E-08
2.2776L-15
2.3655E-22
SOLUBLE TO
STREAM
Cl
O.OOOOEiOO
O.OOOOLHOO
O.OOOOEKOO
O.OOOOL+00
O.OOOOE^O
O.OOOOK+00
1.2298E-16
O.OOOOE+00
1.4125E-19
3.4570E-26
3.3072E-10
O.OOOOEi-00
O.OOOOH+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
2.8794E-07
2.1828E-1G
O.OOOOEHOO
1.3764E-23
9.4549E-08
9.4804E-08
O.OOOOE+00
9.4804E-08
1.35CI5E-09
1.G203E-OG
1.511bE-06
3.1894E-27
5.9235E-08
1.G599E-06
2.1190E-07
4.434GE-15
4.6058E-22
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
SOLUBLE TG
DEEP LAYERS
Cl
O.OOOOFHOO
O.OOOOE+00
O.OOOOE^O
O.OOOOlfM-00
O.OOOOE+00
0.00001M-00
1.G493E-1G
O.OOOOH+00
1.8943E-19
4.6359L-2G
4.5424E-30
0.0000^00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEi-00
3.8614E-07
2.9272E-1G
O.OOOOEHOO
1.84&8E-23
1.2679E-07
1.2714E-07
O.OOOOEHOO
1.2714E-07
1.8218K-09
2.1729E-0&
2.0269E-OG
4.2770E-27
7.943GE-08
2.2259E-06
2.8417L-07
5.94G9E-15
6.1765E-22
ATMOSPHERE
AT SPILLAGE
U/MU3
O.OOOOEHOO
O.OOOOE+00
O.OOOOC+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOEHOO
5.8422E-28
O.OOOOE+00
&.7102E-31
1.&422E-37
3.7545E-21
O.OOOOE+00
O.OOOOLHOO
O.OOOOE+00
O.OOOOIMOO
O.OOOOE+00
9.1189E-18
&.-3127E-27
O.OOOOE+00
1.743GE-33
2.2457E-18
2.2518E-18
O.OOOOE+00
2.2518E-10
1.5058E-19
1.79GOE-1G
1.G754E-16
3.5352E-37
1.5007E-16
1.0398E-1G
5.3686E-1G
4.G345E-25
4.8134E-32
ATMOSPHERE
DOWN WIND
C1/MAA3
O.OOOOEHOO
O.OOOOE+00
O.OOOOEt-00
O.OOOOE+00
O.OOOOE+00
O.OOOOEHOO
3.0538E-39
O.OOOOE+00
3.5075E-42
8.?840E-49
].962bE-32
O.OOOOE+00
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
4.766GE-29
3.G134E-3B
O.OOOOE+00
9.1142E-45
1.1739E-29
1.1770E-29
O.OOOOE+00
1.1770E-29
7.8709E-31
9.3881E-28
8.7574E-2S
1.8479E-48
7.8447E-28
9.6171E-28
2.80G3E-27
2.422GE-3G
2.51G1E-43
UELL WATER
CONC
C17MAA3
1.3Q68E-33
2.4i!91-fE-ll
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
;i.OS21E-09
O.OOOOE+00
O.OOOOE+00
3.2433E-09
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
ANNUAL SUMMARY FOR YEAR 1000 OF THE SIMULATION
THE IkENCH CAP HAS HAD 30.00 PER CENT FAILURE
THE MAXIMUM POSSIBLE WATER DEPTH IN TRENCH DURING THE YEAR IS
2.2G11E-01 CUBIC METERS OF WATER LEFT BOTTOM OF TRENCH
O.OOOOE+00 CUBIC METERS OF WATER OVERFLOWED TRENCH
1.01E-01 METERS
NUCL1HE TRANSPORT INFORMATION
-------�
ro
NUCLIDE
H-3
C-14
CR-51
MN-54
FE-55
CO-58
NI-59
CO-GO
NI-G3
SR-90
NB-94
IC-99
RU-10G
SB-125
1-129
CS-134
CS-135
CS-137
CE-144
EU-154
U-234
U-235
NP-237
U-23Q
PU-23B
PU-239
PU-240
PU-241
AM-241
PU-242
AM-243
CM-243
CM-244
AMOUNT IN
TRENCH
CI
1.5G59E-29
7.7G33E-OS
O.OOOOE+00
O.OOOOE+00
O.OOOOEi-00
O.OOOOE+00
9.6394E-01
1.GG9C-.E-58
5.217GE-04
2.4109E-11
9.48B4E-01
3.081GE-02
O.OOOOEHOO
O.OOOOE+00
4.34i'8E-01
O.OOOOEvOO
9.8707E-01
7.4247E-11
O.OOOOEHOO
1.0b9GE--19
9.83G3E-01
O.tfMlE-Ol
5.9318E-01
9.8G41E-01
3.GGG5E-04
9.G122E-01
8.8971E-01
9.9bi!4E-24
2.18G6E-01
9 . tl'/35E-01
9.0109E-01
3.0538E-10
5.4025E-1B
TRENCH
OVERFLOW
CI
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEHOO
O.OOOOEfOO
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE^O
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOL'+OO
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOEKOO
O.OOOOEHOO
O.OOOOE^O
O.OOOOE+00
O.OOOOE+00
TRENCH
DRAINAGE
CI
1.5274E-31
7.5723E--07
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEHOO
1.8024E-05
U.4Cr/4E-G3
9.7562E-09
4.50(J1E-16
7.G11BE-06
].112'JE-04
O.OOOOE+00
O.OOOOEtOO
3.722GE-04
O.OOOOE+00
2.7729E-06
2.0858E-1G
O.OOOOE+00
7.4434E-2G
3.G840E-OG
3.6944E-06
3.1580E-04
3.G944K-06
2.9434E-10
7.71GGE-07
7.1425E-07
7.9897E-30
7.G804E-09
7.92G4E-07
3.1651E-08
2.G002E-1G
4.5999E-24
AMOUNT AT
WELL
CI
2.9781E-31
1.4652E-OG
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
2.3053E-04
O.OOOOEHOO
O.OOOOE+00
4.797GE-04
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOK+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOH+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
NUCLIDE
H-3
C-14
CR-51
MN-54
FE-55
CO-58
NI-59
CO-GO
NI-G3
SR-90
NB-94
TC-99
RU-106
SB-125
1-129
CS-134
CS-135
CS-137
CE-144
SURFACE
SOIL CONC
CI/Klj
O.OOOOE^O
O.OOOOE+00
O.OOOOE+00
O.OOOOFHOO
O.OOOOE+00
O.OOOOEHOO
2.G4G7E-23
O.OOOOE+00
1.4329E-26
6.G-J11E--34
9.70GOE-1G
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE-iOO
5.G05GE-12
4.2179E-22
O.OOOOEHOO
SURFACE
HATER CONC
C1/MAA3
O.OOOOE^O
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOEHOO
O.OOOOEHOO
1.7G45E-22
O.OOOOtl + 00
9.552Gt:-2d
4.4141E-33
2.7734E-15
O.OOOOE^OO
O.OOOOEHOO
O.OOOOEHOO
O.OOOOE+00
O.OOOOEHOO
5.G05GE-12
4.2179E-22
O.OOOOE^O
SOLUBLE TO
STREAM
CI
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOEHOO
5.G74GE-18
O.OOOOEHOO
3.0722E-21
1.419GE-2B
9.9195E-1]
O.OOOOE+00
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOEHOO
1.8020E-07
1.35G5E-17
O.OOOOEvOO
SOLUBLE TO
DEEP LAYERS
CI
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
o.oooomoo
7.G099E-1B
O.OOOOEHOO
4.11CJ'JE-21
1.9037E-28
1.19G1E- 10
O.OOOOEi-00
O.OOOOEHOO
O.OOOOE+00
O.OOOOG+00
O.OOOOE+00
2.417GE-07
K8191E-17
O.OOOOE^O
ATMOSPHERE
AT SPILLAGE
C1/MAA3
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOEHOO
O.OOOOEHOO
O.OOOOEHOO
2.G957E-29
O.OOOOEHOO
1.4594E-32
G.7437E-40
9.!dt!G5E-22
O.OOOOE+00
O.OOOOEHOO
O.OOOOEHOO
O.OOOOE^O
O.OOOOE+00
S.7094E-18
4.2'JGOE-28
O.OOOOE+00
ATMOSPHERE
IHJUN WIND
C17MAA3
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
1.4091E-40
O.OOOOEHOO
7.6286E-44
3.5250E-51
5.1G79E-33
O.OOOOE+00
O.OOOOEHOO
O.OOOOEHOO
O.OOOOE+00
O.OOOOE-iOO
2.tJt!44E-29
2.2456E-39
O.OOOOE+00
WELL WATER
CONC
U1/MAA3
1.8479E-3G
9.091GE-12
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
1.4304E-09
O.OOOOE+00
O.OOOOE+00
Vi.97G9E-09
O.OOOOE-»00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
-------�
EU-154
U-234
U-235
NP-237
U-23U
PU-238
PU-239
PU-240
PU-241
AM-241
PU-242
AM-243
CM-243
CM-244
1
CO
o
NUCL1DE
H-3
C-14
CR-51
MN-54
FE--55
CO-53
NI-59
CO-GO
NI-63
SR-90
NB-94
TC-99
RU-10G
SB-125
1-129
CS-134
CS-135
CS-137
CE-144
EU-154
U-234
U-235
NP-237
U-238
PU-238
PU-239
PU-240
PU-241
AM-241
PU-242
AM-243
CM-243
CM-244
1
NUCLIDE
H-3
C-14
CR-51
2.0042E-29
1.1013E-12
0.' OOOOE + 00
1.1849K-12
5.8G63E-14
1.5375E-10
1.4231E-30
1.5925K-33
1.2593E-10
l.b'/92L'-10
S.lt)9UE-10
4.50S8E-20
7.9712E-28
b.010iE-30 3.G114E-25 2.1G10K-25 2.0433E-35 3 .0670K-46 O.OOOOE+00
1.5751E-12 5.0G58E-08 G.7934E-08 1.2032E-18 G.2894E-30 O.OOOOE+00
l.b7'J'JK-12 5.0B10E-08 6.813tH'-08 3.20G8E-18 G.3084E-30 O.OOOOE+00
O.OOOOE+00 O.OOOOE+00 O.OOOOEnOO O.OOOOEi-00 0. OOOOEIOO O.OOOOE+00
1.5799E-12 5.0810E-08 G.8138E-08 1.20G8K-18 6.3084E-30 O.OOOOE+00
1.67G1E-14 5.3904E-10 7.2288E-10 5.9749E-20 3.1232E-31 O.OOOOE+00
4.392UK-11 1.4126E-06 3 .8946E-06 l.bGb9K-lt 0.1854E-28 O.OOOOE+00
4.0GG1E-11 1.3077E-OG 1.7537E--OG 3.4495E-1G 7.57G7E-28 O.OOOOE+00
4.bbOOE-34 3.4G33E-29 3.9624K~2'J 1.6220E-39 8.4784E-51 0. OOOOK+00
1.5741E-12 5.0G24E-08 G.7889E-08 1.2826E-1G G.7043E-28 O.OOOOE+00
4.bl20b'-ll 1.4511E-06 1.94GOK-OG 3.G004E-16 8.4077E-28 O.OOOOE+00
6.4873E-12 2.08G4E-07 2.7979E-07 5.2859E-1G 2.7G31E-27 O.OOOOE+00
3.3G54K--20 4.3U13E-16 5.8889K-1G 4.b892E-2G 2.3989E-37 O.OOOOE+00
2.4355E-28 7.7GU6E-24 1.0418E-23 8.1180E-34 4.2439E-45 O.OOOOE+00
AVERAGE CONCENTRATIONS OVER THE YEARS 1 TO 1000 OF THE SIMULATION
MAXIMUM ANNUAL CONCENTRATIONS
ATMOSPHERE DOWNWIND
AVERAGE
CI/MAA3
2.23G3K-29
3.8423E-29
1.0925E-29
(J.891BE-28
4.3020E-27
G.6G77E-29
2.7bl2E-2G
7.7770E-27
2.715GE-2G
2.1390E-2G
2.I3478E-2G
1.79G2E-27
1.1J84E-27
3.&G5GK- 27
K.i:-!21E-27
3.0741E-27
2.9344E-2G
2.2437E-2G
1J3401E-26
2.'J)OOh-26
2.9100E-26
1.3338E-2G
2.9100E-2G
2.8797E-2G
3.0584E-26
3.0528E-26
1.6843E-26
3.0447E-2G
3.0G04E-26
3.1880L-26
2.2912E-26
1.9112E-2G
MAXIMUM
CI/MAA3
2.20-OK-2G
3.7818E-2G
1.0924E-2G
7.G739E-25
3.187GE-24
6.G143E-26
1.0I09E-23
5.G5G2E-24
3.7973E-23
1.4183E-23
1.8444E-2J
1.7207E-24
9.5941E-25
2.9G27E-24
7.0714E-24
2.3496K-24
1.8613E-23
1.4734K-23
6.9273E-25
1.2232E-23
1.8582E-23
1.U582E-23
9.4132K-24
1.U582E-23
1.8531K-23
1.8G78Ei23
1.867GE-23
1.12G6E-23
1.8G75K-23
1.8G78E-23
1.8702E-23
1.4989E-23
1.2G72E ••'
-------�
MN-54
FE-5b
CO-58
NI-59
CO-GO
NI-GJ
SR-90
NB-94
TC-99
RU-10G
SB-1 2 j
1-129
CS-134
CS--135
CS-137
CE-144
EU-154
U-234
U~23b
NP-23?
