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EPA-910/8-75-091
JULY 1975
BEAR RIVER EVALUATION REPORT
1974 SURVEY
PREPARED BY:
BILL SCHMIDT
KATHERINE BECK
SURVEILLANCE & ANALYSIS DIVISION
EPA REGION X
1200 SIXTH AVENUE
SEATTLE, WASHINGTON 98101
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THIS DOCUMENT IS AVAILABLE TO THE PUBLIC IN LIMITED QUANTITIES
THROUGH THE U.S. ENVIRONMENTAL PROTECTION AGENCY, REGION X,
SURVEILLANCE & ANALYSIS DIVISION, SEATTLE, WASHINGTON.
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A WORKING PAPER PRESENTS RESULTS OF INVESTIGATIONS WHICH
ARE, TO SOME EXTENT, LIMITED OR INCOMPLETE. THEREFORE,
* CONCLUSIONS OR RECOMMENDATIONS EXPRESSED OR IMPLIED MAY
BE TENTATIVE.
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ABSTRACT
The quality of the waters in the Bear River Basin was surveyed
from August 27 to August 29, 1974. The purposes of the survey were
to determine point and non-point source loading, to determine whether
water quality has improved since the adoption of the 1958 Enforcement
Conference pollution control measures, to determine the cause and
effect relationships between major waste sources and receiving water
quality, and to determine whether major waste sources are complying
with their NPDES permits. Survey results show violations of Idaho
Water Quality Standards in these parameters: bacteria, turbidity, and
dissolved oxygen. Also, levels of Lindane, a chlorinated hydrocarbon
pesticide and mercury significantly higher than the recommended maximal
levels were found in the upper reaches of the Bear River. Although
sufficient data since 1958 was not available to evaluate the pollution
control measures, water quality changes in BOD's and Total Coliform
bacteria were noted. The Monsanto Co. was found to comply with their
NPDES permit in all but one area - there was an apparent temperature
violation. Nutrient loading was investigated and related to algal
productivity - but not all loading sources were located. Other findings
include realization that point sources did not appreciably affect the
quality of the Bear River except in very localized areas.
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TABLE OF CONTENTS
TITLE PAGE
Abstract 4
Summary 9
Basin Description 14
Previous Studies 18
Summary of 1958 Bear River Enforcement Conference 20
Idaho Water Quality Standards 23
Water Quality Trends 28
August 1974 Intensive Survey 32
Bibliography 58
APPENDICES
A - Ambient Data Al
B - 1974 Survey Figures and Tables Bl
C - Monsanto Co. Compliance Report and August 1974 Cl
Survey Raw Data
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LIST OF FIGURES
FIGURE NO. PAGE
I. Location Map of Bear River Basin
2. Bear River Hydrology 17
3. Sampling Station Locations 35
4. Flow Measuring Locations 36
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INTRODUCTION
Unlike most major rivers of the United States that flush pollutants
into the oceans, the Bear River discharges into the Great Salt Lake.
Because the Great Salt Lake has a limited capacity to assimilate
pollutants, it is important to identify and reduce the pollutant levels
entering the lake from the Bear River.
There have been no water quality surveys conducted on the Idaho
portion of the Bear River since 1955. As a consequence, little data
is available to define the present water quality of the Bear River Basin
as required by PL 92-500.
Region X of the Environmental Protection Agency conducted a water
quality survey on August 27,28 and 29 of 1974. The purposes of this
survey were to:
1. Determine the point source and non-point source loading during
the period when the most severe water quality problems exist.
2. Determine whether there has been an improvement in the Bear
River Basin water quality since the 1958 enforcement conference.
3. Expand the data base to support water quality standards
revisions, waste discharge permitting activities and future pollution
abatement actions.
4. Determine the cause and effect relationship between waste
sources and receiving water quality.
5. Determine whether major waste sources are in compliance with
the NPDES permits.
The results of this study are detailed in subsequent sections
of this report.
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LOCATION MAP
BEAR RIVER BASIN
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BEAR RIVER EVALUATION REPORT
SUMMARY
Findings and Conclusions
1. Idaho's water quality standards for bacteria, turbidity and
dissolved oxygen were violated during the August 1974 survey.
A. Class A and B fecal coliform bacteria standards were violated
in several tributaries to the Bear River as well as in Worm
Creek.
B. The 90% dissolved oxygen standards were violated periodically
throughout the Bear River system over the last six years.
C. Dramatic increases in turbidity levels in the Bear and Cub
Rivers suggest water quality standards violations; however,
the standards are difficult to apply due to the wide range
of interpretations of the standard.
2. Recommended water quality criterion (1) of 0.05 ug/1 for mercury
(Hg) was exceeded throughout the entire reach of the Bear River
in Idaho. Based upon survey data, there is a possibility of a
mercury buildup in the bottom of Alexander Reservoir.
3. During the August 1974 survey, the chlorinated hydrocarbon pesticide,
Lindane, exceeded the recommended criterion (1) of .005 ug/1 in the
Bear River. The highest levels of approximately .010 ug/1 occurred
in the vicinity of the Bear Lake outlet.
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4. There has not been ample data collected since the 1958 Bear
River Enforcement Conference to adequately document the effective-
ness of pollution control actions resulting from the conference;
however, the following water quality changes are apparent:
A. Biochemical Oxygen Demand (BODS) levels have increased in the
lower Bear River and decreased in the Cub River following the
enforcement conference.
B. Total coliform bacteria levels generally are higher in the
Bear and lower in the Cub River for the post conference
period.
C. The reduction of BOD5 and total coliform levels in the Cub
River apparently resulted from installation of treatment
facilities at Del Monte Corporation.
5. The compliance monitoring evaluation of Monsanto Company showed that
the company was generally in compliance with the initial effluent
limitations as specified in their NPDES permit except for an
apparent violation of the discharge temperature stipulation.
6. High levels of total and fecal coliform bacteria were infiltrating
the Mud Lake area from the Paris, Idaho septic tank drainfield
during the survey period.
7. High levels of fecal coliform bacteria and the presence of some
pathogenic bacteria were documented in Worm Creek below the Preston
STP indicating poor disinfection of the STP effluent.
8. Nutrient loading of the Cub River in the Franklin area cannot be
reconciled with the Del Monte discharge; apparently an unknown inflow
in that area adds a large percentage of loading to the Cub River.
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9. The bacteriological data collected during the August 1974 survey
show that the domestic animal population along the Bear River has
a heavy bacterial impact on water quality. Livestock appears to be
the major source of warmblooded animal fecal contamination in this
portion of southeastern Idaho. Even though the pathogen recoveries
were more frequent near populated areas, the predominant source of
fecal waste contamination still appears to be animal in origin.
10. High total solids concentrations are predominant in the Bear River
basin. Most of the solids are dissolved with 20% to 30% of the total
being of organic nature. The solids increase significantly from the
Wyoming-Idaho to the Idaho-Utah border as the result of groundwater
and irrigation return inflow.
11. The greatest number of game fish caught in the Idaho Bear River
sustem occur from downstream of Soda Spring Reservoir to Grace
Powerhouse. The greatest catch per angler occurs in the area between
Grace Dam and Powerhouse where the only flow in the reach is from
groundwater inflow. These high catch reaches are characterized by
low turbidity and suspended solids. Alexander Reservoir apparently
settles out the suspended solids.
12. During the survey period point sources did not appreciably affect
water quality of the Bear River except in very localized areas.
Non-point sources from agricultural runoff and groundwater affect
the Bear River water quality to a greater extent.
The majority of the phosphorus in the Bear River Basin comes
from identifiable but non-controllable sources. The primary
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phosphorus sources are springs throughout the lower river from
Alexander Reservoir to the Utah-Idaho border and Mud Lake, Georgetown
Creek, Soda and Spring Creeks.
During the survey period considerably more phosphorus and
suspended solids were being discharged from the Mud Lake area than
were entering. This was probably due to scouring caused by the high
volume of discharge from Bear Lake. Mud Lake at the same time was
acting as a sink for organic material and N03-N.
13. The potential for nuisance levels of algal productivity exists
in the reservoir areas of the Bear River. High phosphorus, pH,
and alkalinity levels as well as 120% to 130% daytime dissolved
oxygen saturation levels indicate an insipient algal production
problem in the slack water areas of the basin. Periphyton
chlorophyll a_ levels below Grace Power Plant indicate that the
water in that area can presently be classified as mesotrophic.
Recommendat ions
1. Permanent monitoring stations should be established at the
following locations:
A. Bear River at the Idaho-Wyoming Border
B. Bear River just below Soda Springs Reservoir
C. Bear River near the Idaho-Utah Border
D. Cub River near the Utah-Idaho Border
Sampling should be minimally on a monthly frequency.
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2. The following studies are needed based upon the results of the
August 1974 water quality survey:
A. More extensive surveys to evaluate the vertical water
column and bottom muds of Alexander and Oneida Reservoirs.
B. Evaluation of water quality during the non-irrigation
season in the Soda Springs vicinity to determine effect of
the Monsanto discharge.
C. Diurnal studies during the late summer for dissolved oxygen
in selected areas of the Bear River to assess actual water
quality standard violations.
D. Studies or research to determine what, if any, agricultural
management practices could be used to reduce the turbidity
and nutrient loading in the Bear River system.
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BASIN DESCRIPTION
The Bear River, shown on Figure 1, drains approximately 6,800
square miles in three different states of which 2,350 square miles,
or 35 percent, is in the State of Idaho. The total length of the
river is approximately 500 miles; of which 160 miles, or 32 percent,
is in Idaho. After flowing some 500 miles from its source in the
Uinta Mountains of Utah and crossing state boundaries five times,
the river terminates in the Great Salt Lake, only 90 miles west from
its point of origin. Major tributaries to the Bear River in Idaho
are shown on Figure 1.
The Bear River Compact, approved by the U.S. Congress in 1958,
established a commission that administers the distribution of river
water among the states of Idaho, Utah, and Wyoming. The compact
stipulates the policy of the participating states to encourage additional
projects for the maximum beneficial use of the available Bear River
water.
The principal uses of water in the Bear River basin in order of
priority are hydroelectric power, irrigation, domestic, stock and
industrial purposes.
The Bear River enters Idaho near Border, Wyoming and flows in a
westwardly direction towards Stewart Dam where water is diverted by
canal into Mud Lake and then to Bear Lake. Bear Lake is approximately
70,400 surface acres in size and contains 1.4 million acre-feet of
water. The Lifton Pumping Plant located at the north end of Bear Lake
was constructed in 1914 to control the water level in Bear Lake and
thereby regulate flows into the Bear River for downstream power
generation and irrigation purposes. The pumping station contains no
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power producing facilities.
Between the north end of Bear Lake and the city of Soda Springs,
the river meanders through rolling farm and grazing lands. Near Soda
Springs the river enters a narrow channel which it has cut through the
lava. Alexander Reservoir, also called Soda Reservoir or Soda Point
Reservoir, and its associated hydroelectric plant are located in this
lava channel. The Alexander power plant was constructed in 1924, is
operated by the Utah Power and Light Company, and contains a total
installed generating capacity of 14,000 kilowatts. At capacity,
Alexander Reservoir covers approximately 1,007 surface acres and
contains 15,000 acre-feet of water.
West of Alexander Reservoir, the river passes Alexander Point
and makes a sharp turn to the south where it enters Gem Valley. In
Gem Valley, the river passes Last Chance Dam which is a mains tern
irrigation diversion structure: the river then flows into the Grace
Reservoir. Grace Reservoir was constructed in 1923 and contains
approximately 200 acre-feet of water at capacity. At the Grace Dam
the river water is diverted into a flume and sent cross-country for
approximately 4.5 miles to the Grace Power Plant. This facility was
constructed in 1923 and is operated by the Utah Power and Light Company.
It has a total installed generating capacity of 31,000 kilowatts.
From the Grace Dam to the Grace Power Plant, the river is located
in a steep walled canyon known locally as Black Canyon. When all river
water is being diverted at the Grace Dam, flows in the Black Canyon
consist almost entirely of spring water. It has been suggested that
springs which arise in the Black Canyon are the result of leakage
from the river between Alexander Dam and the Grace Dam.
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Immediately downstream from the Grace Power Plant is the Cove
Pond. At capacity, this pond is approximately five surface acres in
size and contains 25 acre-feet of water. It serves as an equalizing
reservoir and point of diversion for water which is used at the Cove
Power Plant located approximately two miles downstream. Water demands
by the Utah Power and Light Company's Cove Plant, which has an installed
generating capacity of 7,000 kilowatts, render the river virtually
unfishable between the Cove Pond and power plant.
Downstream from the Cove Power Plant, the river meanders through
Gentile Valley and Mound Valley and enters Oneida Narrows Reservoir near
the small community of Cleveland. Oneida Reservoir and associated
power plant is located in the upstream portion of a narrow canyon
(Oneida Narrows) which is about 11 miles in length. At capacity, the
reservoir covers approximately 480 surface acres and contains 11,485
acre-feet of water. This facility was constructed in 1920, is
operated by the Utah Power and Light Company, and has a total installed
generating capacity of 30,000 kilowatts. Water flows in the river
downstream from the dam vary daily, depending on power demands at high
flows. Because of this, fishing downstream of Oneida Reservoir is
virtually impossible.
Downstream from Oneida Narrows, the river enters Cache Valley and
leaves Idaho near the small community of Weston.