U-230
PU-230
PU-239
PU-240
PU-241
AM-241
PU-242
AM-243
CM-24J
CM-244
4.CI072E-11
2.132GE-]0
2.U404E-12
1.G842E-09
3.l*bbbF'-10
1.4775C-09
2.G316E-09
1.G402E-09
9.lj6iilE-ll
5.5338E-11
1.9386E-10
4.3G90E-10
1.5231E-10
2.9309E-09
l.]U'J4k'-09
3.U2GOE-11
9.2239E-10
1.5994E-09
].b995t-09
&.G929E-10
1.5995E-09
1 .4460E-09
1.5452E-09
1.S421E-09
8.4319E-10
1.6014E-09
1.54G4E-09
] .7IH70E-09
1.1494E-09
9.b760F.-10
3.0420E-12
2.04i!L'F.-ll
1.6004E-13
9.9822E-10
3.0803K-11
4.622GE-10
5.4C74F.-10
2.9242E-10
1.32G1E-11
4.9940E-12
1.9306E-11
1.2379E-10
1.49HK-1]
1.69G7E-09
1.0047E-10
3.317GE-12
9.5043E-11
3.3139E-10
3.31G2K-10
5.7740E-11
3.31G2E-10
I.44t.6E-10
1.5644E-10
I.SIGUL'-IO
8.3628E-H
1 .G2/!'-'E-10
1.5G58E-10
1.777bE-10
1.14SOE-10
9.S134E-11
4.1S49E-11
2.1132E-10
2.5031E-12
1.6842E-09
3.0683E--10
1.477 IE -09
2.6293E-09
1.G402E-09
9. 963 IE- 11
5.399GE-11
1.9214E-10
4.3G90E-10
] .bOb'OE-10
2.9309E-09
1.1IJ84E-09
3.7066E-11
9.2097E-10
1.5994E-09
1.5995F-09
b.G92rJE-10
1.5995E-09
1.445GE-09
1.5452E-09
].b421E-09
8.4161E-10
1.6013F.-09
1.54G4E-09
1.7370H-09
1.14I35E-09
9.5G?.bE-10
4.2543B-12
2.1163E-11
2.503GIL'-13
9.9022E-10
3.94b2E-]l
4.G270E-10
b.5041F;-10
2.9242E-10
].32G1E-13
5.4470E-12
].9924E-11
1.2379E-10
1.5556E-U
1.G9G7E-09
1.0100H-IO
3.7114E-]2
9.3b"G3£-ll
3.3139E-10
3.31G2F.--10
b.7740L'-ll
3.31G2E-10
] .4481E--10
1.S644E-10
1.81G8L-10
8.4183E-11
1.G225E--10
l'.777bL-10
1.14131E-10
9.bG08E-ll
5.1950E-13
1.8004E-12
l."l'J45E-l6
2.6509E-11
7.3b50E-ll
&.4853E-10
1.I3721E-09
5.0510E-11
1.1309E-15
G.9229E-13
2.0765E-10
3.GG50E-11
2.S895E-09
3.6430E-30
G 4fi5bE~15
G.'2S15E-13
4.8084E-11
4.8107't-ll
9.6129K-14
4.8107E-H
4.S924E-lb
5'.3990E-l|b;
2'.G717E-14
b".3928E-.lb
3.3062E-14
6".46li2E-]3
5.1720E-13
1.7979E-12
1.9237E-13
1.19451- -10
2.G490E-11
7.3547E-U
b.4t!4Gb'-10
1.U7VJ1E--09
b. Ob] 8E~] 1
1.12G7E-15
C..9135E-33
2.07G5E-10
3.G583E-11
2.5895E-09
3.G425E-10
6.4540E-15
G.2500E-13
4.8084E-1]
4.8107E-11
9.6129E-14
4.8107E-U
4.8922E-15
5.38Gb'E-15
b 3990F-] "i
2.'84091]-15
2.G716E-I4
S.3920E-15
3.3062E-14
7.7GS2E-13
G.4b98E-13
4.4b28E-14
1.1235E-13
1.1769E-14
9.G039E-11
1.5905E-12
5.9134E-11
G.1436E-10
2.00B2E-11
1.5155E-H
2.9404E-14
1.24G1E-12
7.4754E-10
1.8849E-10
1.3317E-00
1.873bE-09
l.b5G5E-14
7.5018E-14
4.8084E-12
4.8107E-12
1.153GE-14
4.13107E-12
8.80G3E-lb
9.G958G-15
9.7182E-15
i3 . ti'
-------�
PU-238
PU-239
PU--240
PU-241
AM-24]
PU-242
AM-243
CM-243
Ch-244
O.OOOOE+00
o.oooomoo
O.OOOOE^O
O.OOOOKiOO
o.oooot+oo
O.OOOOE^O
O.OOOOK-lOO
O.OOOOEfOO
O.OOOOE+00
O.OOOOEfOO
O.OOOOt-iOO
O.OOOOE+00
O.OOOOEHOO
O.OOOOKiOO
O.OOOOE+00
O.OOOOE^O
O.OOOOEnOO
O.OOOOh+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
0.0000^00
O.OOOOE+00
O.OOOOE^O
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
0.00001-^00
O.OOOOE+00
O.OOOOE^O
o.oooomoo
O.OOOOEi-00
O.OOOOK+00
O.OOOOEfOO
O.OOOOE+00
O.OOOOEi-00
O.OOOOFHOO
O.OOOOE+00
O.OOOOfM-00
O.OOOOE+00
O.OOOOE+00
O.OOOOE-iOO
O.OOOOEi-00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
o.ooooi;+oo
O.OOOOE+00
O.OOOOK+00
O.OOOOE+00
o.ooootnoo
O.OOOOE^O
O.OOOOE+00
0.0000^00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOCt-00
O.OOOOK+00
o.ooooe+oo
O.OOOOE+00
o.ooooe^o
O.OOOOE+00
O.OOOOE-IOO
O.OOOOE^O
O.OOOOE+00
O.OOOOE+00
O.OOOOLiOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
o.oooot+oo
o.oooot+oo
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
co
i
CO
ro
NOTE:
1 NUCLIHE
H-3
C-14
CR-51
MN-54
FE-55
CO-58
NI-59
CO-GO
NI-63
SR-90
NB-94
TC-99
RU-10G
SB-125
1-129
CS-134
CS-135
CS-137
CE-144
EU-154
U-234
U-235
NP-237
U-230
PU-238
PU-239
PU-240
PU-241
AM-241
PU-242
AM-243
CM-243
CM-244
Q.P.E. - GENERAL BRCULATION EXPOSURE
M.I.F. - MAXIMUM INDIVIDUAL EXPOSURE
G.P.E. UILL BE USED TO CALCULATE HEALTH EFFECTS
1
NUCLIHE
H-3
C-14
CR-51
MN-54
FE-55
CO-58
NI-59
CO-GO
NI-63
SR-90
ANNUAL INTAKE
BY [NiJESXION
PCI/Y
3.1379E+00
2.2320E+03
1.5060E-12
1.7110E-10
2.1033E-09
3.3855E-11
2.9101E-Oti
4.1455E-09
1.GOG2E-08
2.2185E-OU
2.3975E-07
2.13WE + 03
2.38U5E--10
8.1205E-10
1.0007EV03
1.9104E-09
1.3147E-07
1.8998E-08
1.4939E-10
4.91G4E-09
9.8417E-09
2.1BB5E-09
9.B417E-09
5.4979E-09
&.906GE-09
6.3S48E-09
3.1987E-09
6.125GE-09
5.9114E-09
G.G780E-09
4.3733E-09
3.641GE-09
AGGREGATED VALUES OF RADIOACTIVITY:
PUMPED OUT PUMPED OUT
THE STREAM
O.OOOOKiOO
O.OOOOLNOO
O.OOOOEi-00
O.OOOOH-iOO
O.OOOOK-lOO
0.00001;-i-OO
O.OOOOK+00
O.OOOOE+00
ANNUAL INTAKE
BY INHALATION
PCI/Y
1.78'J1E-13
3.0738E-13
8.7397E-14
7.1135E-12
3.4416E-11
5.3341E-13
2.2010E-10
G.221GE-11
2.1724E-10
1.6952E-10
2.2783E-10
1.43G9K-11
9.1073E-12
3.0925E-11
G.4977E-11
2.4593E-11
2.3475E-10
1.7950E-10
G.364t)E-12
1.4721E-10
2.3280E-10
2.3280E-10
9.0706E-11
2.3280E-10
2.3038E-10
2.44G7E-10
2.4423E-10
1.3474E-10
2.4350K-10
2.4483E-10
2.5504E-10
1.8330E-10
1.5289E-10
THE WELL
1.GG8GE--OG
1.18G8E--03
O.OOOOE+00
O.OOOOEHOO
O.OOOOE^O
O.OOOOE+00
O.OOOOK+00
O.OOOOE+00
O.OOOOK+00
O.OOOOE^O
O.OOOOL'+OO
O.OOOOE+00
EFT BOTTOM
OF TRENCH
5.9941K-02
9.7463E-01
5.2354E-09
8.9245K-07
2.2170E-07
1.2574E-07
1.75GOK-02
8.G009E-05
1.9914E-03
4.2409E-04
OVERFLOWED
TKCNCH
O.OOOOK+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE^O
O.OOOOE^O
O.OOOOK+00
0. 000012 + 00
O.OOOOE+00
O.OOOOEi-00
RELEASED TO
THE ATMOSPHERE
1.3492E-07
2.3101E-07
G.5909E-08
5.3G4bE-06
2.5954E-OS
4.0227E-07
].6b99E-04
4.G919E-05
1.G384E-04
1.2784E-04
RELEASED TO
BASIN
2.4601E-03
9.G049E-01
5.7943E-08
9.4963E-06
2.4504E-06
1.3099E-06
4.1560E-03
5.6022E-04
3.3280E-03
1.8456E-03
-------�
NB-94
TC-99
RU-10G
1
CO
co
1-129
CS-134
CS-135
CS-137
CE-144
EU-154
U-234
U-235
NP-237
U-238
PU-23G
PU-239
PU-240
PU-241
Ah-241
PU-242
AM-243
CM-243
CM-244
O.OOOOE+00
1.13b5H- 03
O.OOOOE-iOO
O.OOOOE-iOO
5.3212E-04
O.OOOOE+00
O.OOOOE+00
O.OOOOE^O
O.OOOOE-iOO
O.OOOOE^O
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEKOO
O.OOOOE+00
O.OOOOEi-00
O.OOOOE-iOO
O.OOOOE+00
O.OOOOE+OO
O.OOOOE+00
O.OOOOE+00
O.OOOOE>00
O.OOOOE+00
O.OOOOE+00
O.OOOOK+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEi-00
o.oooon+oo
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOtMOO
O.OOOOEHOO
O.OOOOE-<00
O.OOOOE+00
O.OOOOE-iOO
O.OOOOE+00
O.OOOOE-iOO
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
o.oooot+oo
7.4712E-03
9.5013E-01
8.3905E-07
3.1023E-05
5.55G1E-01
7.7982E-07
2.6701E-03
G.7792E-05
1.00G9K-07
7.1781E-OG
3.5535E-03
3.5537E-03
3.964GE-0)
3.5587E-03
8.1138K-05
7.5258E-04
7.2335E-04
l!&7)7E-05
7.G30'JE-04
3.1B54E-05
2.2307E--05
9.rJ484E-06
FRACTION OF
NUCI.IDE
H--3
C-14
CR-51
hN-54
FE-55
CO-58
NI-59
CO-GO
NI-G3
SR-90
NB-94
TC-99
RU-IOG
SB-125
1-129
CS-134
CS-135
CS-137
CE-144
EU-154
U-234
U-235
NP-237
U-238
PU-238
PU-239
PU-240
PU-241
AM-241
PU-242
AM-243
CM-243
CM-244
MAXIMUM
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE-iOO
O.OOOOE-iOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
INGEST ION DUE TO
FRACTION
1.0000
1.0000
0.0000
0.0000
0.0000
0.0000
0.0000
0.0000
0.0000
0.0000
0.0000
1.0000
0.0000
0.0000
1.0000
0.0000
0.0000
0.0000
0.0000
0.0000
0.0000
0.0000
0.0000
0.0000
0.0000
0.0000
0.0000
0.0000
0.0000
0.0000
0.0000
0.0000
0.0000
ANNUAL EXPOSURE
1.7103E-04
1.0836E-05
G.8601E-OG
2.3321E-05
4.9001E-05
1.854GE-05
J.7707E-04
I.U537E-04
4.7999E-06
1.1L02E-04
1.7559E-04
1.7559E-04
G.EI405E-05
1.7559E-04
1.7376E-04
1.8455E--04
J.U421E-04
1.01G2E-04
1.&372E-04
1.U4GGE-04
1.923GE-04
1.3ti24E-04
1.1531E-04
WATER
4.1431E-03
5.2446E-01
9.0382E-OG
2.3476E-04
4.0810E-02
8.5406E-OG
4.1125E-03
I5.G075E-04
1.1240E-06
7.3340E-05
4.1419E-03
4.1439E-03
4.1S96E-03
4.1439E-03
5.996711-04
3.0277E-03
X938GE-03
6.4080E-05
1.2274E-04
3.0596E-03
P.25G6E-04
2.0718E-04
1.0014E-04
NUCLIDE
A IK
CONCENTRATION
YEAH
SURFACE
CONCENTRATION
YEAR
INGEST 1DN
RATV:
YEAR
INHALATION
RATE
YEAR
-------�
CI/MAA3
C1/MAA2
PERSON. I'll/Y
PL'RSUN.PCl/Y
CO
-fi
H-J
C-14
CR-51
MN-54
FE-55
CO-58
NI--b9
CO-60
NI-63
SR-90
NB-94
TC-99
RU-10G
SB -125
1-129
CS-1J4
CS-135
CS-137
CE-144
EU-154
U-234
U-2:35
NP-23?
U-23G
PU-238
PU-239
PU-240
PU-241
AM-241
PU-242
AM-243
CM-24J
CM-244
1DARIAB
TABLES
2.2031E-2G
3.7818K-2G
1.0924E-2G
7.67iltJK-2&
3.1I376E-24
G.G143t'--2&
l.l)109E--23
5.G5G2E-24
1.797311-23
1.41U3E-23
1.8444E--23
1.7-.J07E-24
9.5'J4iE-2b
2.%27E-24
7.0714E-24
2.349GE-24
1.0Gm:-23
1.4734E-23
G.9273E-25
1 .2232E-23
1.8bU2K-23
1.8b82E-23
9.4132K-24
1.8582E-23
].8b31E-23
1.D6713E-23
1.8G76E-23
1.126GE-23
1.8G7bE--23
1.UG78E-23
1.8702E-23
1.4-J89E-23
1.2G72E-23
INFO
FOR THE SELLCTED IND
O.OOOOG-iOO
O.OOOOE-iOO
3.6U33E-24
1.0726E-18
5".91G3E-21
1.7119E-17
9283E-17
5.U219E--17
6.7357E-17
2.1207E -18
1.5143E-18
7.1GbOE-10
1.7979E-17
5.2915E-L8
8.9723K-17
G.23G4E-17
8.96b4E-19
4.8154E-17
8.92G8E-17
8.9271E-17
2.6881E-17
B.9271E-17
8.4738E-17
9.0754E-17
4.3137E-17
B.9517E-17
9.0795E--17
9.133GE-17
G.4005E -17
5.0465K-17
0
0
1
•2
7
2
5
4
8
1
1
1
I
11
4
1
3
10
10
2
10
6
.15
14
3
9
16
500
4
3
7.9UG31M03
6.477'JK+OS
3.7649E-08
3.GGlibE-OG
3.0923E--05
8.3%1E-07
1.J7G1K-04
7.4507K-0&
1.3648H-04
0.5785E-05
2.016311-03
5.0160K-OG
1.51G3E-05
2.2316H+0&
3.5951G-05
2.3164K-04
3.2507C-OG
9.5270E-OS
9.5270E-05
9.5?.70L'-Ob
U.9049E-05
8.90b2E--05
S.3473E--05
U.9052E--05
7.'l405E-05
G.034GE-Ob
70
70
1
I
1
1
1
1
204
1
1
298
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
I
4.40G2E-09
7.5637E-09
2.1048E-09
l.b34tlE-07
G.3752E-07
].322CJE-08
3.G217E -06
1.KU2E-06
3.5fJ4GE-06
2.8366E-06
3.6880E-06
3.4413E-07
1.91B8E-07
5.9254E--07
1.4143E-06
4.G992E-07
3.722SE-06
2.94G9E-06
1.3U55E-07
2.4463E-06
3.7164E-OG
3.71G5E-OG
1.B026E-OG
3.7165E-06
3.70G2E-OG
J.7355E-OG
3.7352E-06
2.2531E-OG
3.7350E-06
3.73b6E-OG
3.7403E-OG
2.9977E-OG
2.5344E-06
SELECTED INDIVIDUAL WILL BE DONE FOR THE LOCATION HAVING 100.00 I OF THE HIGHEST TOTAL RISK.
DOSE RATE TABLES COMBINING LOW AND HIGH LET WILL BE PRINTED.
HEALTH RISK TABLES COMBINING LOW AND HIGH LET WILL BE PRINTED.
00 INDICATES THE TABLE WILL NOT BE PRINTED
1 INDICATES INDIVIDUAL VALUES WILL BE PRINTED
2 INDICATES MEAN INDIVIDUAL VALUES WILL BE PRINTED
3 INDICATES COLLECTIVE VALUES WILL BE PRINTED
4 INDICATES ALL OF THE ABOVE WILL BE PRINTED
QUANIIIY
TABLE NO. 1 2 3 4 5 6 7
2.HEALTH RISKS 0000033
3.RISK EQUIVALENT FACTOR 0000000
OTHE GROUND SURFACE CORRECTION FACTOR IS 0.50
OTHERE ARE 11 ORGANS TO BE OUTPUT. THEY ARE:
ORGAN TIME ORGAN TIME ORGAN
R MAR 70. ENDOS1 70. THYROID
BREAST 70. Af'ULA 70. S WALL
INT WALL 70. LIVER 70. PANCREAS
KIDNEYS 70. OTHER 70.
0 ORGAN HOSE EQUIVALENT FACTORS
LOW LET HIGH LET
R MAR 1.00000 20.0000
ENDOSI 1.00000 20.0000
TIME
70.
70.
70.
-------�
.00000
.00000
.00000
.00000
.00000
.00000
.00000
.00000
20,
20
20,
20,
20.
20.
20,
20,
1.00000 20,
11 CANCERS TO BE OUTPUT,
0000
0000
0000
0000
0000
0000
0000
0000
0000
-m. A 2
CANCER
THYROID
BOWEL
OTHER
IS RELATIVE RISK.
CANCER
BREAST 1.
LIVER 1.
THYROID
BREAST
APULA
S WALL
INT WALL
LIVER
PANCREAS
KIDNEYS
OTHER
OTHERE ARE
A 1 INDICATES ABSOLUTE RISK
CANCIR CANCER
LEUKEMIA 1. BONE 1.
LUNG 1. STOMACH 1.
PANCREAS 1. URINARY 1.
OGENET1C DOSES ARE PRINTED FOR TES1ES
THE RISK FACTOR (PER RAD/MILLION BIRTH
260.00000 FOR LOU LET. AND
5200.0000 FOR HIGH LET.
AND IHK REPLACEMENT RATE FOR THE BRCULATION
.14133E-01 YEAR-1
OIHERE ARE 33 RADIONUCLIDES TO BE OUTPUT.
NUCL1UE PARTICLE SIZE CLEARANCE CLASS
A
A
U
W
W
Y
U
Y
10
D
Y
W
Y
W
Li
H
D
D
Y
U
U
Y
Y
W
Y
Y
Y
Y
W
Y
U
U
M
OVARIES AVERAGE
) FOR GENETIC DOSE ARE :
IS
CO
1
CO
en
H-3
C-14
CR-51
MN-54
FE-55
CO-50
NI-59
CO-GO
NI-CJ
SR-90
NB-94
IC-99
RU-10C
SB-125
1-129
CS-134
CS-135
CS-137
CE-144
EU-154
U-2:34
U-235
NP-2.37
U-238
PU-23S
PU-239
PU-240
PU-241
AM-241
PU-242
AM-243
CM-243
CM-244
OORGAN DOSE
ORGAN
R MAR
•f
ENDOST
0.00000
0.00000
1.00000
1.00000
1.00000
1.00000
1.00000
1.00000
1.00000
1.00000
1.00000
1.00000
1.00000
1.00000
1.00000
1.00000
1.00000
1.00000
1.00000
1.00000
I. 00000
] .00000
1.00000
1.00000
1.00000
1.00000
] .00000
1.00000
] .00000
1.00000
1.00000
1.00000
1.00000
WEIGHTING
FACTORS
0.15520
0.00350
FACTORS
PATHWAYS
1234
STOMACH
0.00000
.00000
.00000
.00000
.00000
0.00000
0.00000
.00000
.00000
.00000
.00000
.00000
.00000
.00000
.00000
0.00000
0.00000
0.00000
.00000
.00000
.00000
.00000
.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.
0.
0.
0.
G.I. ABSORPTION
SE
0.95000
0.95000
0.10000
0.10000
0.10000
0.05000
0.05000
0.05000
0.05000
0.01000
0.01000
0.00000
0.05000
0.20000
0.95000
0.95000
0.95000
0.00030
0.00010
0.20000
0.00200
O.OOiiOO
0.00100
0.00200
0.00100
0.00010
0.00010
0.00100
0.00100
0.00010
0.00100
0.00100
0.00100
FRACTION
ULl
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
LLI
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
0.00000
o.ooooo
0.00000
0.00000
0.00000
0.00000
0.00000
-------�
f
+
t
+
+
>
t
+
+
+
THYftOIO
BREAD!
APULA
S WALL
INI WALL
LIVER
PANCREAS
KIDNEYS
OTHER
0
0
0
0
0
0
0
0
0
.09870
.12990
.20750
.08400
.03900
.08530
.05850
.02480
.11360
1
]
j
1
1
1
1
1
1
1
2
'r
2
2
2
2
2
2
2
2
3
3
3
3
3
3
3
3
3
3
4
4
4
4
4
4
4
4
4
4
1IHE LOCATION USED FOR THE SELECTED INDIVIDUAL EXPOSURE IS
THE FATAL CANCER RISK AT THAT LOCATION IS 0.463E-04
1
17700 METERS N FROM THE SOURCE.
CO
I
DARTAB INFO
ORGAN DOSE/EXPOSURE SUMMARY
OAAA COLLECTIVE BRCULATION AAA
ODOSE RATE:
ORGANS: R MAR ENDOST THYROID BREAST APULA S WALL INT WALL LIVER PANCREAS KIDNEYS
OTHER WT.SUH
LOW LET (PERSON RAD/Y) 2.207E-04 4.215E-04 0.217 1.494E-04 7.682E-05 7.520E-04 2.028E-04 9.690E-05 8.5G7E-05 8.403E-05
B.5G7E-05 2.1G2E-02
HIGH LEI (PERSON RAD/Y) 1.570E-12 1.941E-11 2.413E-14 2.413E-14 1.772E-12 2.443E-14 3.392E-14 3.950E-12 2.413E-14 3.091E-14
2.413E-14 1.030E-12
DOGE EU. (PERSON REM/Y) 2.207E-04 4.215E-04 0.217
8.567E-05 2.1G2E-02
OGONAOAL DOSES:
GONADS: TESTES OVARIES AVERAGE
LOW LET (PERSON RAD) 1.938E-03 1.973E-03 1.955E-03
HIGH LET (PERSON RAD) 1.807E-12 1.809E-12 1.808E-12
DOSE EU. (PERSON REM) 1.938E-03 1.973E-03 1.955E-03
1
1.494E-04 7.G82E-05 7.520E-04 2.028E-04 9.690E-05 8.5G7E-05 8.403E-05
DARTAB INFO
PATHWAY
OAAA COLLECTIVE BRCULATION AAA
ODOSE RATES:
WEIGHTED SUMS OF ORGAN DOSE RATES
PATHWAYS: INGESIION
DOSE/EXPOSURE SUMMARY
LOW LIT (PERSON RAD/Y) 2.1G2E-02 2.
HIGH LEI (PERSON RAD/Y) 1.103E-13 9.
DOSE EU. (PERSON REM/Y) 2.162E-02 1.
OAVERAGE GONADAL DOSES:
PATHWAYS: INQESTION
LOU LEI (PERSON RAD)
HIGH LET (PERSON RAD)
INHALATION AIR GROUND INTERNAL EXTERNAL TOTAL
IMMERSION SURFACE
543E-14 1.192E-17 S.SG1E-11 2.1G2E-02 8.8G1E-11 2.162E-02
198E-13 O.OOOE+00 O.OOOE+00 1.030E-12 O.OOOE+00 1.030E-12
842E-11 1.192E-17 8.8G1E-11 2.162E-02 8.8G1E-11 2.1G2E-02
INHALATION AIR GROUND INTERNAL EXTERNAL TOTAL
IMMERSION SURFACE
1.955E-03 4.642E-14 3.954E-16 2.933E-0'J 1.955E-03 2.933E-09 1.955E-03
3.22GE-13 1.485E-12 O.OOOE+00 O.OOOE+00 1.808E-12 O.OOOE+00 1.S08E-12
-------�
DOSE EQ. (PERSON REM)
1
1.955E-03 2.975E-11 3.954E-1G 2.933E-09 1.955E-03 2.933E-09 1.955E-03
DARTAB INFO
NUCL1DE DOGE/EXPOSURE SUMMARY
CD
OAAA COLLECTIVE BRCULAT10N AAA
OBOSE RATES:
UEIQHltD SUMS OF ORGAN DOSE RATES
NUCL1DES: H-3
NB-94
U-234
AM-243
LOU LL1 (PERSON RAL/Y) G.755E-09 0,
G.767E-11
4.334K-14
5.848E-12
HIGH I.E1 (PERSON RAD/Y) O.OOOE+00 0,
O.OOOE+00
5.974K-15
1.698E-13
DOSE EU. (PERSON REM/Y) G.755L-09 8
6.767E-11
1.628E-13
9.243E-12
OAVERAGE GONADAL DOSES:
NUCL1DES:
LOW LEI (PERSON RAD)
HIGH LEI (PERCON RAD)
DOSE EU. (PERSON REM)
H-3
NB-CJ4
U-234
AM-243
1.952E-0?
2.258E-09
9.148E-13
1.946E-10
O.OOOE+00
O.OOOK+00
4.74GE-1G
4.199E-13
1.952E-07
2.258E-09
9.243E-13
2.030E-10
C-14
TC-99
U-23S
CM-243
.5fJ5t-05 3.
1.023E-04
1.082E-11
5.023E-13
.OOOE+00 0.
O.OOOE+00
5.244E-14
7.330E-14
.595E-Ob 3,
1.023F-04
1.187E-11
1.9G8E-12
C-14
1C;-99
U-235
CM-243
1.2211-03
3.699E-04
3.404E-10
1.589E-11
O.OOOE-iOO
O.OOOE+00
1.B67E-1G
2.600E-13
1.221E-03
3.6CJCJE-04
3.404E-10
2.109E-11
CR-51
fiU-106
Np-2-iy
CM-244
320E-21 2.