Figure 2 shows the hydrology of the Bear River at three stations
for a data period of 1969 to 1973. Maximum river discharge normally
occurs between March and July of each year ostensibly to satisfy
irrigation needs downstream. The large difference in flow between
maximum and minimum flows is the result of flow regulation at the dam
for power and irrigation purposes.
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FIGURE 2
BEAR RIVER HYDROLOGY
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Data Source:
Data compiled from USGS
streamflow records
Data Period 1969-1973
At Idaho-Wyoming
Border RM 2hQ.9
ccrr NCV TXC JAN FED rw* APR rv>v JLM JUL ALO SEP
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Below Alexander
Reservoir RM 169.0
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CJCT NCV oec JAN FEB rvj? APR rv>v JLN juu ALJC SEP
X=Min
M=Mean
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Near Preston
RM 97.3
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17
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PREVIOUS STUDIES
Following is a list of water quality or related studies that
have been conducted on the Bear River over the past twenty years:
1. In 1953, the States of Idaho and Utah conducted joint
bacteriological studies of streams in the Idaho-Utah border area.
More than 200 stream samples were collected at about fifteen stations
in this area and coliform organism numbers were determined. These
studies were made during March, June, and Sept., and consisted of a
one-week's series of samples and tests in each of these months.
2. In 1954, United States Public Health Service (USPHS) personnel
conducted a study of the Bear River and some of its tributaries from
the Idaho-Utah border area to its mouth. The purpose of this study
was to ascertain the effects, especially biological, of the cannery and
sugar refinery wastes on the stream. A one-week study was made in
August during the operating season of the canneries and another study
of one week was made in November when the sugar refineries were in
operation. In addition to detailed biological population analyses,
temperature, turbidity, pH, alkalinity, and dissolved oxygen were
determined.
3. From November 7 to December 9, 1955, a joint State-Federal
study of water quality and industrial waste characteristics was made
in the Idaho-Utah border area to obtain physical, chemical, and
bacteriological data which Utah could use in classifying streams and
ascertaining waste abatement needs. The study included analyses of
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10 samples from each of 14 stations. Stream flows also were determined
with the aid of the United States Geological Survey (USGS). Industrial
waste studies also were made at three beet sugar refineries and two
dairies. The 1955 study provided data which enables a reasonably
complete analysis of the problem during the sugar refining season.
4. Idaho Fish and Game Department (IFG) conducted a fish creel
census in the Idaho portion of the Bear River in 1972 and 1973. A
report titled "Returns of Planted Rainbow Trout, Fishing Pressure and
Catch in the Bear River and Fish Populations in Mains tern Reservoirs
and Tributary Streams" was published in June 1974.
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1958 BEAR RIVER ENFORCEMENT CONFERENCE SUMMARY
On October 8, 1958, the first session of a two session enforcement
conference on pollution of interstate waters of the Bear River was
convened at the request of the Utah Water Pollution Control Board. The
Surgeon General of the Public Health called the conference under
provisions of Section 8 of the Federal Pollution Control Act because
it was feared that pollution occurring in Idaho was endangering the
health and welfare of persons in the State of Utah.
At the conclusion of the first session, the conference unanimously
made the following conclusions and recommendations:
1. The Bear River is an interstate stream within the meaning of
the Federal Water Pollution Control Act.
2. The Bear River, as it flows back and forth from Wyoming and
Utah in the Evans ton area, may present a potential minor pollution problem.
3. Pollution of interstate waters subject to abatement under the
Federal Water Pollution Control Act is occurring in the Bear River and
its tributary, the Cub River, as they flow from Idaho to Utah.
Municipal and industrial wastes from Preston, Idaho, the Franklin Sugar
Company at Whitney, Idaho, and the California Packing Company at
Franklin, Idaho, are finding their way into the waters of the Bear River.
There they combine with waste from the Amalgamated Sugar Company at
Lewiston, Utah, the Cache Valley Creamery at Lewiston, Utah, the
community of Lewiston, Utah, the Sego Milk Company at Richmond, Utah,
the California Packing Company and the Rocky Mountain Dairy Company at
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Smithfield, Utah, the California Packing Company, E.A. Miller Packing
Company, L.L. Miller Packing Company and the Morning Mild Company at
Wellsville, Utah, the Community of Wellsville, Utah, and the City of
Logan, Utah, which are also finding their way into the waters of the
Bear River.
4. Such discharges from Idaho contribute to the pollution of
the Bear River so as to endanger the health and welfare of persons in
Utah, a State other than that in which the discharges originate. The
effects of this pollution are:
A. Deterioration of water quality used for irrigation and
stock watering so as to cause a potential health hazard.
B. Deterioration of water quality so as to interfere with
aquatic life and fishlife.
C. Deterioration of water quality so as to interfere with the
Cache River Basin area as a recreational area.
D. Deterioration of the river so as to make it unsuitable as a
potential source of public water supply.
5. The State of Utah, with the advice and assistance of the USPHS
was to gather information and data which would permit the State of Utah
to classify the waters of the Bear River under the Utah State Law.
The second session of the conference was held on July 19, 1960
and ended with the recommendation that representatives from the states of
Idaho and Utah meet and establish a time schedule for specific remedial
action by the municipal and industrial dischargers in the Bear River
area of concern.
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Shortly after the conference ended, Idaho obtained commitment
letters from the municipal and industrial dischargers and worked out
waste load allocation and agreements with the State of Utah.
Since the 1960 session of the conference, Franklin Sugar Company
closed down, and other significant dischargers have installed
treatment facilities.
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IDAHO WATER QUALITY STANDARDS FOR THE BEAR RIVER
According to Idaho's Water Quality Standards, the Bear and Cub
Rivers have been designated as primary contact recreational waters
(Class A). These are waters where the human body may come in direct
contact with the raw water to the point of complete submergence. The
raw water may be accidentally ingested and certain sensitive organs
such as eyes, ears, nose, etc. may be exposed to the water. These
waters may be used for swimming, water skiing, skin diving, support and
propagation of fish, aquatic and semi-aquatic life and other forms of
wildlife.
Worm Creek has been designated as secondary contact recreational
waters (Class (B). Class B waters are for uses in which the raw water
supply is suitable for support and propagation of fish and other
aquatic and semi-aquatic life, and other forms of wildlife. These
waters may be used for boating, wading, and other activities where
ingestion of the raw water is not probable.
The following Idaho Water Quality Standards apply to special
waterbodies of the Bear River Basin:
Bear Lake
1. Total Coliform concentrations were associated with a fecal
source(s) shall not exceed a geometric mean of 50/100 ml., nor shall
more than 20 percent of total samples during any 30 day period exceed
200/100 mg. (as determined by multiple-tube fermentation or membrane
filter procedures and based on not less than 5 samples for any 30 day
period).
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2. Fecal Coliform concentrations shall not exceed a geometric
mean of 10/100 ml., nor shall more than 10 percent of total samples
during any 30-day period exceed 20/100 ml.; or greater than 50/100 ml.
for any single sample. Coliform criteria for shoreline waters shall
conform with that of Class A2 waters. Shoreline waters shall be
defined as the first 100 feet of water surface as measured from the
shoreline.
Bear River and Cub River
1. Total coliform concentrations where associated with a fecal
source(s) shall not exceed a geometric mean of 240/100 ml., nor shall
more than 20 percent of total samples during any 30-day period exceed
1000/100 ml. (as determined by multiple-tube fermentation or membrane
filter procedures and based on not less than 5 samples for any 30-day
period).
2. Fecal coliform concentrations shall not exceed a geometric
mean of 50/100 ml., nor shall more than 10 percent of total samples
during any 30-day period exceed 200/100 ml.; or greater than 500/100 ml.
for any single sample.
Worm Creek Class B
1. Total coliform concentrations where associated with a fecal
source(s) shall not exceed a geometric mean of 1000/100 ml., nor shall
more than 20 percent of total samples during any 30-day period exceed
2400/100 ml. (as determined by multiple-tube fermentation or membrane
filter procedures and based on not less than 5 samples for any 30-day
period).
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2. Fecal Coliform concentrations shall not exceed a geometric
mean of 200/100 ml., nor shall more than 10 percent of total samples
during any 30-day period exceed 400/100 ml.; or greater than 800/100 ml.
for any single sample.
The following Idaho Water Quality Standards apply to the entire
Bear River Basin:
Bear Lake, Bear River, Cub River and Worm Creek
The dissolved oxygen D.O.) concentration not to be less than
6 mg/1 or 90 percent of saturation, whichever is greater.
1. The DO standard shall apply to all flowing waterways.
2. The DO standard shall apply to the waters of all natural lakes
and reservoirs except as excluded below:
a. In depths of water less than 100 feet in natural lakes or
reservoirs, the bottom 20 percent of water depth shall be
excluded from application of the DO standard. In water
depths greater than 100 feet, the bottom 20 feet of water
depth shall be excluded for application of the DO standard.
b. Waters below a thermocline in stratified lakes or impound-
ments shall be excluded from application of the DO standard.
c. No wastewaters shall be discharged and/or no activity shall
be conducted in waters excluded by a. and b. above, which
either alone or in combination with other wastewaters or
activities will cause the DO concentration in these waters to
be less than 4 mg/1.
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c. Notwithstanding exclusion of a. and b. above, the DO
standard shall always apply to the top two feet of any lake
or reservoir.
The hydrogen ion concentration (pH) values are not to be outside
the range of 6.5 to 9.0. The induced variations shall not be more than
0.5 pH units.
Any measurable increase when water temperature is 66 F or above,
or more than 2°F increase other than from natural causes when water
temperatures are 64°F or less (unless otherwise specified).
Any increase exceeding 0.5 F due to any single source, or 20 F
due to all sources combined.
For purposes of determining compliance, a "measurable increase"
means no more than 0.5^F rise in temperature of the receiving water
as measured immediately outside of an established mixing zone. Where
mixing zone boundaries have not been defined, cognizance will be given
to the opportunity for admixture of wastewater with the receiving
water.
The turbidity other than of natural origin shall not exceed 5
Jackson Turbidity Units (JTU). Whenever the receiving water is
greater than 5 JTU, due to conditions other than those caused by man,
then no discharge and/or activity either alone or in combination with
other wastewater or activity shall cause an increase of more than 5 JTU.
Water Quality Criteria (1)
Other W.Q. criteria are also of concern in the Bear River although
not defined in the water quality standards of the state. The following
are only recommended criteria based on research:
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1. Mercury
2. Cadmium
3. Chromium
4.
5.
Lead
Chlorine
.05 ug/1 aquatic life toxicity
10 ug/1 livestock water limit
.03 mg/1 (T. hardness
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WATER QUALITY TRENDS
The State of Idaho has been sampling the Bear River at five
stations each year on approximately a quarterly basis. Those stations
are:
1. At the Wyoming-Idaho State line R.M. 273.9
2. Near Montpelier downstream of the Bear Lake Outlet Canal
Confluence R.M. 219.3
3. At Soda Spring, Idaho (Above dam) R.M. 174.4
4. Near Grace, Idaho below Grace Power Plant R.M. 156.6
5. Near Preston, Idaho R.M. 97.3
Figures 1A through 11A (Appendix A) show plots of Dissolved
Oxygen (D.O.), D.O. saturation, alkalinity and orth-phosphorus
concentrations data collected from 1969 to the present time for these
stations. Basically, for the parameters shown there has been very
little change in water quality conditions in the Bear River in the
last six years neither in time nor over the length of the River.
Although standards were generally attained, water quality violations
for D.O. were documented at Montpelier, Soda Springs and Preston
stations over the six year period. Alkalinity, phosphorus and pH levels
which are high throughout the six year period throughout the river
system are indicative of high algal blooms condition which occur in
predominately agricultural areas. The ortho-phosphorus levels shown
on Figures 4A and 8A are considerably greater than the .025 mg/1 P04
which is considered a minimum requirement for an algal bloom.
Water quality of the Cub River and Worm Creek; like the Bear
River, has not changed appreciably over the last six years. Figures
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12A and 15A show the ambient monitoring data collected by the State
of Idaho on a quarterly basis over the period. All data suggests a
high level of algal activity. The high D.O.'s were obtained during the
daylight hours during the period when algae are undergoing photosynthesis
and, therefore, supersaturate the water with D.O. No D.O. data is
available during early morning or night when D.O. levels would be the
lowest. The pH levels on Cub River in 1973 exceeded the upper limit
of the Idaho Water Quality standards again indicative of high algal
activity.
Table IA (Appendix A) shows a comparison of the pre-enforcement
conference (1954-1955) data collected in Idaho with the data collected
since the enforcement conference. The post-enforcement data is a
compilation of State of Idaho ambient monitoring data and EPA intensive
survey data. Available data was selected for two periods to conform to
the winter and summer food processing seasons. Those periods were
November through December and July through September. The EPA intensive
survey was conducted during the summer food processing season only, since
the main winter industry cited during the enforcement conference,
Franklin County Sugar Company, closed shortly after the conference.
There is not ample data available either before or after the
enforcement conference to document changes conclusively, but the
following indications are noted:
1. NOV-DEC period
Bear River
1. There appears to be higher levels of 5-day Biochemical
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Oxygen Demand (BODS) in the river since the enforcement
conference although the D.O. levels don't reflect that
increase. The unexpected high D.O. levels are probably
due to high reareation rates typically found during
November and December.
2. Total coliform populations are apparently greater during
post enforcement period times than before. This difference
is not significant due to the analytical techniques used.
Cub River
1. Instream BODS levels are significantly less following the
enforcement conference than prior to it. This is due to
the treatment installed at Del Monte Cannery following the
conference.