3.472E-16
1.024E-14
1.14GE-15
OOOE+00 0,
O.OOOE+00
4.792E-14
4.750E-14
320E-21 2,
3.472E-1G
9.G8GE-13
9.52SE-13
MN-54
•30-125
U-238
TOTAL
093E-15 3,
1.944E-14
3.&35E-14
2.162E-02
OOOE+00 0,
O.OOOE+00
5.2GGE-15
1.030E-12
093E-15 3,
1.944E-14
1.407E-13
2.1G2E-02
EE-b5 C0-b8 Nl-59 CO-GO N1-G3 SK-90
1-129 C3-134 CS-13S CS-137 Cli-144 EU-154
PU-Siifi PU-239 PU-240 PU-241 AM-24] f'U-242
622E-17 7.922E-18 7.390E-15 4.007E-13 1.720E-16 3.947E-15
2.143E-02 4.544E-14 2.144E-14 1.3G4E-16 1.914E-16 1.748E-12
8.G26E-15 2.888E-14 5.853E-14 5.660E-17 1.353E-12 5.114E-14
OOOE+00 O.OOOE+00 O.OOOE+00 O.OOOE+00 O.OOOE+00 O.OOOE+00
O.OOOE+00 O.OOOE + 00 O.OOOE + 00 O.OOOE^O O.OOOOOO O.OOOE+00
1.227E-13 1.1G6E-13 1.1G4E-13 1.036E-15 1.603E-13 1.107E-13
622E-17 7.922E-18 7.390E-1& 4.007E-13 1.720E-1G 3.947E-15
2.143E-02 4.5)44E-14 2.144E-14 1.364K-16 1.914E-16 1.748E-12
2.4G3E-12 2.3G1E-12 2.387E-12 2.077E-14 4.560E-12 2.2G5E-12
CR-51 MN-b4 FE-&5 C(J~5£J Nl-59
RU-106 SH-125 1-129 CS-134 Cb-13b
NP-237 U-2313 PU-238 PU-239 PU-240
CM-244 1'OIAL
1.07GE-19 6.982E-14 6.849E-1G 2.801E-1G 8.154E-14
1.055E-15 6.44GE-13 3.G41E-04 1.496E-12 6.716E-13
2.560E-13 7.049E-13 1.729E-13 G.42GE-13 1.209E-12
2.402E-14 1.955E-03
O.OOOE+00 O.OOOE+00 O.OOOE+00 O.OOOE+00 O.OOOE+00
O.OOOE+00 O.OOOE+00 O.OOOE+00 O.OOOE+00 O.OOOE+00
5.717E-14 4.329E-1G 1.522E-13 1.0G7E-13 1.071E-13
1.923E-13 1.808E-12
1.07GE-19 G.982E-14 G.e49E-16 2.801t-lG 8.154E-14
1.055E-15 G.446E-13 3.G41E-04 1.49GE-12 6.716E-13
1.400E-12 7.136E-13 3.218E-12 2.777E-12 3.351E-12
3.870E-12 1.955E-03
CO-GO Nl-63 Sk-90
CS-137 CE-144 t'U-]54
PU-241 AM-241 PU-242
1.323E-11 3.455E-15 3.930E-15
3.859E-15 1.250E-15 5.790E-11
G.604E-17 4.5G3E-11 1.059E-12
O.OOOE+00 O.OOOE+00 O.OOOE+00
O.OOOE+00 O.OOOE+00 O.OOOE+00
1.208E-15 4.087E-1J 1.013E-13
1.323E-11 3.455E-15 3.930E-15
3.859E-15 1.258E-15 5.790E-11
2.423E-14 5.380E-11 3.084E-12
DARTAB INFO
RISK/RISK EQUIVALENT SUMMARY
STOMACH BOWEL
LIVER
PANCREAS URINARY
COLLECTIVE BRCULAIION AAA
OCOLLEC1IVE FATAL CANCER RISK:
CANCERS: LEUKEMIA BONE THYROID BREAST LUNG
OTHER TOTAL
LOU LEKDEATHS/YR) 9.5931-09 4.096E-10 6.082E-07 5.436E-09 4.4G7E-09 1.771E-08 2.219E-09 2.319E-09 1.410E-09 5.844E-10
2.737E-09 G.551E-07
HIGH LLKDEATHS/YR)
2.857E-16 1.847E-1G 2.532E-18 2.615E-18 7.794E-1G 1.7GOE-18 1.G49E-18 3.235E-16 1.135E-18 8.411E-19
2.294^-18 1.50GE-15
9.b93E-09 4.096E-10 6.082E-07 5.436E-09 4.4G7E-09 1.771E-08 2.219E-09 2.319E-09 1.410E-09 5.844E-10
2.7J7G--09 G.551E-07
OFATAL CANCER RISK EQUIVALENT:
TOTAL (DEAIHS/YR)
-------�
CANCERS:
SlOhACH BOWEL
LIVER
PANCREAS URINARY
(PERSON REM/YR)
OUHOLE BODY FATAL CANCER RISK
OGENEIIC RISKS:
LOU LLKEFFECTG/YR) 7,
HIGH LEKEFFECTS/YR) 1,
COMBINED(EEFECTS/YR) 7,
OGENETIC RISK EQUIVALENT:
(PERSON REM/YR) 6.51SE-05
1
LEUKLMIA BONE THYROID BREAST LUNG
OTHER TOTAL
2.203L-04 4.212E-04 2.196E-02 1.492E-04 7.676E-05 7.515E-04 2.026E-04 9.G90E-05 8.590E-05 8.394E-05
8.590E-05 2.335E-03
ECHPERSON REM/YR)
185E-09
328E-16
185E-09
2.335E-03
DARTAB INFO
PATHWAY RISK/RISK EQUIVALENT SUMMARY
OAAA COLLECTIVE BRCULATION AAA
OCOLLECIIVE FATAL CANCER RISK:
PATHWAYS: 1NGESTION
LOW LLKDEATHS/YR) G.551E--07
HIGH LEHDEATHS/YR) 1.399E-16
TOTAL (HEATHS/YR) G.b51t-07
oo OFATAL CANCER RISK EQUIVALENT:
PATHWAYS: INCEPTION
CO
oo
(PERSON REM/YR) 2.335E-03
WHOLE BODY RISK EG (PERSON REM/YR)
OGENETIC RISKS
HIGH LLT(EFtECTG/YR>
CO«BINED(EFFECTS/YR)
OGENETIC RISK EQUIVALENT:
(PERSON REM/YR)
1
IMMERSJ10N SURFACE
7.185E-09 1.706E-19 1.453E-21 1.070E-14 7.1i35E-0'3 1.071JE-14 7.185E-09
2.371E--17 1.091E-16 O.OOOE+00 O.OOOE+00 1.328E-16 O.OOOE+00 1.328E-16
7.10bt-09 1.093E-16 1.453E-21 1.078E-14 7.185E-09 1.07BE-14 7.185E-09
G.bltlE-Oti 9.916E-13 1.310E-17 9.775E-11 6.510E-05 9.775E-11 6.518E-05
DARIAB INFO
NUCLIDE RISK/RISK EQUIVALENT SUMMARY
OAAA COLLECTIVE BRCULATION AAA
OCOLLECT1VE FATAL CANCER RISK:
NUCL1HES: H-3
NB-94
U-234
LOW LEKBEATHGi/YR)
HIGH LEKDEAIHS/YR)
TOTAL (DtATHS/YR)
C--14 CR-51 MN-54
TC-99 RU- 106 SB-125
U-235 Nf-237 U-23U
CM-24ii CM-244 TOTAL
1.896t-12 2.411E-08 9.318E-25 5.375E-19 9
1.899E-14 2.869E-08 9.574E-20 5.455E-18
1.216K-17 3.037E-15 2.642L-18 9.889E-18
1.639E-15 1.407E-16 3.143C-19 G.551E-07
O.OOOEHOO O.OOOE+00 O.OOOE+00 O.OOOL+00 0
O.OOOE+00 O.OOOE+00 O.OOOE+00 O.OOOE+00
1.33'JL-l? 1.114E-16 7.525E-17 1.180E-17
2.069E-16 1.137E-1& 0.119E-17 1.586E-15
1.89GE-12 2.411E-08 9.318E-25 5.075E-19 9
FE-55
1-129
PU-230
CO-58
CS-134
PU -2:39
NI-59
Cti-135
PU-240
CO-GO
CS-137
PU-241
Nl-63
Cf-144
AM-241
.692E-21 2.223E-21
G.023E-07 1.275E-17
2.399E-18 8.090E-13
.OOOE+00 O.OOOE+00
O.OOOE+00 O.OOOE+00
2.0GOE-16 1.922E-16
SR-90
EU-154
PU.-242
2.070E-18 1.124E-1G 4.426L-20 1.010E-18
5.935E-18 3.808E-20 5.304C-20 4.90GE-16
1.G40E-17 1.240E-20 3.794E-16 1.433t-17
O.OOOE+00 O.OOOE+00 O.OOOE+00 O.OOOE+00
O.OOOE^O O.OOOE+00 O.OOOE + 00 O.OOOE + 00
1.920E-1G 9.548E-19 1.989E-1G 1.025E-16
.692E-2I 2.223E-21 2.070E-18 1.124E-16 4.426E-20 1.010E-18
-------�
1.899E-14
2. 5551,'--17
2.869E-08 9.574E-20 5.455E-18
3.149E-15 7.790E-17 2.169E-17
TOTAL FATAL CANCER RISK FROM ALL EXPOSURES
OFAIAL CANCER RISK EQUIVALENT:
1.846E-15 2.544E-1G 8.150E-17 G.551E-07
023E-07
084E-1G
1.275E-17 5.985E-18 3.808E-20
2.003E-16 2.084E-16 9.672E-19
5.304E-20 4.906E-1G
5.783E-1& 1.968E-16
G.551E-07
NUCL1DES:
(PERSON REM/YR)
H-3
NB-94
U-234
Ah-243
C-14
TC-99
U-235
CM-243
CR-51
RU-10G
NP--237
CM-244
FE-55
1-129
PU-238
CO-58
CS-134
PU-239
Nl-59
CS-135
PU-240
CO-GO
CS-137
PU-241
OGENEIIC RISKS:
MN--54
SH-125
U-238
_____ _.._.. TOTAL
&.759E-09 8.594E-05 3.321E-21 2.094E-15 3.455E-17 7.925E-18 7.379E-15 4.008E-13 1
G.770E-11 1.023E-04 3.413E-16 1.945E-14 2.147E-03 4.545E-14 2.133E-14 1.357E-1G
1.377K-13 1.122E-11 2.777E-13 1.190E-13 7.427E-13 7.140E-13 7.428E-13 3.448E-15
G.581E-12 9.070E-13 2.905E-13 2.335E-03
NI-G3 SR-90
CE-144 EU-154
AM-241 PU-242
.578E-16 3.600E-15
l.tWE-16 1.749E-12
2.061E-12 7.016E-13
NUCL1DES:
LOU LEKEFFECTS/YR)
HIGH LLKEFFECTS/YR)
COMBINED(EFEECIG/YR)
03
I
CO
OGENETIC
(PERSON
RISK EQUIVALENT:
REM/YR)
H-3 C-14 CR-51 MN-54 FE-55 CO-SB NI-59 CO-GO
NB-94 TC-99 RU-10C, [ifc-125 1-129 CS-134 CS-135 CS-137
U-234 U-235 NP-237 U-238 PU-2U8 PU--239 PU-240 PU-241
AM-243 CM-243 CM-244 TOTAL
7.173E-13 4.487E-09 3.953t-25 2.566E-19 2.517E-21 1.029E-21 2.996E-19 4.8G1E-17 1
8.299E-15 1.359E-09 3.877E-21 2.369E-18 1.338E-09 5.495E-18 2.4G8E-18 1.418E-20
3.3G1L-18 1.251E-15 9.400E-19 2.590E-18 6.353E-19 2.361E-18 4.443E-18 2.427E-22
7.152E-1G 5.840E-17 8.U2GE-20 7.185E-09
O.OOOE+00 O.OOOL-iOO O.OOOE+00 O.OOOE+00 O.OOOE+00 O.OOOE+00 O.OOOE+00 O.OOOE+00 0
O.OOOE+00 O.OOOE+00 O.OOOE+00 O.OOOE+00 O.OOOEnOO O.OOOE+00 O.OOOE+00 O.OOOE+00
3.488E-20 1.372E-20 4.202E-18 3.182E-20 1.11CJL-17 7.841E-18 7.871E-18 8.878E-20
3.00GE-17 1.91LE-17 1.413E-17 1.328E-1G
7.I73E-13 4.4B7E-09 3.953E-25 2.5G6E-19 2.&17E-21 1.029E-21 2.99GE-19 4.8G1E-17 1
8.2'J'JH-15 1.359E-09 3.877E-21 2.3G9E-18 1.338E-09 5.495E-18 2.4G8E-18 1.418E-20
3.39GE-18 1.251E-15 5.143E-18 2.G22E-10 1.182E-17 1.020E-17 1.231E-17 8.902E-20
7.4G1E-16 7.'/51E-]7 1.422B--17 7.1B5E-09
NI-63 SR-90
CE-144 EU-154
AM-241 PU-242
.269E-20 1.444E-20
4.G22E-21 2.128E-1G
1.677E-16 3.892E-18
.OOOE+00 O.OOOE+00
O.OOOE+00 O.OOOE+00
3.003E-17 7.441E-18
.269E-20 1.444E-20
4.G22E-21 2.128E-16
1.977E-1G 1.133E-17
G.507E-09 4.071E-05 3.50GE-21 2.327E-15 2.283E-17 9.336E-18 2.718E-15 4.410E-13 1.152E-16 1.310E-1G
~ " 1.214E-05 4.9Q5E-14 2.239E-14 1.286E-1G 4.193E-17 1.930E-12
1.073E-13 9.255E-14 1.117E-13 8.075E-16 1.793E-12 1.028E-13
7.528E-11 1.233E-05 3.517E-17 2.149E-14
3.0C1E-14 1.135E-11 4.GG5E-14 2.379E-14
G.7G8E-12 7.031E-13 1.290E-13 G.518E-05
DARIAB INFO
COLLECTIVE DOSE EQ. (PERSON RE« /YEAR)
OAAASUMMED OVER ALL ORGAN
NUCLIHIIS
INGEST1UN
•/. Of INTERNAL
OF ALL PATHWAYS
INHALATION
I OF INTERNAL
H-3
NB-94
U-234
AM-243
G.755E-09
1.G31L-14
2.074E-15
5.80rJE-13
100.
83.1
1.74
17.1
100.
2.411E-02
1.27
6.28
C-14
TC-99
U-2HS
CM-243
8.595E-05
1.023E-04
2.11GE-15
2.243E-13
100.
100.
0.201
15.3
100.
100.
1.7B2E-02
11.4
CR-51
RU-.LOG
NP-237
CM-244
1.950E-21
G.G99E-17
1.723E-13
1.421E-13
G2.0
VJ.'d
17.9
14.9
5B.7
l'j.3
17.0
14.-J
MN-54 FE-55
SC-125 1-129
U-238 PU-23U
TOTAL
6.850E-18 2.488E-17 B
O.OOOE+00 2.143E-02
1.945E-15 3.9GGE-13
2.1G2E-02
9:3.9
JOO.
CO-58 NI-59 CO-GO Nl-63 SR-90
CS-134 Cli-135 CS-1J7 CE-144 EU-15'
PU-239 PU-240 PU-241 AM-241 PU-24;
.835E-19 1.087E-16 5.98GE-1G 1.482E-16 3.117E-)
3.156E-15 2.142E-14 O.OOOE+00 O.OOOE+00 O.OOOE^
5.070E-14 5.443E-14 &.043E-15 5.282E-13 4.G19E-
76. &
O.OOOE+00
1.U3
100.
0.327
O.OOOG+00
1.38
100.
1G.2
G8.7
100.
16.1
73.1
99.]
2.17
11.2
G.95
2.15
91.9 49.0 8G.2 79.0
99.9 O.OOOEHOO O.OOOE+00 O.OOOE^
2.34 29.1 16.5 2.18
1.47 0.149 06.2 79.0
99.9 O.OOOE+00 O.OOOE+00 O.OOOEJ
2.20 29.1 11.2.13
5.561L-22 8.3G3E-23 1.195E-21 2.09CE-18 1.623E-18 3.24GE-19 9.592E-18 G.218E-16 2.382E-17 8.298E-]
3.320E-15 7.837E-18 2.802E-1G 2.147E-17 9.251E-1G 2.74GE-17 2.6G2E-17 1.3G4E-1G 1.531E-16 1.238E-
1.174E-13 1.049E-12 7.884E-13 1.043E-13 2.058E-12 2.281E-12 2.275E-12 1.473E-14 2.680E-12 2.1G6E-
2.825E-12 1.244E-12 8.097E-13 1.842E-11
8.232E-12 9.730E-17 38.0 23.4 6.13 26.9 8.11 50.9 13.8 21.0
1G.9 7.GG2E-I2 80.7 100. 4.:31GE-12 O.U&2 0.124 100. 100. 100.
U3.8 fJ7.£i 97.7 '/0.9 B3.5 97.8
98.3
02.'
99.8
84.7
82.1
85.1
0.519E-08
-------�
DO
O
7. OF ALL PATHWAYS
AIR IMMERSION
7. OF EXTERNAL
7. OF ALL PATHWAYS
GROUNLi 'a
X OF EXTERNAL
7. OF ALL PATHWAYS
INTERNAL
X OF ALL PATHWAYS
EXTERNAL
OF ALL PATHWAYS
TOTAL OVER ALL PATHWAYS
X OF TOTAL
Q.232E-12 9.730E--17 36.0
4.906E-03 7.6G2E-12 80.7
72.1 8.84 81.4
30.6 63.2 85.0
0.100 4.48 4.10 0.130 0.155 13.8 21.0
0.110 4.316E-12 G.042E-02 0.124 100. 60.0 7.081E-
74.1 8:J.G %.G 95.3 70.9 58.8 95.6
EI.519E-08
o.oooi;ioo
5.171E-18
4.22'JL-22
1.5U9E-19
O.OOOE+00
7.G44E-06
9.767E-07
2.722K-06
O.OOOEiOO
7.G4i00 4.003E-06 'J.943E-
9.409E-02 1.360E-06 5.G14E-04 O.OOOE+00 O.OOOE+C
1.198E-03 O.OOOE+00 O.OOOE+00 7.754E-04 1.515E-
1.045E-08 9.838E-09 O.OOOE+00 1.1C6E-06 8.862E-
O.OOOEiOO
2.281E-21
1.002E-11
5.001E-13
O.OOOE^O
100.
100.
100.
O.OOOE+00
2.230E-15
1J1.1
25.4
1.360E-22
O.OOOE+00
7.930E-15
1.064E-15
78.4
O.OOOE+00
100.
100.
4 12
O!OOOE+OO
0.820
0.112
2.004E-
1.942E
3.448E
B.861E
100.
100.
]00.
100.
99.6
99.9
24.5
4.098E
15 9.721E-18 6.707E-18 7.272E-15 3.994E-13 O.OOOE+00 O.OOOE+(
-14 1.888E-15 4.226E-14 O.OOOE+00 O.OOOE+00 J.CJ1E-17 1.747E-
-14 8.359E-15 2.871E-14 5.827E-14 O.OOOE+00 1.351E-12 5.091E-
-11
100.
100.
100.
26.8
-07
99.9 100. 100. O.OOOE+00 O.OOOEK
100, O.OOOE + 00 O.OOOd^O 100. 100.
100. 100. O.OOOE+00 100. 100.
84.7 9CI.4 99.7 O.OOOE + 00 O.OOOE+C
93.0 O.OOOE+00 O.OOOE+00 20.0 99.9
1.22 2.44 O.OOOti+00 29.6 2.25
6.755E-09 8.595E-05 3.14GE--21 8.947E-18 2.650E-17 1.208E-18 1.103E-16 1.220E-15 1.720E-16 3.947E-]
1.963E-14 1.023E-04 3.472E-16 2.147E-17 2.143E-02 3.184E-15 2.144E-14 1.3G4E-1G 1.531E-1G 1.238E-
1.19511-13 1.0blE-12 9.607E-13 1.062E-13 2.455E-12 2.332E-12 2.329E-12 2.077E-14 3.208E-12 2.215E-
3.406E-12 1.468E-12 9.518E-13 2.1G2E-02
100. 100. 94.7 0.427 73.2 15.2 1.60 0.305 100. 100.
0.110 100. 7.01 100. 100. 80.0 7.081E-
'/b.5 99.7 98.0 97.6 100. 70.4 97.8
2.901E-02
73.4
36.8
100.
8.8t
74.6
100.
99.2
99.9
O.OOOL'KOO O.OOOEiOO 1.744E-22 2.004E-15 9.721E-18 6.714E-18 7.272E-15 3.994E-13 O.OOOEiOO O.OOOE+(
6.765E-11 2.281E-21 O.OOOE+00 1.942E-14 1.888E-15 4.226E-14 O.OOOE+00 O.OOOEi-00 J.832E-17 1.747E-
4.330L-14 1.002E-11 7.939E-15 3.448E-14 8.359E-15 2.871E-14 5.827E-14 O.OOOE+00 1.351E-12 5.091E-
5.337E-12 S.001E-13 1.0G4E-15 8.BG1E-11
O.OOOE+00 O.OOOE+00 5.25
100. 2.230E-15 O.OOOE+00
26.6 91.1 0.820
63.2
25.4
O.lli
99.6
99.9
24.5
26.8 84.8
3.I307E-12 93.0
0.339 1.22
98.4 99.7 O.OOOEiOO O.OOOEK
O.OOOE+00 0.000l->00 20.0 99.9
O.OOOEiOO 29.6
2.44
2.25
6.755E-09 8.595E-05 3.320E-21 2.093E-15 3.622E-17 7.922E-18 7.390E-15 4.007E-13 1.720E-16 3.947E-]
G.767E-11 1.023E-04 3.472E-1G 1.944E-14 2.143E-02 4.544E-14 2.144E-14 1.364E-16 1.914E-1G 1.748E-
1.62CE-13 1.187E-11 9.G86E-13 1.407E-13 2.463E-12 2.3G1E-12 2.387E-12 2.077E-14 4.560E-12 2.2GGE-
9.243E-12 1.968E-12 9.520E-13 2.162E-02
3.124E-05 0.397 1.535E-17 9.681E-12 1.675E-13 3.6G4E-14 3.418E-11 1.853E-09 7.957E-13 1.825E-]
3.130E-07 0.473 1.606E-12 8.989E-11 99.1 2.102E-10 9.916E-11 G.308E-13 8.852t^l3 8.08GE-
7.529E-10 5.490E-08 4.479E-09 6.506E-10 1.139E-08 1.092E-08 1.104E-08 9.G05E-11 2.109E-08 1.048E-
4.274E-08 9.103E-09 4.406E-09
DARTAB INFO
COLLECIWE GENETIC DOGE EQ. (PERSON REM)
OAAA3UMMED OVER ALL GONAD
NUCLIDES
H-3
NB-94
U-2J4
C-14
TC-99
U-235
CR-51
RU-10G
NP-237
MN-54
SB-125
U-238
FE-55
1-129
PU-238
CO-58
CS-134
NI--59 CO- 60 N1-G3 bR-90
CS-135 CS-137 CE-144 L'U-15'
PU-240 PU-241 AM-241 PU-242
-------�
INGEST ION
Z OF INTERNAL
Z OF ALL PATHWAYS
INHALATION
X OF INTERNAL
Z OF ALL PATHWAYS
oo AIR IMMERSION
i
'/. OF EXTERNAL
'/. OF ALL PATHUAYS
GROUND SURFACE
Z OF EXTERNAL
Z OF ALL PATHWAYS
INTERNAL
Z Of ALL PATHWAYS
EXTERNAL
AM-243
1.952E-07
7.651E-13
2.637K-15
1.505E-12
100.
99.8
27.7
17.9
100.
3.388E-02
0.2C5
0.741
CM-243
1.221E-03
3.699E-04
5.979E-15
8.G28E--13
100.
100.
80.4
1G.G
]00.
100.
1.75GE-03
4.09
CM-244 TOTAL
9.839E-20 2.694E-16 5.639E-16 5.574E-17 2.517E-15 2.280L-14 3.323E-15 2.795E-]
1.024E-15 O.OOOE+00 3.641E-04 8.522E-14 6.708E-13 O.OOOE+00 O.OOOE+00 O.OOOE<
1.191E-12 1.298E-13 1.398E-13 8.591E-15 1.412E-12 1.232E-
4.472E-13 2.613E-15
G.360G-13 1.955E-03
9G.5
'J7.1
39.0
16.5
91. 5
97.1
31.9
16.4
96.6
O.OOOE+00
29.6
100.
0.386
O.OOOVM-00
0.366
100.
97.3
100.
39.1
82.3
100.
37.0
99.0
99.2
6.08
19.9
5.70
4.67
97.9
99.9
6.53
3.09
99.9
4.17
97.9
96.2
71.1
O.OOOEHOO O.OOOE+00 O.OOOE<
35.5
0.172
17.3
96.2
6.08
71.1
O.OOOE+00 O.OOOE+00 O.OOOE<
35.5
2.62
1.671E-20 1.235E-21 3.566E-21 9.414E-1G 1.553E-17 5.358E-19 5.478E-17 4.967E-16 1
1.78bE-15 1.G63E-1Q 3.080L-17 1.953E-17 1.554E-17 7.272E-16 7.958E-16 3.859E-15
' ••• 1.854E-12 2.004E-12 2.002E-12 1.563E-14
6.893E-15 1.455E-15 7.004E-13 6.222E-15
6.922E-12 4.346E-12 3.210E-12 2.975E-11
3.3EI
100.
70.4
1.521E-06
8.557E-12
0.233
72.3
82.1
1.011E-16 3.50
4.496E-13 2.92
19.6
.4
8.557K-12 1.011E-16
7.903E-05 4.496E-13
0.746 4.if74E-04
3.41 20.6
O.OOOll + OO 0
1.727L-16
1.219E-20
5.3b2E-18
O.OOOE+00 0
7.6401-.;-06
1.333E-06
2.750E-06
O.OOOE+00 0
7.64GE-06
1.3191!--06
2.636E-06
.OOOE+00 1
3.138E-24
1.502E-17
9.855E-18
.OOOE+00
4.190E-03
4.413E-06
6.204E-05
.OOOE+00
8.483E-19
4.412E-06
4.672E-05
O.OOOE-iOO 0.
2.258E-09 7
9.147E-13 3
1.946E-10 1
O.OOOE-iOO 0.
100.
100.
100.
O.OOOE-iOO 0.
100. 2
99.0
95.8
OOOE+00 4
.488E-20
.404E-10
.589E-11
OOOE+00
100.
100.
100.
OOOE+00
.024E-14
100.
75.3
61.0
83.5
3.31
2.92
50.0
83.0
.216E-21
O.OOOE+00
B.558E-19
3.386E-21
21.& '
O.OOOE+00
3.396E-04
1.430E-05
1.13
O.OOOE+00
6.115E-05
8.75iE-OG
.411E-21
O.OOOE+00
2.520E-13
2.369E-L4
78.4
O.OOOE+00
100.
100.
4.10
O.OOOEHOO
1U.O
0.612
2.68 0.952
4.267L-12 0.846
60.9 93.9
1.348E-02 2.27 0.191
3.030E-03 4.267E-12
0.872
1.521E-06
2.873E-18
6.007E-18
7.317E-21
3.954E-16
4.132E-03
9.320E-04
1.109E-06
1.348E-05
4.116E-03
9.319E-04
1.095E-06
2.022E-11
57.6
2.13
0.118
93.5
6.717E-02
I 0.118
59.8
2.13
100.
64.5
3.754E-03
100.
64.5
.314E-
3.744E
6.765E
3.80
100.
82.7
3.80
0.298
12.6
3.99
16 1.135E-:
-18 2.860E-
12 1.902E-
28.9
100.
93.9
28.9
4.940E-
61.7
1.019E-22 2.489E-19 1.094E-21 7.435E-17 O.OOOE+00 O.OOOE+(
2.231E-19 1.813E-17 O.OOOE+00 O.OOOEiOO 4.802E-20 8.783E-
5.394E-21 7.070E-21 5.706E-21 O.OOOE^O 1.89.JE-18 4.934E-
9.655E-05 0.111 1.38&E-OG 5.630E-04 O.OOOEvOO O.OOOE+I
2.894E-04 1.286E-03 O.OOOE+00 O.OOOE+00 3.829E-03 1.517E-
3.126E-06 1.100E-06 4.720E-07 O.OOOE+00 4.148E-06 4.G60E-
1.488E-05 8.885E-02 1.342E-06 5.620E-04 O.OOOE+00 O.OOOE+(
6.128E-14 1.212E-03 O.OOOE+00 O.OOOE+00 3.818E-03 1.517E-
1.676E-07 2.546E-07 1.703E-07 O.OOOE^O 3.518E-06 1.600E-
6.954E-
6.446E
7.047E
2.933E
100.
100.
100.
100.
99.6
100.
98.8
1.500E
14 1.055E-16 2.236E-16 7.897E-14 1.321E-11 O.OOOE+00 O.OOOE+(
-13 7.710E-14 1.410E-12 O.OOOE+00 O.OOOEfOO 1.254E-15 5.790E-
-13 1.725E-13 6.425E-13 1.209E-12 O.OOOE+00 4.562E-11 1.059E-
-09
100.
100.
100.
99.9
100.
100.
-04
15.4 79.8
2.117E-08 94.3
S.36 23.1
100. 100. O.OOOE+00 O.OOOEH(
O.OOOE + 00 O.OOOVJ + 00 100. 100.
100. O.OOOE+00 100. 100.
96.8 99.8 O.OOOL+00 O.OOOE+(
O.OOOE+00 O.OOOE+00 99.7 100.
36.1 O.OOOE+00 84.8 34.3
1.952E-07 1.221E-03 1.020E-19 2.789E-16 5.794E-16 5.627E-17 2.571E-15 2.330E-14 3.455E-15 3.930E-]
7.669E-13 3.699E-04 1.055E-15 1.953E-17 3.641E-04 8.595E-14 6.716E-13 3.859E-15 3.744E-18 2.860E-
9.530E-15 7.433E-15 1.148E-12 8.835E-15 3.045E-12 2.134E-12 2.142E-12 2.423E-14 8.177E-12 2.025E-
8.427E-12 5.209E-12 3.846E-12 1.955E-03
100. 100. 94.8 0.399 84.6 20.1
100. 5.75
94.6 7G.9
3.396E-02 100.
1.03 2.1B4E-03
4.15
24.7
100.
82.0
99.4
3.030E-03
1.24
3.15
100.
63.9
0.176
100.
100.
100.
0.298
15.2
100.
4.940E-
65.7
O.OOOE+00 O.OOOE+00 5.627E-21 6.954E-14 1.055E-16 2.238E-16 7.897E-14 1.321E-11 O.OOOE+00 O.OOOE+(
2.258E-09 7,4eSB-30 Q,f>ooc i.0£> ^r44&S=-l'3 7t7tOE-H *-*K'P 13
-------�
X OF ALL PATHWAYS
TOTAL OVER ALL PATHWAYS
7. Of TOTAL
9.147E-13 3.404E-10 2.520E-13 7.047E-13 1.725K-13 6.425E-13 1.209E-12 O.OOOE+00 4.562E-11 1.059E-
1.946E-10 1.5B9E-11 2.3G9E-14 2.933E-09 nAAn ,
O.OOOE-iOO O.OOOE+00 5.23 99.6 J5.4 79.9 96.to 99.8 O.OOOHOO O.OOOE+(
100. 2.117E-OU 94.3
•Jhl.U 5.36 23.1
100.