2. JULY-SEPT. PERIOD
Bear River
1. Instream BODS levels are greater following the conference
than before. This increase is reflected in the lower D.O.
concentration reported on several occasions following the
conference and including the values from the EPA intensive
survey in 1974. This higher BODS and lower dissolved oxygen
levels in the river could be due to a greater amount of
algal activity in the river system resulting from
increased agricultural activity in the basin.
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2. Total coliform levels reported by Idaho appear to be
considerably greater than prior data showed; however,
total coliform data during a three day period shows the
level to be very low. No conclusions can be drawn from
this information.
Cub River
1. There appears to have been an improvement in the water
quality in the Cub River during this time of the year.
The BODS level reduction between the comparative periods is
greater than appears because the stream flow is small. The
meager post enforcement conference data indicates that the
D.O. level is higher and the bacteria levels are lower in
the reach below Del Monte Cannery. This is to be expected
since treatment facilities have been installed and the BOD
levels have dropped.
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AUGUST 1974 SURVEY
SURVEY DESCRIPTION
The Bear River in Idaho cannot be adequately studied as one
continuous river because major river diversions, inflows, and im-
poundments are located throughout the river which alter the river
characteristics and make it function as nearly independent segments.
For the August 27 thru 29 Bear River survey, the river was
divided into the following four independent reaches:
1. Bear River between the Wyoming-Idaho border and Rainbow
Inlet to Mud Lake. R.M. 274.5 to R.M. 232.0
2. Bear River between the Bear Lake Outlet and Grace Dam
R.M. 220.5 to $.M. 164.0
3. Bear River between Grace Power Plant and Oneida Dam.
R.M. 157.0 to R.M. 126.0
4. Bear River between Oneida Dam and the Idaho-Utah border
R.M. 126.8 to R.M. 93.8
Mud Lake and the Idaho portions of Cub River and Worm Creek
were also analyzed separately since they function independently.
A reconnaissance trip was made to the basin by EPA personnel
for the purpose of locating sampling points, measuring flows, placing
macroinvertibrate samplers, and working out logistic problems. It
was decided to sample the river daily for three consecutive days,
the tributaries, drains and springs would be sampled only once since
these flows are relatively constant. The reach of river between Oneida
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Reservoir and the Utah-Idaho border had to be sampled early in the
morning to obtain a sample at constant flow. The reservoir is used
for power peaking and the flow fluctuates rapidly over the day. The
reservoir release, however, is held fairly constant overnight and is
not increased until about 8 or 9:00 each day. The sampling procedure
was to sample just below this darin at about 6:00 each morning and
work in a downstream direction completing the last station near the
stateline before the raising flow reached the downstream station. The
res Its of this study reach cannot be analyzed with the rest of the
river since the flows are considerably lower than the rest of the
river.
An automatic sampler was placed near the Idaho-Utah state line so
that diurnal fluctuations in river quality could be determined over
a 48 hour period. Samples were collected and analyzed at two hour
increments over the period for turbidity, specific conductance,
nutrients, and organic carbon.
Table IB (Appendix B) lists and the map on Figure 3 shows the
survey sample locations. Figure 4 is a map showing all survey flow
meausrement locations for the study area.
All river, tributary and spring samples were collected using
the following procedures:
1. Samples were collected using a Kemmer sampler or by sample
cubitainer.
2. Specific conductance, ph and temperature were analyzed
at the sample site immediately. Samples collected for shipment
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to the main EPA lab were preserved, tagged and iced on the
site.
3. Dissolved oxygen samples were fixed at the site, iced and
taken to the field lab in Preston for titration.
4. Samples for alkalinities and turbidity were taken to the
field lab for analysis.
Flows were obtained by one of the following methods: reading
river stage recorder charts that correspond to sample time then
determining flow using a rating curve; obtaining flows from a water
master or; measuring the flow using a gurley current meter.
Samples for pesticide analysis were collected in the water
column in one (1) gallon glass jars and capped with teflon lined lids.
The jars were kept in the dark and shipped to the Redmond, Washington
lab for analysis.
Benthic macroinvertebrate samples were collected using artificial
substrates of the rock-basket type. The substrates were exposed for an
eight week period (August through September 1974) at representative
sites on the Bear River. At the end of the eight week period, the
colonized substrates were removed and the macroinvertebrates were
scraped from the substrate into a jar containing a 70% ethanol
solution. The samples were then shipped to the Redmond Laboratory
where they were sorted, counted and identified by genus and species
where possible. This information was used to calculate a species
diversity index (DBAR) and species density.
Periphyton chlorophyll j. determinations in the flowing water
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SAMPLING STATION LOCATIONS
AUGUST 1974 BEAR RIVER SURVEY
1-18 Mainstem
20-50 Tributaries
51-57 Springs
SCALE OF MILES
10
FIGURE 3
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FLOW MEASURING LOCATIONS
BEAR RIVER BASIN
O Read Gage
^ Measure Flow
Contact Water Master
fa Estimate Flow
ivcrdoU X I
\ N (v-r, i N .
In;
SCALE OF MILES
10
FIGURE 4
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portions of the Bear River were obtained by exposing artificial sub-
strates (glass microscope slides mounted in partially submerged wood
frames). The slides were removed from the frames after an exposure
period of eight weeks. The slides were frozen in dry ice and shipped
to the Redmond Laboratory for spectrophotometric analysis.
Bacteria samples were collected and analyzed as follows:
All samples were collected according to standard methods (2)
in sterile polyproplyene screw-cap bottles with aluminum foil hoods.
To each bottle 0.5 ml of a 10% solution of sodium thiosulfate was
added prior to sterilization.
Stations exhibiting a fecal coliform values greater than 150/100 ml
were sampled an additional time. Bacteriological analyses of these
samples were expanded to include Pseudomonas aeruginosa and
Staphylocoecus aureus.
Total coliforms, fecal coliforms and fecal streptococci were
determined using the MF technique in accordance with standard methods
(2), the medium selected for fecal streptococcus (Lancefield's Group D
Streptococcus) enumeration was KF streptococcus agar with 1% TTC added.
Quantatitive tests for S. aureus and P. aeruginosa were also
performed. The former organism was isolated by the MF procedure on
m-Staphylocoecus broth and confirmed by coagulase-testing and DNase
activity. P. aeruginosa was isolated on m-PA agar according to the
method of Levin (3). Verification of suspected colonies was accomplished
by observations of casein hydrolysis and fluorescent pyocyanin pigment
production of milk agar.
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Effluent samples from all significant wastewater sources were
collected concurrent to the receiving water sampling. Municipal and
Industrial samples were collected using automatic composite samplers
that were located in the discharge line. Samples were collected by
the automatic samplers on 15 minute intervals over a 24 hour period.
A grab sample was taken at the Del Monte Plant in Franklin, Idaho
since they have a lagoon treatment facility which characteristically
produces an effluent of uniform quality.
All samples were collected in 1 gallon polyethelene containers
and then split into individual containers for the various analyses
that were needed. Preservatives were added to the samples according
to standard EPA methods. Samples for BODS analysis were taken from
the 24 hour composites, iced and shipped to the EPA laboratory at
Redmond, Washington. Settleable solids analysis using the Imhoff Cone
method were run the same evening of sample collection.
The BODS samples were set up immediately upon arrival at the EPA
Redmond laboratory and all other samples were anlayzed according to
their perishable priority. All samples were preserved and analyzed
using standard EPA methods.
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AUGUST 1974 INTENSIVE SURVEY RESULTS
Hydrology
Flow determinations during the survey were made by either 1-Reading
USGS or Utah Power Co. existing gages, 2-Actual flow measurement, 3-flow
determined by water master, and 4-flow estimation. Table lib shows the
actual values. The locations of the stations are shown on Figure 4.
The flow conditions existing at the time of the survey are discussed
separately in the following paragraphs for the Bear River, Cub River and
Mud Lake.
River Hydrology:
Figure IB is a stick diagram showing locations of the tributaries,
diversions and irrigation returns that were significant during the three
day survey period.
The curves on Figure 2B show the flow along the Bear River in Idaho
for the three day study period of August 27,28 and 29th. The points
on the figure represent instantaneous flow corresponding to sampling
times.
Flows from R.M. 233 to 220 are minimal (approximately 5 to 10 cfs.),
therefore, the river actually begins again downstream of the Bear Lake
outlet confluence with the Bear River R.M. 15.9. The flows again are
minimal below Grace Dam at about R.M. 167. The only flow in the reach
from R.M. 167 to R.M. 156 or about 11 miles is from spring water. River
flow fluctuates considerably below Oneida Reservoir due to varying
power demand; therefore, the flow shown in the figure from R.M. 130
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to the stateline is for a minimum release flow and cannot be compared
to the upstream flows.
The Bear River flow is supplemented by groundwater throughout
the entire river reach in Idaho with most occurring in the stretch
of river from Alexander Reservoir to the stateline in the form of
springs. Hot springs are abundant in the lower reach from approximately
R.M. 150 to the stateline.
Cub River Hydrology:
The majority of the flow is diverted at Cub Canal diversion
during the irrigation season. The Cub Canal diversion takes off at
approximately R.M. 20.9 on the Cub River. Flow in Cub River during the
August 1974 survey period, as shown in Figure 3B, at 40 cfs just down-
stream of the diversion. The river slows through agricultural land and
appears to lose substantial flow to ground or diversions until it
reaches Franklin, Idaho. Flow in the Cub River just upstream of
Franklin (R.M. 16.5) was measured at 7.8 cfs. The next point of
measurement was downstream of the Del Monte discharge at R.M. 15.1.
Flow at that point was 22.5 cfs. The source of this inflow between the
two flow measurement points is unknown. Worm Creek enters the Cub
River at approximately R.M. 7.9. During the survey period approximately
12 cfs was measured in Worm Creek leaving Idaho and presumably entering
the Cub River in Utah.
A "stick diagram" showing the inflows to and outflows from the
Cub River is shown on Figure 4B.
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Mud Lake Hydrology;
Mud Lake is located in the Bear Lake National Wildlife Refuge
which is directly north of Bear Lake. Mud Lake is supplied by the Bear
River via Rainbow Canal behind Stewart Dam. This water may be released
from the canal for storage in Mud Lake or released directly into the
Bear Lake outlet canal. The water from Mud Lake is diverted into Bear
Cake by a sluiceway at a pumping plant or by gates in a causeway at the
south end of Mud Lake if supplemented water for storage is needed in
Bear Lake. Bear Lake, as an offstream reservoir is operated by the
Utah Power and Light Company for power, downstream irrigation and
maintenance of favorable flow conditions in the Bear River.
Other inflow sources to Mud Lake are Bloomington Creek and small
irrigation return flows from the west as well as Crockett and Black
Otter canals from the east.
Figure 5B is a "stick diagram" of the flow condition that
existed during the August 27,28 and 29, 1974 survey period. Table IIIB
contains the inflows and outflows that occurred during the survey period.
During that period, approximately 900 cfs were flowing from Bear Lake
into the Bear Lake outlet canal which runs through Mud Lake. Comparing
the inflow and outflow, it appears that approximately 86 cfs are
entering Mud Lake through groundwater or unaccounted for passages.
This difference, however, is small and could partly be accounted for
by the variance in accuracy of the flow measurement.
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Point Source Dischargers
Table IVB shows the Organic and nutrient loadings in the basin,
while Tables Vb and VIb, show the point source data collected from
the main municipal and industrial dischargers in the Bear River Basin.
The data represented is for average values during the August survey
period and is based upon a 24 hour composite for all sources except
the Del Monte Corporation discharge which has a lagoon treatment system
and the Caribou Trout Farm which has a continue s discharge. Grab
samples were taken from these discharges.
All sewage treatment plants discharge into either the Bear River,
or its tributaries. The effects of these discharges upon the receiving
water are minimal for the most part; however, any noticeable effects
will be discussed in the following sections.
Monsanto Corporation discharges into Soda Creek which is
essentially an irrigation canal during the irrigation season. Very
little if any of their discharge enters the Bear River system during
the irrigation season; however, it is not known how much enters the
Bear River system during the remainder of the year. The discharge
sampling program for Monsanto corresponds with a compliance monitoring
evaluation which was completed concurrently. The compliance monitoring
evaluation report is included in the Appendix of this report.
Caribou Trout Farm utilizes spring water, supplemented by Little
Spring Creek water for their operational water supply. Their discharge
is into Little Spring Creek near its confluence with the Bear River
in the backwater of Alexander Reservoir.
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Del Monte Corporation discharges into the Cub River during food
processing season. The effect of this waste on the receiving water
will be discussed in the following sections.
Gem Valley Cheese is a small operation below Grace power plant.
Loadings could not be calculated because flow from the plant is inter-
mittent and could not be measured during the survey; however, discharge
constituent concentrations were determined and are included in the
tables. A compliance evaluation was made at this plant also but no
report was prepared due to the small size of the operation.
Water Quality Standards Violations
The August 27,28 and 29 intensive survey data shows that although
very few water quality standards were violated technically, values
were either very close to limits or not enough samples were taken to
support the numerical criteria of the standards.
Coliform Bacteria
Only three samples at each main river station were collected
during each day, therefore, not enough samples were collected to
apply the Bear River water quality standards. However, there is no
reason to believe that total bacteria levels would not be violated if
enough samples were taken. Figure 6B shows the bacteria results in
the Bear River and the water quality standard levels for both total
and Fecal coliforms.