99.0
95.0
2.024E-14 O.OOOE'tOO
100. 18.0
75.3 0.612
O.OOOE+00 O.OOOE+00
36.1 O.OOOE+00
99.7
84.8
100.
34.3
1 DARTAB INFO
FATAL CANCER RATE (DEATH/YR)
COMB.LET
OAAASUMMED OVER ALL CANCER
NUCLIllLS
1.952L-07 1.221E-03 1.076E-19 6.982E-14 6.849E-16 2.801E--16 B.154E-14 1.323E-11 3.455E-15 3.930E-1
2.258E-09 3.699E-04 1.055E-15 6.446E-13 3.641E-04 1.49GE-12 6.716E-13 3.859E-15 1.258E-15 5.790E-
9.243H-13 3.404E-10 1.400E-12 7.136E-13 3.218E-12 2.777E-12 3.351E-12 2.423E-14 5.380E-11 3.084E-
2.030L'-10 2.109E-11 3.870E-12 1.955E-03
9.9Q3E-03 62.5
1.155L-04 10.9
4.727L-00 1.741E-05 7.157E-08 3.649E-08 1.645E-07 1.420E-07 1.714E-07 1.239E-09
1.038E-05 1.079E-06 1.979E-07
5.502E-15 3.571E-09 3.503E-11 1.432E-11 4.170E-09 6.7G6E-07 1.7G7E-10 2.010E-)
.395E-11 3.296E-08 10.6 7.648E-08 3.435E-08 1.974H-10 6.432E-11 2.961E-
--" -- -- •- -' - " 16 1.577E-
INGEST10N
oo % Of INTERNAL
'/. OF ALL PATHWAYS
INHALATION
'/. Of INTERNAL
% OF ALL PATHWAYS
AIR IMMERSION
X OF EXTERNAL
% OF ALL PATHWAYS
GROUND SURFACE
H-3
NB-94
U-234
AM-243
C-14
TC-99
U-235
CM-243
CR-51
RU -106
NP-237
CM-244
HN-54
•JB--125
U-238
TOTAL
FE-55
1-129
PU--238
CO-50
CS-134
PLI-239
NI-59
CS-135
PU-240
CO-60
CS-137
PU-241
NI--63
CE-144
AM-241
SR-90
EU-15'
PU-24:
1.89C.E-12 2.411E-08 5.474E-25 1.923E-21 G.523E-21 2.479E-22 2.736E-20 1.622E-19 3.773E-20 8.052E-)
4.555E-18 2.869E-08 1.863E-20 O.OOOE+00 6.023E-07 B.824E-19 5.978E-18 O.OOOE^O O.OOOE^O O.OOOE^
2.307E-19 2.658E-19 1.017E-17 2.303E-19 2.551E-17 3.017E-18 3.243E-18 2.688E-19 3.168E-17 2.868E-
3.437E-17 1.6B7E-17 1.176E-17 6.551E-07
100.
84.3
1.72
16.5
100.
2.398E-02
0.903
1.86
1.561E-25
8.466E-19
1.317E-17
1.730K-16
8.232E-12
15.7
98.3
83.5
8.232E-12
4.457E-03
51.6
9.42
O.OOOE+00
1.451E-21
1.187E-25
4.457E-23
O.OOOE+00
7.G44L-06
9.7G8E-07
2.721E-OG
o.ooomoo
7.G42E-OG
4.G44E-07
2.414E-OG
100.
100.
0.237
14.8
100.
100.
8.443E-03
6.63
2.346E-26
2.198E-21
1.119E-1G
9.722E-17
9.730E-17
7.663E-12
99. G
85.2
9.730E-17
7.663E-12
3.55
38.2
O.OOOE+00
2.683E-29
1.334E-22
8.G55E-23
O.OOOE+00
4.190E-03
4.392E-06
G.1G7E-05
O.OOOE+00
9.350E-20
4.235E-06
3.401E-05
62.0
19.5
13.4
14.5
50.7
19.5
13.1
14.4
3.355E-25
7.711E-20
6.549E-17
G.945E-17
3U.O
80.5
86.6
85.5
36.0
80.5
84.1
85.2
1.057E-26
o.ooofi+oo
7.317E-24
3.909E-26
21.6
O.OOOE+00
3.284E-04
1.310E-05
1.13
O.OOOE+00
9.393E-OG
4.796E-08
76.6
o.ooot+oo
1.92
100.
0.327
O.OOOMOO
1.06
100.
5.883E-22
G.024E-21
1.179E-17
1.451E-15
23.4
100.
9U.L
2.215E-07
0.100
0.110
54.3
2.215E-07
2.417E-23
5.079E-23
7.891E-26
3.34GE-21
4.132E-03
9.320E-04
8.158E-07
1.345E-05
4.115E-03
9.310E-04
3.638E-07
5.107E-13
93.6
100.
12.4
67.3
100.
12.2
4.424E-22
2.60SE-20
1.805E-16
6.35
4.330H-12
87.6
4.56
4.330E-12
06. 6
2.G33E-27
1.538E-24
G.336E-2G
9.655E-05
2.903E-04
2.702E-06
2.717E-05
2.553E-16
3.041E-08
73.1
99.1
1.57
11.2
6.92
1.51
9.102E-23
7.676E-21
1.892E-16
26.9
0.862
98.4
4.09
6.020E-02
94.5
2.092E-24
1.528E-22
6.926E-2G
0.111
1.289E-03
8.59GE-07
9.409E-02
1.199E-03
3.458E-08
91.3 49.4 85.3 79.7
99.9 O.OOOE^O O.OOOE+00 O.OOOE^
L.69 27.8 15.9 1.57
1.32 0.144 85.3 79.7
99.9 O.OOOEHOO O.OOOE+00 O.OOOE<
1.56 27. U 5.48 1.46
2.G20E-21 1.664E-19 G.525E-21 2.048E-
7.431E-21 3.808E-20 4.229E-20 3.023E-
l.OOOE-16 6.934E-19 1.6746-16 1.797E-
8.74 50.6 14.7 20.3
0.124 100. 100. 100.
98.3 72.2 04.1 98.4
0.127 0.14U 14.7 20.3
•0.124 100. 79.7 6.161L
90.6 72. '.2 28.9 91.3
2.820E-26 6.312E-22 0.000£K)0 O.OOOE+(
O.OOOE+00 O.OOOE+00 4.165E-25 7.436E-
6.589E-26 O.OOOE+00 1.518E-23 5.633E-
1.3B2E-06 5.G31E-04 O.OOOE^O O.OOOE + (
O.OOOE+00 O.OOOE + 00 3.873E^-03 1.516E-
4.031E-07 O.OOOE+00 4.003E-06 3.943E-
1.362E-06 5.614E-04 O.OOOE+00 O.OOOE+C
O.OOOE+00 O.OOOE+00 7.852E-04 1.516E-
3.1G2E-08 O.OOOE+00 2.G25E-06 2.862E-
O.OOOE+00 O.OOOE<00 3.838E-26 5.850E-19 2.727E-21 1.882E-21 2.040E-18 1.121E-16 O.OOOE+00 O.OOOE+(
1.099E-14 6.402E-25 O.OOOE+00 5.449E-18 5.297E-19 1.186E-17 O.OOOE+00 O.OOOE+00 1.075E-20 4.903E-
-------�
en
i
oo
OF EXTERNAL
X OF ALL PATHWAYS
INTERNAL
I OF ALL PATHWAYS
EXTERNAL
OF ALL PATHWAYS
TOTAL OVER ALL PATHWAYS
'/. OF TOTAL
OAAASUMMED OVER ALL GONAD
NUCLIDES
INGES11UN
X OF INTERNAL
'/. OF ALL PATHWAYS
INHALATION
I OF INTERNAL
1.215E-17 3.036E-15
1.630E-15 1.403E-16
0
0
.OOOEi-00
100.
100.
100.
.OOOtM-00
100.
47. 5
88.7
O.OOOE +00
100.
100.
100.
O.OOOK+00
2.231E-15
CJ6.4
55.2
2.228E-18
2.984E-19
78.4
O.OOOE+OO
100.
100.
4.12
O.OOOE+00
2. 86
0.366
9.673E-1G
2.487E-14
100.
100.
100.
100.
99.6
99.9
44.6
3.796E-06
2.345E-18
100.
100.
100.
2K.1
U.795E-11
1.13
8.0561
99.9
100.
100.
84.7
93.0
4.0i!
100. 100. O.OOOE+00 0.000£+(
O.OOOE+00 O.OOOE+00 100. 100.
100. O.OOOt'+OO 100. 100.
9U.6 99.7 O.OOOE+00 O.OOOE*<
O.OOOE + 00 0.000>-+00 20.3 99.9
7.84 O.OOOt+00 65.6 7.26
1.896E-12 2.411E-OQ Q.828E-25 2.511E-21 6.965E-21 3.389E-22 2.998E-20 3.286E-19 4.426E-20 1.010E-]
5.401E-18 2.869E-08 9.574E-20 6.024E-21 6.023E-07 8.901E-19 5.985E-18 3.808E-20 4.229E-20 3.023E-
1.340E-17 1.121E-16 7.567E-17 1.202E-17 2.060E-16 1.922E-16 1.920E-16 9.672E-19 1.991E-16 1.825E-
2.083E-1G 1.141E-16 8.121E-17 6.551E-07
100. 100. 94.7 0.427 71.9 15.2 1.45 0.292 100. 100.
- - -- - o.llO 100. 6.-3U 100. 100. 79.7 6.161E-
55.4 98.9 96.0 92.2 100. 34.4 92.7
2.844E-02
52.5
11.3
100.
3.56
44.0
100.
97.1
99.6
O.OOOE+00 O.OOOE+00 4.B95E-26 5.850E-19 2.727E-21 1.884E-21 2.040E-18 1.121E-16 O.OOOE+00 O.OOOE+(
1.899K-14 6.402E-25 O.OOOE+00 5.449E-18 5.297E-19 1.186E-17 O.OOOE+00 O.OOOE+00 1.075E-20 4.903E-
1.215E-17 3.036E-15 2.228E-18 9.673E-18 2.345E-18 8.056E-18 1.635E-17 O.OOOE+00 3.792E-16 1.428E-
1.630E-15 1.403E-16 2.984E-19 2.487E-14
O.OOOK'+OO O.OOOE+00 5.25 99.6 28.1 84.8
100. 2.231E-15 O.OOOE+00 99.9 8.795E-11 93.0
1.13 4.02
47.5
88.7
96.4
55.2
2.86
0.366
44.6
98.6 99.7 O.OOOE+00
O.OOOE+00 O.OOOE+00 20.3
O.OOOE+00
7.84
65.6
O.OOOE+(
99.9
7.26
1.096E-12 2.411E-08 9.318E-25 5.875E-19 9.692E-21 2.223E-21 2.070E-18 1.124E-1G 4
1.899E-14 2.869E-08 9.574E-20 5.455E-18 6.023E-07 1.275E-17 5.985E-18 3.808E-20
2.555E-17 3.149E-15 7.790E-17 2.1G9E-17 2.084E-16 2.003E-16 2.084E-16 9.672E-19
1.84GE-15 2.544E-16 8.150E-17 6.551E-07
.426E-20 1.010E-]
5.304E-20 4.906E-
5.783E-16 1.968E-
UARTAfc INFO
COLLECTIVE
COMB. LET
: n w A fi
] U N H U
2.894E-04 3.68 1.422E-1G 8.968E-11 1.480E-12
2.099E-06 4.38 1 .462E-11 8.328E-10 91.9
3.900E-09 4.807E-07 1.1B9E-08 3.312E-09 3.181E-08
2.010t-07 3.884E-OB 1.244E-08
GENETIC EFFECKEFFECTS/YR)
H-3 C-14 CR-51 MN-54 FE-55
NB-94 TC-99 RU-106 SB-125 1-129
U-234 U-2J5 NP-237 U-238 PU-230
AM-243 CM-243 CM -244 TOTAL
7.173E-13 4.4Q7H-09 3.615E-25 9.901E-22 2.072E-21
2.011E-18 1.359E-09 3.764E-21 O.OOOE+00 1.338E-09
9.689E-21 2.197E-20 1.643E-18 9.601E-21 4.376E-18
5.531E-18 3.171E-18 2.337E-18 7.185E-09
100. 100. 96.5 96.6 97.3
99.8 100. 97.1 O.OOOEi-00 100.
27.7 80.4 39.0 29.6 39.1
17.9 16.6 16.5 100.
100. 100. 91.5 0.3U6 D2.3
3.300E-02 100. 97.1 O.OOOEHOO 100.
0.285 1.75GE-03 31.9 0.366 :J7.0
0.741 4.09 1G.4 100.
3.394E-13 3.1GOE-10 1.716E-08 G.756£-12 1.542E-1
1.946E-09 9.137E-10 5.813E-12 8.097E-12 7.490E-
3.058E-08 3.181E-08 1.476E-10 8.828E-08 3.005E-
CO-58 Nl-59 CO-60 Nl-63 SK-90
CS-134 CS-135 CS-137 CE-144 EU-15'
PU-239 PU-240 PU-241 AM- 241 PU • 24i
2.048E-22 9.247E-21 8.378E-20 1.221E-20 1.027E-I
3.132E-19 2.465E-18 O.OOOEvOO O.OOOE+00 O.OOOE-
4.769E-19 5.137E-19 3.157E-20 5.108E-18 4.527L-
99.0 97.9 97.9 96.2 71.1
99.2 99.9 O.OOOEi-00 O.OOOE + 00 O.OOOE^
6.08 6.53 35.5 17.3 6.08
19.9 3.09 0.172 96. 2> 71.1
5.70 99.9 O.OOOE-iOO O.OOOE+00 O.OOOE^
4.67 4.17 35.5 2.62 3.99
6.139E-26 4.536E-27 1.310E-26 3.459E-23 5.706E-23 1.969E-24 2.013E-22 1.825E-21 4.827E-22 4.170E-:
6.559E-21 6.110E-24 1.132E-22 7.176E-23 5.709E-23 2.672E-21 2.924E-21 1.41BE-20 1.376E-23 1.051E-
6'813E'18 7-365£-18 7.358E-18 5.745E-20 2.486E-17 6.989E-
2.533H-20 5.346E-21 2.