Fecal coliform levels found on the survey exceed the Class A
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single sample criteria of 500/100 ml. for the Bear River tributaries
of Montpelier Creek, Stauffer Creek, a spring near Preston, and a
creek north of West Pump Canal. These are tributaries to the Bear
River and, therefore, are subject to the same standards. Class B
waters of Worm Creek had single sample violations (800/100 ml.) at
Worm Creek below the Preston STP and again near Franklin, Idaho.
Bacteria levels for these tributaries, as well as other tributaries
in the basin are shown on Table VIIB.
Dissolved Oxygen
All samples for dissolved oxygen analysis were taken during the
daylight hours, therefore, they probably would not reflect the lowest
values that would occur in the river system. However, one value is at
the lower limit of acceptable concentration. Diurnal studies would
have undoubtedly shown violations of Water Quality Standards for
dissolved oxygen concentration.
Figure 7B shows actual daytime dissolved oxygen concentrations as
well as percent saturation values by river mile for the mains tern of the
Bear River. The 6 mg/1 concentration standard is not violated, although
the limit is approached in the Montpelier area. However, the 90 percent
water quality criteria is violated at several points along the Bear
River. The most notable area is in the Oneida Reservoir area. The
90% criteria is violated from approximately R.M. 140 in Oneida
Reservoir to the Utah-Idaho border. Greater than 100 percent D.O.
saturations are indicative of photosynthesis by algae and occurs
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during the daylight hours. These same algae respire at night
driving the D.O. levels below the 100% saturation level. Percent
saturation levels of 120 to 130 percent normally means night time levels
would be much lower than 90% and, therefore, concentrations would be below
the 6 mg/1 levels.
Based upon the above discussion, the magnitude of dissolved
oxygen violations would probably be greater and cover a greater portion
of the river if samples were collected during the early morning hours.
Turbidity
Idaho Water Quality standards state that a 5 JTU increase above
background level of turbidity is a violation of Idaho water quality
standards. The JTU value of Bear River water entering Idaho from
Wyoming is around 10 JTU, therefore, any change of 5 JTU's other
than natural would be a violation. Irrigation downstream from the
Idaho-Wyoming border changes the turbidity level, shown in Figure 8B,
drastically, resulting in Water Quality Standards violations from about
the Bear Lake diversion (R.M. 242.7) to Alexander Dam (R.M. 169.4).
Alexander Reservoir apparently acts as a settling basin, thereby re-
ducing the turbidity levels again to the initial levels. Idaho water
quality standards for turbidity in the Cub River were violated during
the August EPA survey. Turbidity levels of the Cub River (Figure 9B)
increased from less than 3 JTU upstream of the Del Monte discharge to
about 11 JTU below the discharge, constituting an increase greater
than 5 JTU due to man's activity.
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pH levels in the Bear River (Figure 10B) and Cub River (Figure 11B)
did not violate water quality standards during the survey period;
however, the levels are near the upper levels of the standard.
Cause and Effect Discussion
Bear River
Recreation
The health of a stream can be determined non-technically by
looking at the actual recreational use of that stream. Figures 12B
and 13B show the areas in the Bear River that successful fishing has
been taking place as well as the numbers of fish that have been caught.
(4) Limited fishing takes place between the Bear Lake outlet and Oneida
Reservoir; however, the best fishing areas occur in the stretch of
river from Alexander Dam to Grace Dam and in the area of Grace Dam to
Grace Powerhouse where only a minimal flow due to river discharge
occurs. The River is diverted at Grace Dam through a pipeline system
to Grace Dam and the only flow in that reach is due to groundwater
inflow.
Invertebrate Population
The benthic macroinvertebrate community also indicates the health
of a stream. Unpolluted streams for the most part contain a biologic
community with a high species diversity. Polluted waters support a
community of low species diversity.
The species composition of the benthic macroinvertebrate community
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in the Bear River is dominated by those organisms which are
facultative in their tolerance to organic pollution. The diversity
index calculations (See Figure 14B) further substantiate this
contention by indicating moderately polluted water throughout the
Bear River study reach. Diversity index of 3 or above is indicative
of a healthy community. (5)
Heavy Metals
Figures 15B to 17B depict heavy meatls concentrations throughout
the Bear River system. Toxicity levels shown on the curves are from
the "1972 Water Quality Criteria" (1). Hardness as CaC03 (Figure 18B)
is also included here since toxicity is related to the water's hardness.
The heavy metals curves are dashed denoting that samples were taken
only at selected points, not at all stations.
Bear River water is hard entering Idaho, it's CaC03 concentration
is about 250 mg/1. Water from Bear Lake outlet canal that makes up
the Bear River water just downstream of Montpelier has a hardness
level on the order of 300 mg/1 and the level gradually rises in a
downstream direction due to groundwater and surface water inflow
(See Table VIIIB for chemical constituents of these inflows). Figure
15B depicts the total mercury concentrations in the Bear River. The
curve shows that the levels of these constituents recommended safe
for aquatic life are exceeded throughout the entire Idaho reach of
the river. The levels decrease considerably in Alexander Reservoir
indicating that the Reservoir is concentrating Hg in it's bottom
muds. Zinc and Cadmium levels are low in the basin (See Figures 16B
and 17B).
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Algal Bloom Potential
River mile graphs shown on Figures 19B through 22B represent the
potential of the Bear River to support massive algal blooms. Phosphorus
concentrations (Figure 19B) during the 3 day EPA survey exceeded the
.05 mg/1 (6) level considered minimum needed for algal blooms. Total
phosphorus levels exceed this level for the entire length of the
river while nitrate-nitrogen (Figure 20B), another required nutrient,
never exceeded its 0.3 mg/1 (6) level. However, blue-green algae have
the ability to fix nitrogen from the atmosphere.
High total alkalinity (Figure 21B) and pH (Figure 10B) values
support the potential for algal blooms. Total alkalinity values like
hardness discussed earlier constantly increase through the river system,
and the pH levels are near 8 most of the time indicating that
bicarbonate alkalinity exists, thereby indirectly furnishing carbon
dioxide for plant growth.
Periphyton samplers were placed at several locations on the river
for the purpose of collecting samples for chlorophyll a_ analysis;
however, only four samplers were recovered. Chlorophyll _a results
(Figure 22B) from these samples show that chlorophyll a^ levels are
below the 10 mg/wr level which is considered a eutrophic threshold
(7). Chlorophyll level at one station below Grace Powerhouse was at 5.5
mg/rn^ which shows that the water was in a mesotrophic condition in
this area. Oneida Reservoir was observed to have heavy algal growth
occurring during the survey. The low chlorophyll value near Preston
cannot be explained by the survey results. Even though phosphorus
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levels are low in that area during low-flow, the diurnal fluctuation
of phosphorus concentrations (Figure 23B) appear to be directly related
to flow and greatly exceed algal productive levels. Another possibility
is that during the low flow period, debris floating down the river
catches on the samplers, thereby limiting sunlight.
Dissolved oxygen concentrations and percent saturation values are
shown on Figure 7B. These samples were collected during the day and,
therefore, reflect the photosynthesis produced dissolved oxygen by
algae in these areas where productivity is the greatest. Saturation
values reach 120 to 130 percent between Soda Springs and Oneida Reservoir.
Saturation values greater than 100% are indicative of photosynthesis.
Nutrients
Figures 24B and 25B show the relative total phosphorus and total
nitrogen nutrient loading to the Bear River in terms of ///day as well
as loadings from the sources. The survey results show that in the
upper rivers considerable phosphorus has been picked up in the Mud
Lake area (the relative contribution in the Mud Lake reach will be
discussed in a later section).
Other measured sources of phosphorus which effect the Bear River
are Georgetown and Soda Creeks. Both tributaries flow through
populated and agricultural areas; however, samples of groundwater in the
Georgetown area (See table VIIIB) showed total phosphorus concentrations
of about 0.1 mg/1 and most of Georgetown Creek water is composed of
groundwater. Soda Creek is high in total phosphorus mostly resulting
from irrigation water reuse in the Soda Springs area. Phosphorus
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below Grace Power plant is due to mainly groundwater. Springs
sampled between Soda Springs and Oneida Reservoirs (Table VIIIB) show
total phosphorus concentrations of .17 mg/1.
o
Major nitrate nitrogen (NO -N) loadings in the River Basin are
from Georgetown, Big Spring and Soda Spring creeks in the Reach
between Mud Lake and Alexander Reservoirs. Again springs sampled in
this reach show groundwater (approx. 3.4 mg/1) the main reason. In
the reach between Alexander and Oneida Reservoirs Whiskey and Trout
Creeks have measurable contributions; however, groundwater is the
main reason for the high concentrations. Groundwater NO-^-N
concentrations in this reach range between .09 mg/1 for hot springs
to 3.0 mg/1 for cold springs. Diurnal NO-^-N measurements taken at
R.M. 104.3 on the Bear River near Preston and shown on Figure 26B
show that Nitrogen concentrations vary from 0.1 mg/1 at high flow to
0.17 mg/1 at low flow. This data shows that groundwater is a main
contribution to nitrate nitrogen in this portion of the River.
Solids
Figure 27B shows the total, dissolved and volatile solids in
the main stem of the Bear River.
There is a substantial increase in total solids concentrations
in the Bear River from the Wyoming-Idaho border to the Utah-Idaho
border. The increase is fairly constant throughout the study reach.
The majority of the solids is in the form of dissolved solids and
approximately 20 to 30% of the total solids are of organic nature.
Suspended solids concentrations (Figure 28B) are minor compared to
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the other forms of solids. However, suspended solids levels coincide
with turbidity levels (Figure 8B) and affect the fishing to a greater
extent than other forms of solids. The lower suspended solids and
turbidity levels coincide directly with the highest fish catch levels
in the Bear River (Figure 12B). Survey data (See Appendix C) show
that spring water turbidity levels are minimal and since spring water
makes up part of the flow in the Bear River below Alexander Reservoir,
the ground water dilution plays an important role in this stretch.
High dissolved solids are representative of groundwater inflow and
agricultural runoff. Specific conductance has a relationship to Total
Dissolved solids. When the total dissolved solids level is less than
2000 mg/1, the T.D.S. level is approximately .6 to .7 times the specific
conductance level. Figure 29B shows the conductivity levels in the
Bear River. The conductivity-T.D.S. relationship described above holds
true for the river. Table VIIIB shows the specific conductance for
the tributaries and groundwater inflows for the various reaches of the
Bear River. The data shows that the first major increase in con-
ductivity occurs downstream of the Bear Lake outlet canal. The canal
water itself measures nearly 700 umho/cm. Major inflows of ions occur
in the Soda Springs area and downstream via Big Springs, Soda and
Whiskey creeks as well as all hot and cold springs flowing into the
River. The spring inflow conductivity range from 900 to 1400 umho/Cm.
Bacteria
Figure 6B shows river mile plots of total and fecal coliform
bacteria along with fecal streptococci (strep) for the Bear River
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and its tributaries. Figure 30B shows the relationship ratio of
fecal coliform to fecal streptococci bacteria. Large fecal strep
densities represent bacteria from agricultural sources and low fecal
strep densities associated with higher fecal coliform densities represent
evidence of domestic sources of bacteria. A mean FC/FS ratio of 2.0
from samples strongly suggests bacteria from a domestic source while
a ratio of 0.7 or less strongly suggests animal sources of bacteria.
A ratio between 1.0 and 2.0 indicates an uncertain source of bacteria
contamination. However, this does not mean bacteria from domestic
waste is not present only that there is a predominance of animal waste.
The complete bacteria survey data is included in Appendix B.
Downstream from the Wyoming border to Montpelier all three
bacterial indices increased progressively reflecting a loading due to
increased agricultural use. From Montpelier to Soda Springs all
bacterial counts were quite variable with no discernable pattern.
However, from Soda Springs to Preston all three indicators reflected
bacterial loading due to a combination of agricultural runoff and/or
domestic use.
The FC/FS ratio for the Bear River were all lower than the .7
value indicating a predominance of bacteria of farm animal origin.
However, high FC/FS ratio were detected on Ovid, Montpelier and Soda
Springs Creeks which suggest possible bacterial contamination from
human sources.
High bacterial levels were found in a spring located south of
Oneida Rd. West of Preston (Station 153587). Total fecal and fecal
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strep, populations were 10,000, 2,700 and 7,800 per 100 ml.
respectively indicating contamination of the spring probably from a
livestock source since the FC/FS ratio was about 0.4.
Table IXB summarizes the bacterial pathogen data. Coagulase-
positive _S_. aureus was found in 8 out of 13 (62%) samples examined.
High numbers of this organism were found in Montpelier Creek; Bear
River, Trout Creek, Williams Creek near Thatcher; Bear River near
Fairview and at Upper Canal near Fairview. The presence of these
pathogen in water suggests pollution from a human rather than animal
source.
Pesticides
Table XB shows the results of pesticide analysis at selected
stations in the Bear River Basin. Many other chlorinated hydrocarbon
and organophosphate parameters were analyzed; however, only those shown
on the table were above the analytical threshold.
Lindane (BHC) levels exceeding 0.005 ug/1 were equalled or exceeded
at all but three locations sampled in the basin. The recommended
toxic level for BHC is considered to be .005 ug/1 according to Water
Quality criteria. (1) Detectable levels of DDD, DDE, DDT and Lindane
were found only in the reach above the confluence of the Bear River
and the Bear Lake outlet. The levels of these parameters were below
detection limits in the Bear Lake outlet which makes up the majority
of flow below that point and, therefore, has an overwhelming influence
on the character of the river flow during this time of year. It
appears that most of the conservative pesticides are entering Idaho
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from Wyoming. The toxic levels for DDD, DDE and DDT are considered
to be approximately 0.05 ug/1.