^ 543E-17 1 597E~17 1
87557E-12 1.011E-1G 3!SO
0.233 4.49GE-13 2.92
100.
2.68 0.952 2.13 2.13 3.80 28.9
4.267E-12 0.846 0.118 100. 100. 100.
-------�
7. OF ALL PATHWAYS
AIR IMMERSION
X OF EXTERNAL
7. OF ALL PATHWAYS
GROUND SURFACE
I OF EXTERNAL
X OF ALL PATHWAYS
INTERNAL
7. OF ALL PATHWAYS
EXTERNAL
X OF ALL PATHWAYS
TOTAL OVER ALL PATHWAYS
X OF TOTAL
72.3 19.6
82.1 D3.4
G.557E--12 1.011E-16
7.903E-05 4.496E-13
0.746 4.274E-04
3.41 20.6
O.OOOE+00
6.3451--22
4.481E-2&
1.9G7K-23
O.OOOL^OO
7.64(iF::-06
1.333L'-OG
2.750E-06
O.OOOE+00
7.646E-06
1.319E-06
2.636E-06
O.OOOtMOO
8.296E-15
3.361E-1B
7.151E-16
O.OOOE+00
100.
100.
100.
O.OOOL-iOO
100.
99.0
95.0
O.OOOE+00
1.153E-29
5.519E-23
3.G21E-23
O.OOOE+00
4.190E-03
4.413E-06
G.204E-05
O.OOOEnOO
8.483E-19
4.412E-06
4.672E-05
61.0
83.5
3.31
2.92
50.0
03.0
4.467E-27
O.OOOE+00
3.145E-24
1.244E-26
21.6
O.OOOE+00
3.396E-04
1.430E-05
1.13
O.OOOE+00
6.115E-05
0.751E--08
70.4
1.521E-OG
1.340E-02
60.9
93.9
93.5
64.5
2.27 0.191 6.717E-02 3.754E-03
3.030E-03 4.267E-12 4.862E-02 0.118 100.
0.872 57.6 72.2 59.8 64.5
1.521E-06
U2.7
3.80
0.298
12.6
93.9
28.9
4.940E-
61.7
1.056E-23 3.
2.207E-23 8
2.872E-26 1
1.453E-21
4.132E-03 9.
9.320E-04 2
1.109E-06 3
1.348E-05
4.11GE-03 1.
9.319E-04 6
1.095E-06 1
2.022E-11
745E-28 9.145E-25 4.022E-27 2.732E-22 0.000£K>0 O.OOOE+(
.199E-25 6.661E-23 O.OOOE+00 O.OOOE+00 1.765E-25 3.227E-
.982E-2G 2.S98E-26 2.097E-26 O.OOOE+00 G.955E-24 L.013E-
655E-05 0.111 1.386E-06 5.G30E-04 O.OOOE+00 O.OOOE+(
.894E-04 1.286E-03 O.OOOE+00 O.OOOE+00 3.829E-03 1.517E-
.126E-OG 1.100E-OG 4.720E-07 O.OOOEnOO 4.148E-06 4.660E-
488E-05 8.885E-02 1.342E-OG 5.620E-04 O.OOOE+00 O.OOOE+(
.128E-14 1.212E-03 O.OOOEK>0 O.OOOEK>0 J.81UG-OJ 1.517E-
.676E-07 2.54GE-07 1.703E-07 O.OOOE+00 3.518E-06 1.600E-
O.OOOE+00 1
2.7S1E-25
1.251E-15
5.837E-17
O.OOOE+00
100.
100.
100.
O.OOOE+00
2.024E-14
100.
75.3
.G21E-2G
O.OOOE+00
9.259E-19
8.704E-20
78.4
O.OOOE+00
100.
100.
4.10
O.OOOE+00
13.0
0.612
2.555E-
2.3G8E
2.590E
1.078E
100.
100.
100.
]00.
99.6
100.
98.8
1.500E
19 3.878E-22 8.215E-22 2.902E-19 4.853E-17 O.OOOE+00 O.OOOE+(
-18 2.833E-19 5.180E-18 O.OOOE+00 O.OOOE+00 4.608E-21 2.127E-
-18 6.340E-19 2.3G1E-18 4.442E-10 O.OOOE+00 1.676E-16 3.391E-
-14
JOO.
100.
100.
99.9
100.
100.
-04
15.4 79.8
2.117E-08 94.3
>.3G 23.1
100. 100. O.OOOE+00 O.OOOE+(
O.OOOE+00 O.OOOE-iOO 100. 100.
100. O.OOOGKJO 100. 100.
96.8 99.8 O.OOOE+00 O.OOOE+(
O.OOOE+00 O.OOOE+00 99.7 100.
36.1 O.OOOE-iOO 84.8 34.3
7.173E-13 4.487E-09 3.746E-25 1.025E-21 2.129E-21 2.068E-22 9.448E-21 8.561E-20 1.269E-20 1.444E-:
2.818E-18 1.359E-09 3.877E-21 7.176E-23 1.338E-09 3.158E-19 2.468E-18 1.418E-20 1.376E-23 1.051E-
3.502E-20 2.731E-20 4.217E-18 3.247E-20 1.119E-17 7.842E-18 7.872E-18 8.902E-20 3.005E-17 7.442E-
3.097E-17 1.914E-17 1.413E-17 7.185E-09
100. 100. 94.8 0.399 84.6 20.1 3.15 0.176 100. 100.
3.030E-03 100. 5.75 100. 100. 0.2'JB 4.9401!-
1.24 94.6 7 6.-3 63.9 100. 15.2 65.7
3.396E-02 100.
1.03 2.134E-03
4.15 24.7
100.
02.0
99.4
O.OOOE+00 O.OOOE+00 2.068E-2G 2.555E-19 3.878E-22 8.224E-22 2.902E-19 4.853E-17 O.OOOE+00 O.OOOE+(
8.296K-15 2.752E-25 O.OOOE+00 2.369E-18 2.033E-19 5.180E-18 O.OOOE+00 O.OOOE+00 4.608E-21 2.127E-
3.361t:-18 1.251E-15 9.259E-19 2.590E-18 6.340E-19 2.361E-18 4.442E-18 O.OOOE+00 1.676E-16 3.891E-
7.151E-16 5.837E-17 8.704E-20 1.078E-14
O.OOOtMOO O.OOOE+00 5.23 99.6 15.4
100. 2.024E-14 0.0001M-00 100. 2.117E-OU
99.0 100. 18.0 98.8 5.36
95.3 75.3 0.612
79.9
94.3
23.1
96.8 99.8 O.OOOE+00 O.OOOE+(
O.OOOEK)0 0.000>-+00 99.7 100.
"" " O.OOOL+00 84.8
36.1
34.3
NUCLIDE
7.173E-13 4.487E-09 3.953E-25 2.566E-19 2.517E-21 1.029E-21 2.996E-19 4.861E-17 1.269E-20 1.444E-I
8.299E-15 1.359E-09 3.877E-21 2.369E-18 1.338E-09 5.495E-18 2.468E-18 1.418E-20 4.G22E-21 2.128E-
3.396E-1B 1.251E-15 5.143E-18 2.G22E-18 1.182E-17 1.020E-17 1.231E-17 8.902E-20 1.977E-16 1.133E-
7.4G1E-16 7.751E-17 1.422E-17 7.185E-09 *
9.983E-03 62.5 5.502E-15 3.571E-09 3.503E-11 1.432E-11 4.170E-09 6.766E-07 1.767E-10 2.010E-]
1.155E-04 18,9 5.395E-11 3.296E-08 18.6 7.648E-08 3.435E-08 1.974E-10 6.432E-11 2.961E-
4.727E-08 1.741E-05 7.157E-08 3.G49E-08 1.G45E-07 1.420E-07 1.714E-07 1.239E-09 2.751E-06 1.577E-
1.038E-05 1.079E-06 1.979E-07
RE3IHUAL RADIOACTIVITY RELEASED OUTSIDE THE BASIN
WITH THE STREAM WATER
HKST SECOND THIRD FOURTH FIFTH SIXTH SEVENTH EIGHTH NINTH TENTH
MILLENNIUM MILLENNIUM MILLENNIUM MILLENNIUM MILLENNIUM MILLENNIUM MILLENNIUM MILLENNIUM MILLENNIUM MILLENNIUM
-------�
oo
'
H-3
C-14
CR-51
MN-54
FE-55
CO-58
NI-59
CO-GO
NI-63
SR-90
NB-94
TC-99
RU-106
SB-125
1-129
CS-134
CG-13b
CS-137
CE-144
EU-154
U-234
U-235
NP-237
U-238
PU-238
PU-239
PU-240
PU-241
AM-241
PU-242
AM-243
CM-243
CM-244
H-3
C-14
CR-51
MN-54
FE-55
CO-50
NI-59
CO-60
NI-63
SR-90
NB-94
TC-99
RU-106
SB-125
1-129
CS-134
CS-135
CS-137
CE-144
EU-154
U-234
U-235
NP-237
U-230
PU-23C
PU-239
PU-240
0.24C.OF-02 0.3412E-26 0.66S3E-57
0.9G05E+00 0.9266E-03 0.2564E-07
0.b794E-07 O.OOOOE+00 O.OOOOE+00
0.9496E-05 O.OOOOE+00 O.OOOOE+00
0.2450E--05 O.OOOOE+00 O.OOOOE+00
0.1310E-05 O.OOOOE+00 O.OOOOE+00
0.415GL-02 0.1817E-15 0.794GE-29
0.5G02K-03 O.OOOOE+00 O.OOOOE+00
0.3328E-02 0.7872E-19 0.1864E-35
0.104GE-02 0.2513E-26 0.3427E-50
0.4143E-02 0.6638E-08 0.10G4E-13
0.5245E+00 0.4653E+00 0.6000E-02
0.90LfUi:-0!) O.OOOOEiOO O.OOOOE + 00
0.2348E-03 O.OOOOE+00 O.OOOOE+00
0.40tdL-01 0.63G9E+00 0.1Ei49E + 00
0.8541E-05 O.OOOOE+00 O.OOOOE+00
0.4112t;-02 0.3805E-04 0.3520E-OG
0.5G07E-03 0.4815E-15 0.4137E-27
0.1124E-Ob O.OOOOE+00 O.OOOOE+00
0.7334E-04 0.3543E-23 0.1714E-42
0.414i!l.-02 0.8077E-05 0.1575E-07
0.4144E-02 0.8105E-05 0.1585E-07
0.4200E-02 O.OOOOE-iOO O.OOOOE+00
0.4144E-02 0.8105E-05 0.1505E-07
0.5997E-03 0.b805E-07 0.5619E-11
0.3028E-02 0.7G82E-03 0.1949E-03
0.2939t:-02 O.G901E-03 0.1G21E-03
O.G408E-04 0.2G45E-27 0.1094E-50
0.1227E-03 0.2S50E-04 0.5300E-05
0.3060E-02 0.7974E-03 0.2078E-03
0.2257E-03 0.1932E-03 0.1654t-03
0.2072E-03 0.1877E-13 0.1702E-23
0.1001E-03 0.18G4E-21 0.3475E-39
RESlLiUAL RADIOACIIUIIY IN
TRANS 11 IN YEAR 10000
O.OOOOEK)0
O.OOOOt+00
O.OOOOE^O
O.OOOOE+00
O.OOOOEK)0
O.OOOOEHOO
0.6b28E+00
O.OOOOE+00
0.1413E-32
O.OOOOE+00
0.3739EIOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE + 00
0.2875E-20
O.OOOOEi-00
0.38SbE-iOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE^O
0.4048E+00
0.4164EHOO
0.2529E-05
0.4164EI-00
0.1472E-34
O.OOOOE+00 O
0.1385E-11 0
O.OOOOE+00 O
O.OOOOE+00 O
O.OOOOE+00 O
O.OOOOE+00 O
0.2487E-01 0
O.OOOOE+00 O
0.2947E-12 0
0.3279E-35 0
0.2304E-01 0
0.1G71E-03 0
O.OOOOE + 00 O
O.OOOOE+00 O
0.1232E+00 0
O.OOOOE+00 O
0.22G3E-01 0
0.3219E-34 0
O.OOOOE+00 O
0.1117E-61 O
0.2387E-01 0
0.2411E-01 0
0.3190E-01 0
0.2411E-01 0
0.1804E-13 0
0.1149E-01 0
O.OGG1E-02 0
O.OOOOE+00 O
0.4333E-05 0
0.12G7E-01 0
0.7067E-03 0
0.1087E-32 0
0.1320E-56 0
REMAINING
TRENCH
.OOOOE+00
.1036E-33
.OOOOE+00
.OOOOE+00
.OOOOE+00
.OOOOE+00
.2441E-01
.OOOOE+00
.2909E-15
.0015E-45
.247GE-01
.1562E-03
.OOOOE + 00
.OOOOE+00
.1305E-01
.OOOOE+00
.3073E-01
.7921E-43
.OOOOE+00
.OOOOE+00
.3011E-01
.3049E-01
.3927E+00
.3049E-01
.5683E-1G
.233GE-01
.1G47E-01
.OOOOE+00
.3113E-05
.2637E-01
.1788E-02
.1783E-40
.745GE-72
IN
O.OOOOE+00
0.2395E-76
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEHOO
0.1357E+00
O.OOOOE+00
0.2929E-33
O.OOOOE-<00
0.2028E+00
0.4261E-76
O.OOOOC+00
O.OOOOE-iOO
0.3297E-23
O.OOOOE + 00
0.3957E+00
O.OOOOEiOO
O.OOOOE+00
O.OOOOEHOO
0.3G39C+00
0.3744E+00
0.2024E-14
0.3744E+00
0.2197E-34
O.OOOOE+00 O.OOOOE+00
0.1975E-62 O.OOOOE^OO
O.OOOOEiOO O.OOOOE+00
O.OOOOE+00 O.OOOOE+00
O.OOOOE+00 O.OOOOE+00
O.OOOOE+00 O.OOOOE+00
0.2124E-01 0.1825E-01
O.OOOOE+00 O.OOOOE+00
0.1376E-18 0.6431E-22
0.2185E-55 0.588GE-66
0.2262E-01 0.205GE-01
0.10GOE-18 0.8888E-30
O.OOOOE+00 O.OOOOE+00
O.OOOOE+00 O.OOOOE+00
0.5119E-04 0.1234E-06
O.OOOOE+00 O.OOOOE+00
0.3023E-01 0.29GOE-01
0.7296E-53 0.6639E-63
O.OOOOE+00 O.OOOOE+00
O.OOOOE+00 O.OOOOE+00
0.2928E-01 0.2838E-01
0.2974E-01 0.2891E-01
0.235GE+00 0.1G50E+00
0.2974E-01 0.2891E-01
0.2596E-19 0.1005E-22
0.2572E-01 0.25G5E-01
0.1G80E-01 0.1551E-01
O.OOOOE+00 O.OOOOE+00
0.1137E-05 0.3446E-OG
0.2981E-01 0.3053E-01
0.2610E-02 0.3217E-02
0.8354E-50 0.3279E-59
O.OOOOE+00 O.OOOOE+00
RELEASED TO THE
ATMOSPHERE
0.1349E-OG
0.2318E-06
0.6591E-07
O.OOOOE+00 0.