Mud Lake
Table VIIIB shows the concentration of various constituents of
the inflows and outflows to Mud Lake and Table XIB contains nutrient,
organics and bacteria loading in the Mud Lake area. It appears that
twice as much phosphorus is leaving the Mud Lake area as entering. The
same ratio of suspended solids is leaving Mud Lake also. The reason
for this transport out of the area was probably the high discharge
(900 cfs) from Bear Lake scouring the sediments in Mud Lake that were
deposited during a lower flow portion of year. Since phosphorus
absorbs into soil particles, the phosphorus levels are also transported
out of Mud Lake; therefore, during the survey period, Mud Lake was a
source of suspended solids and phosphorus.
Nitrate nitrogen and total organic carbon (TOG) were reduced
through Mud Lake; therefore, Mud Lake is functioning as a sink for
these constituents.
Drainage from the Paris, Idaho septic tanks is main contributor
of total fecal bacteria to the area; however, the high flow down the
Bear Lake outlet canal dilutes the small amount of concentrated
waste so that the bacterial levels entering the Bear River are less
than 100/100 ml. A new treatment plant for Paris was under con-
struction during the survey period; therefore, the high bacteria levels
should be drastically reduced in the near future.
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Cub River
The Cub River was sampled at three locations along a six mile
reach. The three stations were at the Cub Canal diversion dam
(R.M. 20.9), at R.M. 16.5 just upstream of the community of Franklin,
Idaho and at R.M. 15.1 just below Franklin and the Del Monte discharge.
Results of the study are shown on Figures 31B through 36B and
Table XIIB.
This table shows the nutrient loadings in the Cub River. Total
phosphorus, nitrate and ammonia loadings have been reduced between
R.M. 20.9 and 16.5. Water use for agricultural purpose may be the
reason. The increase in loadings between R.M. 16.5 and 15.1 cannot be
explained by the discharge from Del Monte alone. In the 1.4 mile
reach the Cub River receives approximately 12.5 CFS flow, 18.5 Ig/day
of phosphorus, 30 Ib/day N03-N, and 57.5 Ig/day of NH3-N which is
unaccounted for. This area should be investigated further for additional
waste sources.
Bacterial densities on the Cub River as well as the FC/FS ratio
for the study reach are given on Table XIIB.
Del Monte discharges a high level of bacteria into the Cub River;
however, the samples taken approximately 1/2 mile downstream of the
discharge do not reflect the high densities. The dilution effect
of the additional flow in that reach and the die-off could help
explain this.
-55-
-------�
Cattle observed watering in the Cub River between R.M. 20.9 to 16.5
are probably the reason for the high fecal strep densities of 1600/100
ml. sampled at the lower station.
FC/FS ratios shown on the table strongly indicate bacterial
contamination caused by animals.
There is another discharge between the Del Monte discharge and
the downstream sample station. It appears the discharge is irrigation
return flow; however, access to this area is difficult and could not
be sampled. This could be the reason for the discrepancy.
Worm Creek
Samples were taken from Worm Creek at locations just above the
Preston sewage treatment plant outfall (R.M. 9.9) and approximately
0.8 miles downstream of the outfall. Twenty-four hour composite
samples were also taken from the Preston STP outfall concurrently as
part of the point source sampling program. Table XIIIB shows the
sample results.
The general quality of Worm Creek has not deteriorated much as
the result of the Preston sewage treatment plant. In fact, in some respects
the discharge has improved the water of Worm Creek.
However, during the August 1974 survey high levels of bacteria
were observed in the discharge of Preston STP as well as Worm Creek
Immediately downstream and as far as 0.8 miles downstream from the
outfall. Fecal counts as shown on the table, increase from 90/100 ml.
upstream of the outfall to a high of 50,000/100 ml. just downstream
-56-
-------�
and are still high (870/100 ml.) at the downstream sample point.
Pathogenic bacteria E. aeruginosa (40/100 ml) and S. aureus (200/100 ml.)
were detected in Worm Creek below the Preston sewage treatment plant.
Although the numbers of these pathogens are not extremely high, their
presence is indicative of poor disenfection practices.
Fecal bacteria levels from Preston STP were on the order of
100/100 ml. which does not account for the high level in the stream;
however, STP samples were taken August 28 and Worm Creek samples were
taken on August 29th which could account for the bacteria differences.
During this period the operator at Preston STP was having trouble with
the chlorination equipment.
-57-
-------�
BIBLIOGRAPHY
1. 1972 Water Quality Criteria - National Academy of Science -
National Academy of Engineering - Washington
2. American Public Health Association. 1971. Standard methods
for the examination of water and wastewater, 13th Ed.
APHA, New York.
3. Levin, M.A. and V.J. Cabelli, 1972. Membrane filter
technique for enumeration of Pseudomonas aeruginosa.
Appl. Microbiol. ^4: 864-870
4. Return of Planted Rainbow Trout Fishing Pressure and
Catch in The Bear River and Fish Populations in Mainstem
Reservoirs and Tributary Stream, Idaho Fish and Game,
Heimer, John T. 1974.
5. Biological Parameters For Water Quality Criteria,
Bioscience Vol. 18, No. 6, Wilhm, Jerry L. and
Dorris, Troy C. 1968
6. Report of The Committee on Water Quality Criteria. FWPCA,
National Technical Advisory Committee to the Secretary
of the Interior April 1, 1968.
7. Biological Field and Laboratory Methods for Measuring
The Quality of Surface Waters and Effluents,
Weber, C.I. and B. McFarland, 1973.
58
-------�
APPENDIX A
AMBIENT DATA
-------�
FIGURE IA
16.0-r LONG TERM DISSOLVED OXYGEN
BEAR RIVER NEAR MCUMTPEUBR
1S.0-T-
IDAHO DHW DATA
3
3
O
V 12.0-
'E
D
0
x a.0-
V
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N
B.0-
M
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/
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li
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1
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AF
,
>72
?S
1
w
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s
3
-------�
U3.0-r-
FIOURE EA
LONG TERM PH
BEAR RIVER NEAR MONTPELIER
IDAHO DHW DATA
8.0-4-
NJ
7.0-1-
§ i
111
5 S
3 >3j K
IS »
B"" SI g =3 =; -.
_ a S S3 ~ K
^ C S3 «-. M S3
_l£|^l_l 4, i i ij ij_i!| i i
5 S "3" 3 53 3 $15 S3 S ~j S' S3 S S3 S*" *
6 'I 5 3 § a S .3 S 5 3 SS5= s
e-o-r E g
9-4 fr«4
1969
I""
1972
VEARS
»** ZZ
^^ M fc:^
nr £* S3
-a-., .K..-M_
T
1973
a a ;
1975
-------�
FIGURE 3A
T
O
T
A
L
K
A
l_
I
N
I
T
Y
M
Q
X
L
3S0-
32Z3-4-
123-4-
103 H-
LONG TERM ALKALINITY
BEAR RIVER NEAR MONTFELIER
1969
IDAHO DHW DATA
1970
1971
1972
1973
1971*
1975
-------�
FIGURE.
UDNG TERM ORTHO PHOSPHATE
o
R
T
H
O
F
H
O
S
F
H
A
T
M
G
0.G2J-
6-G2J-
0.40--
0.20- -
BEAR RIVER NEAR MONTPELZCR
IDAHO DHW DATA
Algal Bloom Potential Level = .025
1969
975
-------�
FIGURE 5A
TERM DISSOLVED OXYGEN
BEAR'RIVER AT SODA SPRINGS
D
I
S
3
O
L
V
E
D
O
X
V
O
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N
M
G
13.0 +
12.0-4-
S.0 +
IDAHO DMW DATA
6-0H ±Er tr-
3.0-i-
1969
D iee>-
o
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p
El
R 140-
C
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9
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1969 1970 1971 1972 1973 1974 1975
YEARS
A-5
-------�
FIGURE BA
U3.0-T-
LONG TERM PH
BEAR RIVER AT SODA. SPRINGS
IDAHO DWW DATA
B.0-f-
1969
-------�
FIGURE 7A
T
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A
L
A
L
K
A
L
I
N
I'
T
V
3S2J-J-
22J2J4-
120
1969
LONG TERM ALKALINITY
BEAR RIVER AT SODA SPRINGS
IDAHO DHW DATA
1970
1971
1972
VEAR3
1973
1971*
1975
-------�
FIGURE 8A
LONG TERM ORTHO PHOSPHATE
LK3-
O
R 0.Q3-
T
H
O
P
M 0.B2J-
O
S
P
H
A
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M
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^
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to
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w ra
X C
x
1 m ?S [x y i ^
i
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©EAR RZVER AT SODA SPRINBS
IDAHO DHW DATA
Algal Bloom Potential Level - «01
i
i I ^i
K ' pjj j H J>sj p '^>
' S ixi' ^§ ^ k. m $ S S ^ i
r r r i
YEARS
-------�
FIGURE BA
16.0-r LONG TERM DISSOLVED OXYGEN
BEAR RIVER AT PRESTON IDAHO
0
I
3
3
O
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D
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M
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13.04-
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3.0 +
IDAHO DHW DATA
5 3
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1 1 = g
C
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1970
r
1971
1972
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1973
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1975
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100-
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1974 19
YEARS
A-9
-------�
FIGURE 1OA
10. EH-
LONG TERM PH
BEAR RIVER NEAR PRESTON
IDAHO DWW DATA
S.0-I-
8.0-
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6.0-
a
MB BM
- 1 i
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FIQURC TIA
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1975
-------�
FIGURE ISA
CUB RIVER DLW DEC MONTE CANNERY
RIVER MILE 13.I
D
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9
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Quality Standa
1969
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A-12
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FIBURE I3A
CUB RIVER BLW DEL MONTE, CANNERY
RIVER MIt-E IS. I*
1970
1971
1972
1973
IDAHO DATA
1975
YEARS
-------�
FIGURE I4A
WORM OREEK NEAR IDAHO-UTAH BORDER
D
I
5
9
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Idaho Water Quality
Standard
\
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1974 1975
-------�
01
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123--
FIGURE ISA
WORM CREEP; NEAR IDAHO-UTAH BORDER
RIVER MILE 4-.0
>969
19
70
1971
1972
1973
IDAHO DATA
1974
1975
VEARS
-------�
APPENDIX B
1974 SURVEY FIGURES AND TABLES
-------�
FIGURE IB
BEAR RIVER FLOW DIAGRAM
WYOMING IDAHO BORDER _
Thcr.es Tcrk
Blacjc Otter Div.
3ear Lake Outlet
Ovid Creek
Eightmtle Creek
Alexander Reserve:
prace Dam
SheeD Creek
"ontTjelier Creek
Georgetown Creek
Big Spring Creek
Soda Spring Creek
Lest Chance Day, diversion ^
Grace Dan Diversion
Grace Pover
Whiskey Creek
Trout Creek
Williams Creek
Mink Creek
Plant
X
r|
P
*
9
t
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fM Cove power Dlant r"fl<}v *
jOneida Dam
^West Cache Canal ^.
~ 9 T
1
Cub River
IDAHO .UTAH BORDER
B-l
-------�
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F
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9
FIGURE SB
FL.OW
BEAR RIVER
FLOW MTES
1 - 8/27M
2 - 8/2PM
3 - 8/29/TU
Inatatoneous flovi corresponding
to aeraple tines.
110
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FIGUFtE 3B
BEAR RIVER SURVEY
CUB RIVER
FLOW CF3
14-
13
IB
17
ia
RIVER MILES
-------�
FIGURE
FLOW DIAGRAM FOR CUB RIVER
Bear River Basin
CUB CANAL
IDAHO
'"WORM "CREEK
Franklin
Del Monte
Discharge
UTAH BORDER
BEAR RIVER
B-4
-------�
FIGURE SB
FLOW DIAGRAM FOR BEAB LAKE
Bear River Basin
Flow conditions for
August 1974 EPA Water
Quality Survey
Bloomington Creek
B-5
-------�
FIGURE BB
COLirORM ON TOE BEAR RIVER
Data Period 8/27-8/29 197U
X Total Collform
0 Fecal Coliform
8 Fecal Streptococcus
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RIVER MILES
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FIGURE 7B
DISSOLVED OXYGEN
BE API RIVEI3
14C- -
130- -
120- -
110- -
100- -
Q0- -
130 130 170 139 210
RIVER MILES
H h
220 Z70 290
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MEDIAN VALUES 8/27/74.--8/2B/7*-
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110 130 ISO 170 190 210
R IVER MIUES
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FIGURE SB
TURBIOITY
BEAR "RIVER
MEDIAN VALUE3 8/E7/7 4.--8/2S/74-
R
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110
R IVER MILES
A *
-------�
FIGURE SB
TURBIDITY
CUB RIVER
r
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RIVe.R MILES?
-------�
FIGURE IOB
pH
BEAR RIVER
MEDIAN VALUES 8/27/74---B/2B/74-
I0.0z>-r
B.exs- -
8.03--
H 7.00--
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5.00- -
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1
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RIVER MILES
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FIGURE MB
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R IV JT.R .M I LS.S
-------�
FIGURE ISB
RAINPOW FI9H T»ER HOUR
BEAR 'RIVER
C41
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H
e.s- -
e.0-
i.a- -
MAY - AUO 1872/1873
H
O
U
R .