O.OOOOE+00 0.
O.OOOOE+00 0.
O.OOOOEi-00 0.
O.OOOOE+00 0.
O.OOOOE+00 0.
0.1544E-01 0.
O.OOOOE+00 0,
0.2963E-25 0,
O.OOOOE+00 0,
0.185GE-01 0.
0.6109E-42 0,
O.OOOOE+00 0,
O.OOOOE+00 0,
0.1667E-09 0,
O.OOOOE+00 0,
0.2892E-01 0,
O.OOOOE+00 0,
O.OOOOE+00 0,
O.OOOOEi-00 0,
0.2744E-01 0
0.2803E-01 0
0.1G26E+00 0,
0.2803E-01 0,
0.3750E-2G 0,
0.2497E-01 0
0.1398E-01 0
O.OOOOE+00 0
0.9552E-07 0,
0.3054E-01 0
0.3649E-02 0
0.1230E-G8 0
O.OOOOE+00 0
OOOOE+00
OOOOE+00
OOOOE+00
OOOOE^O
OOOOE+00
OOOOE+00
1282E-01
OOOOE+00
1341E-28
OOOOE+00
1662E-01
1996E-55
OOOOE+00
OOOOE+00
1113E-12
OOOOEt-00
2817E-01
OOOOE+00
OOOOE+00
OOOOE+00
2G43E-01
2707E-01
5509E-02
2707E-01
1385E-29
•2415E-01
1251E-01
OOOOE+00
2513E-07
3034E-01
3940E-02
OOOOE+00
OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
0.1039E-01
O.OOOOE+00
0.5939E-32
O.OOOOE+00
0.1473E-01
0.1470E-70
O.OOOOE+00
O.OOOOE+00
0.3113E-16
O.OOOOE+00
0.2735E-01
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
0.2533E-01
0.2G03E-01
0.1395E-03
0.2603E-01
0.5102E-33
0.2330E-01
0.1117E-01
O.OOOOE+00
O.G388E-08
0.3007E-01
0.4115E-02
O.OOOOE+00
O.OOOOE+00
0.1034E-I-00
0.1555E+00
0.2595E-04
0.4023E-06
0.1850E-03
0.4G92E-04
0.1638E-03
0.1278E-03
0.2210E-03
0.1084E-04
0.6868E-05
0.2332E-04
0.4900E-04
0.1855E-04
0.3739E-03
0.1354E-03
0.4800E-05
0.1110E-03
0.3181E-03
0.3207E-03
O.G041E-04
0.3207E-03
0.1730E-03
0.7410E-03
0.5191E-03
-------�
PU-241
Ah-241
PU-242
AM-243
CH-243
CM-244
O.OOOOE-iOO
0.1563E-07
0/2205E-01
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
0.1300E-06
0.4410E-<00
0.1839E+00
0.0000^00
O.OOOOE+00
0.101GE-03
0.1869E-03
O.G529E-03
0.1020E-02
0.1382E-03
0.1153E-03
HEALTH EFFECTG RESULTING FROM RESIDUAL
RADIOACTIVITY RELEASED IN 1000 YEARS
DO
I
NUCL1DL'
H-3
C-14
CR-51
MN-54
FE-i5
CO-53
NI-59
CO-GO
NI-63
SR-90
NB-94
TC--99
RU-106
SB-12b
1-120
CS-134
CS-13&
CS-137
CE-144
EU-154
U-234
U-235
NP-23'/
U-238
PU-230
PU-239
PU-240
PU-241
AM-241
PU-242
AM-243
CH-243
CM-244
RESIDUAL
ACTIVITY
2.4601E-03
9.G049E-01
5.7943E-00
9.4963E-OG
2.4504B-06
1.3099E-0&
4.1&GOE-03
5.G022E-04
3.3280E-03
1.84&6E-03
4.1431E-03
5.2446E-01
9.0382E-06
2.3476E-04
4.0810E-02
8.5406E-06
4.112bE-03
5.6075E-04
1.1240E-06
7.3340E-05
4.1419E-03
4.1439E-03
4.1996E-03
4.1439E-03
5.9rJ67E-04
3.0277E-03
2.9386E-03
6.4080t-05
1.2274E-04
3.0596E-03
2.2566E-04
2.0718E-04
1.0014E-04
CONVERSION
FACTOR
O.OOOOE-iOO
O.OOOOE^OO
O.OOOOE+00
O.OOOOE+00
O.OOOOE^O
O.OOOOE+00
O.OOOOEHOO
O.OOOOK-iOO
O.OOOOE+00
O.OOOOE+00
O.OOOOIM-OO
O.OOOOE-i-00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE^O
o.oooonoo
O.OOOOE+00
O.OOOOE^O
O.OOOOE+00
O.OOOOE^O
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE<00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
HEALTH
EFFECTS
O.OOOOE+00
O.OOOOE-iOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE^O
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEHOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
HEALTH EFFECTS RESULTING FROM RESIDUAL
RADIOACTIVITY RELEASED IN 10000 YEARS
NUCLIDE
H-3
C-14
CR-51
MN-i.4
EE-55
RESIDUAL
ACTIVITY
2.4601E-03
9.6141E-01
5.7943E-08
9.4'J63fc-OG
2.4504E-06
CONVERSION
FACTOR
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
HEALTH
EFFECTS
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
-------�
CO
CO-bS
NI-59
CO-GO
NI-G3
SR-90
NB-94
TC-99
RU-10G
SB-125
1-129
CS-134
CS-135
CS-137
CE-144
EU-154
U-234
U-235
NP-237
U-238
PU-238
PU-239
PU-240
PU-241
AM-241
PU-242
AM-243
CM-243
CM-244
1.3099E-OG
1.3158E-01
5.G022E-04
3.3280E-03
1.8456E-03
1.4503E-01
9.9589E-01
9.0382E-OG
2.3476E-04
9.9895E-01
8.b40GE-06
2.0178E-01
5.6075E-04
1.1240E-OG
7.3340E-05
1.9498E-01
1.9853E-01
9.97G8E-01
1.9853E-01
5.9973E-04
1.G263E-01
9.8909E-02
6.4080E-05
1.6259E-04
1.9440E-01
2.0G11E-02
2.0718E-04
1.0014E-04
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE-iOO
O.OOOOE-iOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE-iOO
O.OOOOE+00
O.OOOOE-iOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEiOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE-iOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE-iOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE-iOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
COLUMN
COLUMN
COLUMN
COLUMN
COLUMN
COLUMN
COLUMN
COLUMN
COLUMN
TABLE FOR ACCOUNTING MODEL — YEAR 1000
l: INDIVIDUAL CANCER RISK (UNITLESS)
2: BRCULATION DOSE (PERSON-REM/YEAR)
3: COLLLCTIVE CANCER RISK (DEATHS/YEAR)
4: GENETIC RISK (EFFECTS/YEAR)
5: R-ACTIVIIY PUMPED OUT THE WELL 1ST 1000 YEARS (CD
6: R-ACTIVITY PUMPED OUT THE STREAM 1ST 1000 YEARS (CD
7: R-ACTIVITY RELEASED TO ATMOSPHERE 1ST 1000 YEARS (CD
8: R-ACTIVITY RELEASED DOWNSTREAM 1ST 1000 YEARS (CD
9: R-ACTIVITY RELEASED DOWNSTREAM LAST 9000 YEARS (CD
COLUMN 10: R-ACIIVITY IN TRENCH
H-3
C-14
CR-51
MN-54
FE-55
CO-50
NI-59
CO-GO
NI-G3
SR-90
NB-94
TC-99
RU-10G
SB-125
1-129
CS-134
CS-135
CS-137
CE-144
EU-154
U-234
5.3GG3E-12
G.8240E-08
2.6372E-24
1 .6C2!JL- 13
2.7432E-20
6.2927E-21
5.0589L-18
3.1322E-1G
1 "' !b "' b E - 1 1
2i8587E-18
5.3753E-14
8.1199E-08
2.7097E-19
1.5439E-17
1.7046E-OG
3.6088E-17
1.6rJ40E-17
1.0777E-19
1.5012E-19
1.3887E-15
7.2312E-17
6.758GE-09
8.5945E-05
3.3214E-21
2.0942E-15
3.4549E-17
7.9253E-18
7.3791E-15
4.0079E-13
1.5775E-16
3.G004E-15
G.7G99E-11
1.0227E-04
3.4127E-1G
1.9445E-14
2.14G8E-03
4.5451E-14
2.1335E-14
1.3574E-1G
1.8907E-1G
1.7489E-12
1.37G6E-13
AFTER 10000 YEARS ASSUMING PERFECT CONTAINMENT (CD
1.
9
9!
5.
9.
2.
2.
1.
4.
1.
1.
9
9.'
5.
G.
1.
5.
3.
5.
4.
2.
39G1E-12
4111E-OQ
3176E-25
8749E-19
G923E-21
2234E-21
0701E-13
1244E-16
4255E-20
0100E-18
8992E-14
8G90E-08
5739E-20
4551E-18
022GE-07
2751E-17
9053E-18
8079E-20
3041E-20
90G4E-1G
5550E-17
7.1733E-13
4.4872E-09
3.9532E-25
2.5655E-19
2.51G8E-21
1.0292E-21
2.99G4E-19
4.8G14E-17
1.2694E-20
1.4442E-20
8.2990E-15
1.3592E-09
3.8767E-21
2.3G86E-18
1.3381E-09
5.4954E-18
2.4G79E-18
1.4181E-20
4.6217E-21
2.127GE-1G
3.3962E-18
1.G686E-OG
1.18G8E-03
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
1.1355E-03
O.OOOOE+00
O.OOOOE+00
5.3212E-04
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOEfOO
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
1.3492E-07
2.3181E-07
G.5909E-08
5.3G45E-06
2.5954E-05
4.0227E-07
1.6599E-04
4.6919E-05
1.6384E-04
1.2784E-04
1.7183E-04
1.083GE-05
G.8681E-OG
2.3321E-05
4.9001E-05
1.854GE-05
1.7707E-04
1.3537E-04
4.7999E-OG
1.1102E-04
1.7559E-04
2.4G01E-03
9.6049E-01
5.7943E-OQ
9.49G3E-OG
2.4504E-OG
1.3099E-06
4.1560E-03
5.G022E-04
3.3280E-03
1.845GE-03
4.1431E-03
5.244GE-01
9.0382E-OG
2.347GE-04
4.0810E-02
0.540GE-OG
4.1125E-03
5.6075E-04
1.1240E-OG
7.3340E-05
4.1419E-03
3.411GE-27
9.2G66E-04
O.OOOOE+00
O.OOOOE+00
O.OOOOiUOO
O.OOOOE+00
1.2742E-01
O.OOOOE+00
2.9503E-13
2.5130E-27
1.4089E-01
4.7142E-01
O.OOOOE+00
O.OOOOEvOO
9.5814E-01
0.00001^00
1.97G7E-01
4.8146E-16
O.OOOOE+00
3.5431E-24
1.9083E-01
O.OOOOE+00
2.9522E-01
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
9.0787E-01
O.OOOOE+00
1.9G46E-33
O.OOOOE+00
G.9974E-OL
9.5834E-OI
O.OOOOE+00
O.OOOOE+00
9.89GOE-01
O.OOOOE+00
9.8773E-01
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
9.6238E-01
-------�
U-235
NP-237
U-238
PU-238
PU-239
PU-240
PU-241
AM-241
PU-242
AM-243
CM-243
CM-244
TOTALS:
0 MESSAGE
0
? ***
e.cJH4E-ib
2.2047E-16
G.1397E-17
5.89G9E-1G
5.GG88E-1G
5.8977E-1G
2.73'/4E-l£l
l.Gd'GGE-15
5.5708E-1&
5.225Jt-lb
7.2015E-16
2.30G8E-1G
1.8540E-OG
1.1223L-11
2.7767E-13
1.1890E-13
7.42G9E-13
7.139GE-13
7.4279E-13
3.447GE-15
2.0613E-12
7.0162E-13
G.bGllE-12
9.0700E-13
2.9053E-13
2.3350E-03
3
7
2
T
2
9
9
5
1
1
9
8
6
SUMMARY: MESSAGE NUMBER
208
.148GE-15
.789GE-17
.1GCJ3E-17
.0835E-1G
.0029E-1G
.0838E-1G
.6719E-19
.7027E-1G
.9G83E-16
.C4G2E-15
.5445E-16
.1505E-17
.550GE-07
- COUNT
511 Ok
1.250SE-15
5.1427E-18
2.6221E-10
1.1823E-17
1.0203E-17
1.2314E-17
8.9020E-20
1.9770E-1G
1.1333E-17
7.4610E-1G
7.7511E-17
1.4220E-17
7.1B52E-09
OVER
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
o.oooot+oo
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
O.OOOOE+00
1.7559E-04
G.8405E-05
1.7559E-04
1.737GE-04
1.8455E-04
1.8421E-04
1.01G2E-04
1.0372L-04
1.84GGE-04
1.9236E-04
1.3824E-04
1.1531E-04
4.1439E-03
4.1996E-03
4.1439E-03
5.9967E-04
3.0277E-03
2.938GE-03
6.4080E-05
1.2274E-04
3.059GE-03
2.256GE-04
2.0718E-04
1.0014E-04
1.9439E-01
9.9348E-01
1.9439E-01
5.8051E-08
1.59GOE-01
9.5971E-02
2.G451E-2EI
3.985GE-05
1.9134E-01
2.0385E-02
1.8771E-14
1.8G43E-22
9.8999E-01
9.BG74E-01
9.9000E-01
4.I3571E-35
7.4301E-01
3.4299E-01
O.OOOOE+00
2.7402E-07
9.7205E-01
3.8672E-01
O.OOOOE+00
O.OOOOE+00
ARE VOU GULL THERE?
? »**
RESPOND UR PE LOGGED OFF!
-------� |