1.0- -
0.3- -
110
u
£
1.30 130 170 1S0 210
RIVER MILES
233
r
TTt Ml .t lint
I C H U jt 01 '0101
'S U 8 °£ 8 £ 3 2- I
4) I ft) MOM* U P O <3
M *W W 41 tO U . O C
rH 3
M O *
H MJ
a> H
U
I
u
u
in
!
O.U -rl
WO. B
»
01
u
u
01 .* vl
i n i
H rt C vH
I la 3
fc
H 4
270
a
.£
«i
8
.t
2
&
B-12
-------�
FIGURE I3B
RAINBOW FISH PER ANQt-ER
BEAR "RIVER
3.0-r
R
A
I
N
a
o
u
F
I
9
H
F
e.
R
A
N
Q
L
e.3- -
e.0- -
1.3- -
1.0- -
0.3--
MAV- AUO 1872X1873
1L0
1.30
130
170 182 210
RIVER MIUES
230 270 230
JS-S
u «
«
u
c
V
u «
01 U U .
00 U
c u
H a «i
! n n
I
5°
01
u
2
U V 3
*4 *H
3-S
£ I
! J
.£
j
e
1
E
3
&
5
I
B-13
-------�
3.B0-1-
FIGURE
MACRO XNVCRTXBRATC *Ptoita DIVERSITY
RXVCR SURVEY 107*
c
z
V
c
M
9
Z
T
Z
M
X>
E,
x
T
3.30--
3.B0
C.O0- -
Clean water
A
P.M.
I ORG.
1
110
i:
0
1!
0
I
Moderate pollution
1
t
Extreme pollution
1 II 1 1 1
170 lag 210 zaa 890 ZTI
0
>
i
ee
o.r.
274
153.1
140.3
126.6
97.3
97.3
254
3652
5571
652
2506
2994
2.82
2.73
2.96
' 2.90
2.85
3.14
RIVER MILE
?!
15
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0)
0 0}
C j*
fll J^ *-> Q)
fi "> '?
is i"
M .* P- 3
M C ^* P
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u c
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i
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c
u
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1 I
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: i T
** .^ i
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-^ X
'-g. I
' i;*1 =
- « c ^-
;^£ s.
I
t
01
s
ii
88
I
T
O.
t/1
S.
t
o
-------�
S.0-T
l.B- -
FIGURE IBB
TOTAL MERCURY
BEAR RIVER
X - MEDIAN VALUES 8/27/74-- 8/2S/74.
T
O
T
A
M
E
R
C
U
R
V
u
Q
i.e- -
1.4
1.2- -
1.0- -
}_ . x
0.B--
0.4.- -
I
1
^
/
Ik
I/
/
/
r*
fi
§* S
fei
0.2--
Toxlc Limit to Aquatic Organisms
132) ISO) 170 1S0 EU3
R I VER MILE3
7TVI
3
u
tl
U J* V
V * U 0 W
j: « cj<_>
U 11 OP
« u e o x
O O tl
<3
V
u
s
n
£
U
U V
.fi
60
e 60
*H C
B-P
V) 0-
V
O '
u
?
Creek >
o
u
u
i
A
u
11
b
'U
££
M
U
in
QJ u
f* W , I
270 ffV)
.£
B-15
-------�
SfiJ-i-
IBB
TOTAL ZINC
BEAR RIVER
T
O
T
A
L
Z
I
N
C
u
C
X
L
30- -
20- -
x x S8S .
- MEDIAN VALUES
8X27X74- 8/28X7*
110
Y'
f-i
3
150
170
ISO
RIVER MILES
i
2
rt
O
01
u
B
2
U
jj
.3
1
'£t
sJ
U 01
M
u *H
tn o<
en
0
O eo
O-H
in cQ
Ul
u
B
H
1
U
a
V4 .
u
01
l-t
H
B
jj
£
00
M
1
01
M
U
2
u
QO
tl
o
01
u
y
.*
QJ
01
U
'U
^
^
IIT
u u
r-l 01, I
3|
05 £
ffl
a
^
I11
6,
oi
I
I
1
270
B-16
-------�
L0-r
FIGURE 17 B
TOTAL CADMIUM
BEAR RIVER
T
0
T
A
L
C
A
D
H
I
U
M
U
G
e- - x
X- MEDIAN VALUES 8/27/7*-8/ZS/74
I
HI
2- -
T
t
Toxidtv for aouatlc Hfe
n
a
130
170
180
210
230
230
RIVER MILES
J- $t t T
3 "is j -S
3
S
V
U
e
u
U
V
«
a
o to
O vl
»e
(A
60
a
o
&
H «.
U |J f-i
3 U «
o e
b n
H U
3C
^1
270
r
I
230
B-17
-------�
FIGURE IBB
TOTAL. HARDNESS
BEAR RIVER
373-r
T
O
T
A
L
H
A
R
D
N
E
S
3
C
A
C
O
3 -
.M
O
X
L
273- -
s»*yi
x- MEDIAN VALUES 8/27/74.-e/es/74.
1.10
130
1.30
170 isa 210
RIVER MILES
270 gag
r
f
.5
U II
.£
'j l j T n t
1 ji « tl « I
II tl II iH tl, I
u
tl
no. B
tn u
S« £>
3
u
u
o
J.
I
.
a
« S oi
S v
i
B
B-18
-------�
FIGURE 19 Q
TOTAL PHOSPHORUS
BEAR RIVER
0.20-T
0.18--
0.1B--
T
O
T
A
L
0.14-
r
M
O 0-12-
3
H 0.10-
O
R
U 0.08-
3
M
O
0.0B- -
MEDIAN VALUES 8/27/7
- X»C OCCWW XW ^«
\Je
210
230
270
2S0
R I VE.R M I LES
U t>
« b
tj o
£t
Ujl
U -H
O. U
tn a.
.htmlle Creek- >
rgetown Creek ^
j « -v ..
r Lake Outlet >
itpelier Creek >
nbow Canal <
.£
m
1
e
II
8 S
B-19
-------�
FIGURE SOB
IMO_--N
BEAR RIVER
0.33-r
0.30
T
O
T
A
t_
N
O
3
M
D
S
t_
Aloal Bloom Potential Level
X- MEDIAN VAUUE3 8X27X748/29/7'*
2B0
RiveR
J- f
j. .t J T ti t
«J ji u u «1
" S .« I r! V. I.
» H
v> eu
V)
SM
Ji£
(ft
to
H
U)
S S
a «
b -O
8*4
>
II
fc
1
1
K
ii
B-20
-------�
FIGURE 21B
320-r
AI_KAl_ITIY
flEDlAN VALUES 8/27/74-8/28/74-
BEAR RIVER
T
O
T
A
L
A
L
K.
A
L
I
N
I
T
Y
203- -
130-I-
Mln Flow only
150
170 1S0
RIVER MILES
g"v* 270 2£0
I
J;
i !.
£Jf-r-
«i *
0-1 01 S
-
»- « c
> oj o
omX
£
(S
S.
B-21
-------�
FIGURE BBS
BEAR RIVER
CHLOR A
e-
3-
C
H
L «_
O
R
A 3-
M
O
M 2-
1-
>
-
. 1 1
Eutrophlc Level - 10.0
1
^ *
Mesotrophlc Level
.
Ill II 1
i iii ii i
110 130 1S0 170 180 . 210 g'qoi ?sgi 270 gogi
RIVER MILE
* **+ 1- ft T T T Tt f t '
1 1 a s* J -s «*
2 -KM ,1 ° " « * <-i«.
s sJs'Ba^fi'" »« « 1
5-8 " Sfi 8 Iff S -8 ' 8 J 1
1 'SIS Sfix 2 « i 2 2 ^3 > .. '£
O O 4V U V) O* B U'U^ltO M
*<*J^- Vlw M i ^S " it
U Jl rH 3 0 4J ^ jC h *O h *J 2 9
« ^ , rH o -H «i*gMee g -H « c M g
£2 ' S^g ^ JiS S 1 S-|£ 3 J
o ; a.1 3 A
2 £
: «. |. g
£,- . . . 1 . I *
' S '' Ji
Is - a
*! U
^S s
B-22
-------�
i
N>
U>
T
O
T
A
H
O
S
P
H
C
R
U
3
M
G
0.13-1-
0.12- -
0.23
0. GO-
F1GURE 33B
TOTAL PHOSPHORUS
BEAR RIVER
Station 153599
River Mile 97.3
NOON
I
NOON
1
NOON
I
I
TTJ£ I
AUGUST
USD I TKJ
27/28/2S IS74-
I
FRI
-------�
FIGURE 20 B
TOTAL PHOSPHORUS LOADING
T
o
V
A
L
P
H
O
s
P
M
O
R
U
u
B
9
«"
D
A
Y
T
O
T
A
L
H
O
S
T»
H
O
R
U
9
L
B
9
X
D
A
ssze>- -
700- -
4C0- -
100- .
_ Min Flov only §& ^
*~~~ >|M
I1
1 - 8/27/7U
2 - 8/28M
3 - 8/29/7l>
0 - MEDIAH
110 1=0 ISO 170 130
210
1EB- -
TRIDUTARV AND MUNICIPAL UOADINO9.
110
150
170
IBCS
'210
RIVER MIL.ES
1
£2
4-
i
1
u
^N / ^ ^ ^ ^j
S ti-8 I
tl H tl. I.
b *H
f) O,
u
ti
>-*
"a
x
M
W
£
ti
M
2
u
*"
i'«
ti
V
!.
&
270
270
B-24
-------�
FIGURE EBB
TOTAU NITROGEN LOADING
BEAR RIVER
T
O
T
A
I.
N
X
T
R
O
O
E.
H
U
B
a
s
D
A
V
1 - 8/2T.Tk
2 - 8/28,TU
3 - 8/29,7U
0 - KDLAJ
110 130 120 170 1S0 210
ZS0
T 40B-
O
T
A
L
M0m_
JKUfm
H
X
T
R
O 220.
O
£
N
, 100-
B
a
s
D
A
V
TRIBUTARY AND MUNICIPAL LOADINO9
"
»
t
1 1 1 I 1 I 1
1
1
110 130 130 170 LB0 210 230 2S0 270 28
ft Ttt Ml ] If tt t " t
3 .' c k. ji « «« 1
' 1 -S U . i3 ° S 2 3 ! J,
0 1* " E. o 543fi u
-------�
w
N5
T
O
T
A
L
N
O,
3'
N
0.20-r
D.18-
0.1Q-
0.14--
0.12-
0.10--
0.G3--
0.03--
0.04-
0.02
FIGURE 2BB
TOTAL
BEAR RIVER
NUUN
I
I
NOON
I
I
TU£ I WED I TMJ
AUGUST 27X2S/2Q 1974-
Station-153599
River Mile 97.3
FRI
-------�
FIGURE E7B
3
O
L
I
D
' 3
n
c
TBBJ-r
e00- -
303- -
403- -
303--
220- -
SOLIDS DATA
BEAR RIVER
1 - - Total Volatile Solids
2 - - Total Solids
3 - - Dissolved Solids
Median Values - 8/27/74-8/29/74
130 150
.s-s
U X
B-27
-------�
FIGURE EBB
SUSPENDED SOLIDS
CTOTAL RESIDUE NON FILTERABLE!
BE API RIVER
=B>-r
X- MEDIAN VALUES eXZ7/7+-B/ZS/74-
s
t
D
U
c.
T
O
T
A
U
N
F
U
T
M
O
X
RIVER MIUE.S
f
f
IT
.u
«
I «l
J hi
IU
<
I X
«
ri
£
}.
u
«
u
e
s
u
u
CB
JS
i
1
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i ji
M «
u «
b
nu
a
5?
U *H
D* U
w o.
U)
«
T) M
wco
V)
.?
!
u
^1 ,
0
V
H
>*4
fl
U
ji
o
H
M
1
1
M
o
g
O
4J
«l
U
tJ
O
/
J
1
ttf
'U
«t
H
£
in
fH «. I
m
4
o
!
J
C
M
1
JI
B-28
-------�
FIGURE E3B
CONDUCTIVITY
BEAR RIVER
MEDIAN VALUES 8/27/7*
c
o
H
D
U
C
T
I
V
I
T
Y
Tea- -
M1n Flow
I
1
1L0
1 I
1 1
130 130 ^
\l
till
1 1 1 1
'0 iaz> zua ?TV> 220
^x
i 1
1 I
270 2£
RIVER MIUES
A " A.
I
1
^-
i
«J
01 J
6!
Si.
J
1
S
< <-
! !
r
tf
)
1
|3
- 4
J
1
D S
I (.
3 5
,1
Y
S
£ O
)
i! 8
3 C
f 6
in
O
c
X
0
in
i
t
i
i
Ol
2
in U
o>
C 01
^ ^~
1 5
I I
I I
II
3 U
01 U
e
;£§
o k
11:
t
£
M
1
88
EC
ta
-------�
r
c
x
F
9
T
t
o
e.0- -
1.0-
FIGURE 3OB
FC/FS RATIO
BEAR RIVBR
X *
RATIO
TmcO. Cblifon
I > r>etl Straptocoeet
LIVESTOCK POULTRY WASTE
110 130 150 170 180 210. 9na
Riven MILES
btlo of Trtbutarlx on tb. B*v Xlnr
270
F
C
F
3
R
A
T
t
O
.2.0
1.0
: T
DOMESTIC 'WASTE!
xK
> f
UNCERTAIN SOURCE
LIVESTOCK PDULTRV i
n T '
' " i
.LI i i ,i i i
/
STE
f]
n-,
r
i
, , i
i ,
Sit 110 130 130 170 180 210
2E0 270 2S0
RIVE.R MIL'ES
Jil 1 f 1 HI
Ml 1 I
i
3II
s.*2
i \
B-30
-------�
FIGURE 31B
O.35-T-
TOTAL PHOSPHORUS
CUB RIVER
w
T
O
T
A
L
P
H
O
3
P
H
O
R
U
S
n
c
x
L
0.30-*
0.23- '
0.210- -
0.15- -
0.10- -
0.05'
14-
Algal Bloom Potential Level
13
+r 1-
17 18
RIVER MILES
-------�
IMOg -
CUB RIVER
N
O
3
I
-N
M
D.7O-T
O.6D--
0.3D- '
D.3O
0.20- -
O.1O- -
Alqai Bloom Potential Level
14*
ie
18
ia
RIVER MILES
-------�
FIGURE 33B
D.OBf-
.IMH3-IM
CUB RIVER
i
OJ
N
H
3
I
N
n
G
O.O4-
14-
13
17 18
RIVER MILES
18
-------�
SOT-
LO
T
O.
T
A
L
C
H
L
O
R
I
b
e
M
O
X
L
25 -4-
15-1-
104-
34B
TOTAL CHLORI
CUB RIVER
14-
13
17 18
RIVER MILES
13
-------�
BOOT-
35B
DISSOLVED SOLIDS
CUB RIVER
w
P
I
s
s
o
L
V
E
D
S
O
L
I
D
9
M
O
X
L
4O0- -
3(00- -
ZOO-*
X00- -
14-
15
17 18
RIVER MILES
2.1
-------�
FIGURE 3GB
TEM PER ATURE
CUB RIVER
2O-T-
w
T
E
n
F»
E
R
A
T
U
P
E:
13--
1D-
1
14-
15
ie
17
18
ia
RIVER MILES
-------�
TABLE IB
AUGUST 1974 BEAR RIVER SURVEY
HO.
1
2
3
4
5
6
7
8
9
10
11
12
13
14
13
16
17
18
20
n
22
23
24
25
26
27
28
29
30
31
32
34
35
W
36
37
38
39
40
44
^2
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
STATION
KAIMSTEM
153596
153550
153551
153552
153556
153597
153557
153558
153595
153598
153559
153560
153561
153562
153563
153549
153546
153599
SAMPLING STATION LOCATIONS
SAME
RIVER MILE
Bear River 9 Bridge .25 ml. W. of Idaho -Hyo Border 274.0
Bear River ? Bridge 1 ml. S.tf. of Peg ram
Bear River 9 Dlv. Dam 3 mi. E. of Dingle
Bear River 0~Rd. 1 mi. N.E. of Dingle
Bear River 0 Hwy 89 bridge
Bear River 0 Bridge 1 mi blv outlet canal
Bear River 0 Bridge 2 mi. N.W. of Bennlngcon
Bear River 0 1.4 mi. abv. Skinner Creek
Bear River 6 Bridge 1 mi. blv Eightnile creek
Bear River 0 Bridge 0 head Soda Reservoir
Bear River 0 guage blv Alexander Dam
Bear River 0 1 ml. blv Last Chance Dam
Bear River 0 Bridge -3 mi. blv Grace power plant
Bear River 8 Bridge 5 mi. W. of Thatcher
Bear River 0 Bridge 1 mi. blv Oneida Dam
Bear River 0 Hwy 91 Bridge N. Of Preston
Bear River 0 Road bridge 2 ml. W. of Preston
Bear River 0 Road bridge 3 ml. E. of Ueston
256.2
242.7
237.9
223.6
219.3
209.3
197.2
185.3
174.3
169.4
166.1
153.1
140.3
126.6
109.0
104.3
97.3
TRIBUTARIES
153564
153565
153565
153568
153567
153553
153554
153555
153569
153570
153571
153572
153574
153577
153578
153575
153579
153582
153583
153584
153586
153548
153588
153589
153590
153545
1-53591
153544
153592
153593
153594
SPRIMCS
153573
153576
153580
153581
153585
153547
153587
Thomas Fork 0 Hwy 30 Bridge 0 mouth
Sheep Creek .2 ml. abv mouth
Crockett Canal 0 bridge 1 ml. S. of Dingle
Monepelier Creek .:0 RE Yd S.W.-of-.Montpelier
Bloomington Creek 2 mii:S.E.- o£-d51oon±ngton
Rainbow Canal 0 Bridge 1.5 mi. W. of Dingle
Bear Ik outlet canal 0 br. 0 Lift on Pump St.
Bear .Ik outlet 0 Hwy 89 bridge
Ovid Creek 0 br. 3 ml. N.W. .of MonCpeller
Flowing veil 1 ml. N.E. of Bern '
Georgetown Creek 0 rd. Br. near mouth
Stauffer Creek 0 br 2 mi. E. of Nounan
Eightmlle Creek 0 br 1 mi. abv mouth
Big Spring Creek 0 Trout Farm
Big Spring Creek near mouth
Soda Creek .25 ml. blv Hooper Spring
Soda Creek 0 br. .2 mi. abv. mouth
Whiskey Creek 6 Hwy 34 bridge
Trout Creek 0 Hwy 34 bridge 0 Thatcher
Williams Creek 0 Hwy 34 bridge
Mink Creek 0 culvert .1 mi. abv. mouth
Deep Creek 0 culvert .2 ml. N. Squaw Spring
West Cache Canal 0 Flume E. of Weston
Upper Canal 0 Culvert 2 ml. W. of Fail-view
Worm Creek Abv. Preston STP
Worm Creek 0 culvert .8 mi. blw Preston
Worn Creek 0 culvert 2 mi. W. of Franklin
Cub Canal South of Preston
Cub River @ Div. Dam 4 ml. H^E. of Franklin
Cub River Hwy 91 Br. abv. Del Monte
Cub River blw Del Monte
Natural spring llj mi. W. of Georgetown
Hooper spring 1 mi. N. of Soda Spring
Spring 1 ml. E. of Gen Valley Cheese
Spring 1 mi. S. of Niter, Idaho
Maple Grove Hot Springs
Hot Springs (Squa«73 mi. N.W. of Preston
Spring S. of Oneida Rd. W. of Preston
272.0/.01
247.67.2
242.7
-.J24.A/.2.1
*220Y47IO.'2/3.0
220.4/10.2/4.7
220.4/14.1
220.4/1.1
215.9/2.7
203.6/'.l
202.5/.1
186. S/. 8
175.0/.9
175. O/. 4
174.2/3.0
174. 21. 2
145.6/1.1
139. 9/. 8
134.8/.6
120.7/.1
106. 61. 2
115
77.7/7.0/9.9
77.7/7.0/9.1
77.7/7.0/4.4
77.7/20.9
77.7/16.5
77.7/15.1
No. refers to. station location on Map, Tlgur*
B-37
-------�
TAB LE MB
BEAR RIVER SURVEY
August 27,28,29, 1974
w
u>
co
STATION
Be«r River 9 Idaho-Wvo Border
Thou* Fork f couth
Bttr Rivet t bridge S.H. of FegrM
Sheep Creek abv Bouth
Bear River I Div. Du I. of Dingle
Crockett Canal t Br. S. of Dingle
Black Otter Dlveralon
Bear R- H.E. of Dingle
Hontpeller Creek
Bear River 9 Buy 89 bridge
Rainbov Canal V. of Dingle
Bear Lake Outlet-Llfton Pino St.
Bear Lake Outlet Bvy 89 Bridge
Blockington Creek
Bear River 1 mi. blw outlet Canal
Ovid Creek 3 »i. K.W. of Hontpelier
Bear River 2 mi. R.W. of Bennlngtoo
I/ Negative value* denote diversion* froa river
SURVEY FLOWS I/
RECORDING CAGE MEASURE HATER MASTER ESTIMATE FLOW ACCTHDLATED FLOWS
RIVER Mltl
274.0
272. O/. 01
236.2
247. 6/. 2
242.7
242.7
241.3
237.9
224.4/2.1
223.6
220.4/10.2/4.7
220.4/14.1
220.4/1.1
220.*4/10. 2/3.0
219.3
213.9/2.7
209.3
27 28 29 27 28 29 27 28 29 .27 28 29
194 196 IBS
216 218 207
333
-173 r!73 -164
1130 1190 1210
1180 1220 1240
20.7
-5
-33
23 23 23
900
1.0
18
12.7
7.4
27 28 29
214.7 217 203.7
1173 1213' 1233
-------�
TAB LE HB
to
SO
i Creek '
Btauffer Creek
Star River 1.4 abv Skinner Creek
El|htalle Creek
Beer River bl* Blfhtadle Creek
Blf Spring Creek ( velr
Bear River heed Soda Reeervolr
Soda Creak abv *Duth
car River blv Alexander Dea
ear River blv tact Chance DCB
Bear (Liver bl* Crace Fover Plant
Whlek«r Creek
Bear River H. of Tlwtcber
Trout Creek
Will In Creek
Bear River blv OMlda Dn
Mink Creek
Heat Cache Caaal
Bear River . at
Dee* Creek
RECORDDIC CACK KEASUU WATER MASTER ESTIMATE FLOW ACCTOULATn) TUJWS
klVER HOI 27 28 29 27 IS 29 27 28 29 27 28 29 27 28 29
J03.6/.1
202.S/.1
197.2
186.3/.I
185.3
173.0M
174.3
174.X/.1
169.4
166.1
133.1
143.6/1.1
140.3 '
139.9/.B
134.8/.6
126.6
120.7/.1
115.0
109.0
106. 6/. 2
1290 1334 1334
1330 1310 1330
223 227 209
16.1
18. B
30
983 971 971
13
1336 132* 132
23.6
18.0
1127 1107 1127
-143 -141 -111
73.7
5.2
6
6
125» 1299 1319
1280 1315 1335
87 104 112
-------�
TAB LE HB
-C-
O
8TATIOH
Bear Rl»«t W. e( rrutaa
B««r Rivet B. of tfocton
C»* U»«r U« Dal Mont*
Cub Rivet *br D»L ttoat*
Cub tivtt I Divii DM
RECORDING CAGE MEASURE HATER MASTER . ESTIMATE FLOW ACCTIPLATEO FIOHS
RIVER KILE
104.3
97.3
77.7/13.1
77.7/16.3
77.7/20.9
11 li 11 11 li 11 . 11 li 11
22.3
7.8
40
11 li li
11 li 11
160 160 160
ni ISO /SO
-------�
TABLE HEB
MOD LAKE FLOWS
AUGUST 1974 SURVEY
INFLOW CFS
OUTFLOW
:CFS
STREAM
8/27 8/28 8/29 AVG
8/27 8/28 8/29 AVG
Bear Lake Discharge 900
Bloomington Ck. 13
Crockett Canal .5.
Black Otter Canal 33.
Rainbow Canal 150
Bear Lake Outlet
-
1Z5
164
900
13
. 5.
33
163
1190
1210
1200
TOTAL
1114
1200
B-41
-------�
TABLE
BEAR RIVER BASIN
POINT SOURCE LOADINGS
Discharger
Grace STP
Soda Springs STP
Paris STP
Montpeller STP
Preston STP
Receiving Maters
Bear River
Bear River
Bear Lake Outlet
Bear River
Worm Creek
Del Monte Cub River
Monsanto Irrigation Canal
Caribou Trout Farm Big Spring Creek
River Mile
163.3
174.8
220.5/8.0/4.6
222.0
77.7/7.7/9.9
77..7/15.7
174.2/3.1
175/0.4
BOD
IBs/day
1487
1028
246
--
21
T. Phos.
Ibs/day
10.2
38.6
26.7
38.6
9.7
10.1
172.4
9.6
NOV
Ibs/day
.6
7.6
15.1
20.7
B.8
2.3.
100.5
243.6
, Sus. Sol Ids
Ibs/day
47.5
441.0
2704
243
2.1
273
'123.
964.4
-------�
TABLE
BEAR RIVER BASIN
POINT SOURCE DATA
MUNICIPALITIES
Grace STP
Soda Springs STP
Paris STP (south
effluent)
Paris STP (north
effluent)
Montpelier STP
Preston STP
COD
180
290
-
570
lUO
Uo
N-NH3
mq/1
18
U.8
1.7
2.U
9.3
1:7 -
JKN03
mq/1
.5
.83
2.1
1.U"
2.9
.5.1.
Total phos.
mq/1
8.6
U.2
1.6
U,£
5.U
3.6
Jurb.
JTU
30
18
2.2
132
lU
U.3
Total. Col 1.
iH/100 ml
2,100,000
Uoo
1,500,000
1,100,000
Uoo
100
Fecal Coll.
lH/100 ml
100
1,500,000
.feUo.ooo
100
100
INDUSTRIES
Gem Valley Cheese 230
Del Monte Corp. 150 .
Honaanto Co. 16
Caribou Trout Farm
1.2
.u
.lU
.25
2.2
.U
U.9-
2.4
3.0
1.7
8.U
0.1
15
1U
l.U
i;i
18,000
32,000
r,3oo
620
120
-------�
TABLE "21 B
BEAR RIVER BASIN
Point Source Data
MUNICIPALITIES . How
CFS
Grace STP 22
Soda Springs STP 1.7
Paris STP (south .3
effluent)
Paris STP (north .5
effluent)
Montpelier STP 1.3
Preston STP .5
INDUSTRIES
Gem Valley Cheese
Del Monte Corp. 1.1
Monsanto Co. 3.8
Caribou Trout Farm j.g.8
Temp.
. C
22.0
17.3
11.5
12.6
15.7
19 .'6
23.6
18.0
i
21.8
U.2
pH ' Total Sol Ids
mq/1
7.3 62U
6.8 1195
2.3 399
2.2 1125
7.3 766
7.1» . 510
9.0 6U8
7.1* .667
8.0 763
6.6 496
Total Vol .
Sol Ids mq/1
173
331
101
1*76
228
165
233
335
76
S72
Sus. Sol Ids
mq/1
1*0
1*8
16
6lO
3U
1
30
1*6
6
9.5
BCD5
162
38
200
35
-
1
_
-------�
TABLE HIT B
BACTERIA LEVELS IN TRIBUTARIES OF
BEAR RIVEU BASIN
RIVER LOCATION
WYOMING-IDAHO BORDER
Thomas Fork
MUD LAKE TRIBUTARIES
Crocket Canal
Blooming ton Cr.
BEAR RIVER FROM BEAR
Montpeller Creek
Ovid Creek
Georgetown Creek
Stauffer Creek
Eightmlle Creek .
Big Spring Creek
/~^.a Spring Creek
BEAR RIVER FROM SODA
Whiskey Creek
Trout Creek
Williams Creek
TOTAL FECAL -FECAL STATE W.Q.
DATE COLI. COLI. STREP CLASS.
TO BEAR LAKE DIVERSION
-
8/27/74
8/27/74
LAKE DIVERSION TO SODA
8/27/74
8/27/74
8/28/74 .
8/28/74
8/28/74
8/28/74
8/28/74
SPRINGS RES. TO ONEIDA
8/28/74
8/28/74
8/28/74.
-BEAR .RIVER FROM ONEIDA RES. TO ."BORDER
Mink Creek
8/28/74
CUB RIVER FROM R.M. 21 to BORDER
AC Diversion Dam
At. R.M. 21
At R.M. 16.5
(U/S from Del Monte)
At R.M. 15
(D/S from Del Monte)
WORM CREEK
Af\. Preston STP
b^_.' Preston STP
Near State Border
8/28/74
1
8/28/74
8/28/74
8/28/74
8/28/74
8/28/74
0/100 ml
-
-810
170
SPRINGS Pi
4900
600
330
720
430
620
600
RES.
140
360
470
800
690
200
430
520
TNTC
5700
0/100 ml
-
110
60
iERVOIR
4800
110
170 "
570
150
120
140'
34
230
180
160
1
260
190
130
90
50,000
870
ff/100 ml
-
780
1200
4500
40
1200
1900
550
650
120
92
520
350
940
620
1600
810
2000
21,000
3500
'A
A
A
A
A
A,
A
A
A
A
A
A
A
A
A
-
A
A
B
B
B
* TNTC - Too numerous to count
B-45
-------�
-p-
TABLE SQtB
WATER QUALITY OF BEAR RIVER TRIBUTARIES
LOCATION OF
CONFLUENCE I/
R.H. HO.
TYPE OF
INFLOW
FLOW
cti
11
PARAMETERS
T.Hi Hardnefl Cond.
OFFER RtVER
272.0 Thonaa Fk.
247.6 Sheep Creek
HUD LAKE AREA
BEAR R.
224.4
220.4 .
215.9 .
203.6
202.5
186.5
175.0
174.2
Bloomlngton Cr.
Rainbow Canal
Bloomlngton Cr.
. Crockett Canal
Black Otter
Bear Ik. Outlet
Clifton
FROM HUD LAKE TO SODA SPRIHCS
Hontpeller Ck.
Bear Lake Outlet
Ovid Ck.
Spring nr. Georgetown
George town Ck
Stauffer Ck
Elghtmile Ck
Big Ck
Hooper Spr.
Soda Ck.
SODA SPRIHCS TO ONIEDA RES.
145.6
139.9
134.8
Spring (Mr. Cea. Valley)
Spring (Nr. Nllei)
Viikey Ck.
Trout Ck
Vllllaaa Ck
Maple Crave (Hot Springe)
Tributary
Tributary
, Tributary in
Tributary in
Tributary in
Tributary in
Tributary in
Tributary in
Tributary
Tributary
Tributary
Croundwatec
Tributary
Tributary
Tributary
Tributary .
Groundwater
Tributary
t
Groundwater
tTroundvater
Tributary
Tributary
Tributary
Groundwater
UK/1 _
20i7
1
13
171 1.4
12.7
5
33
900
18 .5
1180
7.4
.6
73.7 .6
5.2
16.1
18.8 1.0'
.
30*0
1.2
1.0
1310
23.6
18.0
.«
«g/l_
273
223
203
242
314
236
297
140
306
266
130
176
527
777
587
421
429
370
306
218
333
_ umho/cm
860
460
420
'600
720
520
690
360
610
500
240
360
1180
1400
1090
900
1100
960
720
480
600
T. Alk.
8/1
221
258
253
240
135
180
412
115
555
366
372
327
278
218
389
HOi
g/1
.78
.01
.07
.013
.01
.04
.01
.01
3.4
.88
.06
.10
.2.40
.01
.74
2.6
3.0
2.3
1.0
.12
.09
T.P.
g/1
.06
.03
.07
.08
.52
.04
.07
.03
.10
.20
.08
.04
.09
.30
.51
%
.18
.17
.11
.09
.03
.05
Teap.
fc
15.8
16.0
15.8
16.7
19.3
19.5
21.0
12.3
17.7
20.5
17.0
11.2
11.6
15.9
14.0
14.0
16.0
18.0
16.5
PH
,
7.8
7.6
7.0
7.5
8.2
7.5
7.9
7.2
6.7
7.5
7.8
7.5
6.6
5.4
6.6
6.6
7.0
7.6
7.7
7.7
TOC
»g/l
51.S
19.7
61.0
45.5
22.7
55
34
42
2.5
3.0
3.0
3.0
4.0
NHi
.03
.01
.01
.01
.01
.01
.01
.03
.029
.01
.02
.25
.5
.075
.07
.03
.025
.04
.02
1.2
-------�
TABLE SEDCB (CON'T)
-p-
LOCATION OF
CONFLUENCE I/
R.H. HO.
OHUDA
120.7
RESERVOIR TO IDAHO-UTAH BORDER
Kink Ck.
Squaw Hot Spring
Spring Mr. Preaton
TTPE OF FLOW
INFLOW cfa
Tributary 6
Croundvatar
Cnundwatar
11
PARAMETERS
T.llg
ug/1
1.0
1.0
.2
Bardnex '
Bg/1
US
490
231
Cond.
645
1000
1300
T. Alk.
228
580
230
NO-I
Bg/1
.68
.30
4.30
t.P.
SilL
.13
.06
.08
Temp.
°C
19.0
11.3
pH TOO
Bg/1
7.9 3.0
6.2 2.0
7.6 3.0
NHl
.04
.8
.02
I/ liabcr eorraipoodi to station on Fl|uT« (top/
2/ AT*I«|I of Mapl«f or«t rarrcj period
-------�
TABLE
Station Lab
Number Number
Isolation of Pseudomonas Aeruginosa and Staphyloccus Aureus
Date P. Aerug1nosa/0) S. Aureus/lOOml (
Collected Station Description TOO ml (confirmed (confirmed)
153556
153568
153571
153561
153583
153584
153587
153599
153589
153545
153591
153592
153593
35068
35070
35071
35069
35072
35073
35061
35066
35062
35060
35063
35064
35065
8/29/74 Bear R. @Hwy 89 Br 2m1
W. of Montpeller
Hontpeller Cr. SW.of
Montpeller
" Georgetown Cr J$ni W.
of Georgetown
Bear R @Hwy Br W. of
Thatcher
" Trout Cr %m1 E. of
Thatcher
Williams Cr 3%ni S. of
Thatcher
" Springs S. of Onelda Rd
H. of Preston
" Bear R. 3 ml W. of
Falrview
" Cr. N. of West pump
Canal
" Worm Cr. Below
Preston STP
" Worm Cr. @ culvert 2m1
W. of Franklin
" Cub R. @ Diverson Dam '
4m1 NE of Franklin
Cub R. Hwy, 91 Br h mi
N. of Franklin
0
0
0
4
1
0
0
0
20-
10
40
0
0
0
1800
0
400
800
700.
0
600
1200
0
200
80
0
(1) Confirmed on M1lk Agar
(2) Confirmed by DNase Adtivity & Coagulase Reaction
B-48
-------�
TABLE XB
AUGUST 1974 BEAR RIVER'SURVEY
PESTICIDEQCCURENCE .
PARAMETER
STATION BHC DDD DDE DDT
(Lindarie)
ug/1 ufe/1 ug/1 ug/1
BEAR RIVER
At Idaho-Wyoming Border - .003 .004 .004
Nr. Montpelier (abv. .009 .006 .007
confluence with Bear Lk. outlet)
Blw Bear Lk. outlet .012 -
Blw Grace Power Plant .005 _ _ _
THOMAS FORK
Nr. Mouth .006
BEAR LAKE OUTLET .010
MONTFELLER CREEK .005
BIG SPRING CREEK
SODA SPRING CREEK .003
MINK GREEK .003
CUB RIVER
At Diversion-Dam ,002
Blw Del Monte Discharge -
B-49
-------�
TABLE
MUD LAKE" LOADINGS
w
Ul
o
INFLOW/OUTFLOW
INFLOW
Bear Lake Discharge
Bloomington Creek
Crocket Canal
Black Otter Canal
Rainbow Canal
Paris STP. Discharge
TOTAL INFLOW
FLOW
cfs
900
13
5
33
163
.8 .
1114.8
TOT. PHOS.
0/day
97
5
3
10
70
39
224
NOa
0/day
49
5
1
5
11
21
92
Nfl3 T.O.C.
if/day 0/day
49 297,000
.7
.3
2
9 17,600
3
64 314,600
SUS. SOLIDS
0/day
24,400
2,200
80
5,400
30,500
2,600
65,200
AVG
T. COH.
Per/ 100 ml
350
170
810
220
1,300,000
AVG
F. COLI:
Per 100 /ml
2
60
110
120
700,000
OUTFLOW
Bear Lake Outflow Canal
' TOTAL OUTFLOW
1200 445
1200 445
64 65 145.000 112,000
64 65 145,000 112,000
50
20
-------�
TABLE
CUB RIVER LOADINGS
STATION R.M.
Cub River 20.9
Cub River 16.5
Del Monte Disc. 15.7
Cub River 15.1
FLOW
Cf9
40
7.8
1.1
22.5
- UlJB RIVER
LOADINGSJT/DAY
T. PHOS.
5.4
.1.8
10.1 .
30.4
NOv-N
39
22
2.4
54
NH-i-N
4.3
1.3
2.4
61
CUB RIVER BACTERIAL
DENSITIES PER/100 ml
T. COLI.
690
200
32,000
430
F. COLI.
260
190
-
130
F. STREP
620
1600
N/A
810
FC/FS
.4
.1
-
.2
I
Ul
-------�
TABLE
August 1974 Bear River Survey
WORM CREEK
STATION
PARAMETERS
Sample Sus. T.
Date T. Phos. NH^-N NO^-N Solids TOC COLI.
COLT.
Worm Creek
Preston STP discharge
Worm Creek just blw STP
Worm Creek 0.8 mi. blw STP
8/29/74
8/28/74
8/23/74
8/29/74
iag/1
0.75
3.6
1.14
mg/1"
1.30
1.7
1.55
mg/1
.29
5.1
.64
mg/1
39.0
.1
34.5
mg/1
19.0
16.0
Per 100/
ml
520 .
21
TNTC
5700 "
Per/100
ml
90
100
50,000
870
Values shown are an average of two values
Colonies too numerous to count
B-52
-------�
APPENDIX C
MONSANTO COMPANY COMPLIANCE
MONITORING REPORT
AND
RAW DATA - AUGUST 1974 SURVEY
-------�
ENVIRONMENTAL PROTECTION AGENCY
REGION X
SURVEILLANCE AND ANALYSIS DIVISION
COMPLIANCE MONITORING REP.ORT
PERMITTEE Monsanto Company
Soda Springs, Idaho
NPDES PERMIT NO. ID-000119-S
~~ <. Effective 10/21/73
RECEIVING WATER Soda Creek
PURPOSE
T'o assess compliance with NPDES permit conditions and provide dis-
charge information in conjunction with a receiving water study con-
ducted on the Bear River. ;
PARTICIPANTS '
James Hilemao- Region X, EPA
Douglas Houck Region X, EPA . .__
William .Finfrock Region X, EPA
Mark Hooper Region X, FPA
Rick Walters Region X, EPA, Idaho Operations Of
SUIiHARY OF FIHDIKGS
Based upon the results of the effluent sampling conducted during
August 27-29, 197^, and in inspection of tl\e plant records, the Monsanto
Company was generally in compliance with the initial effluent;, limitation
as specified in their NPDES permit.
. '. Thfc following requirement, however, was found not to be in complin
1. Temperature
Permit requirements (dslly max. = 70°F)
Survey results (8/29/74 - 71.2°F)
This violation is based on one grab sample only and should be con-
sidered as an apparent violation (not necessarily real).
PERMIT SUMMARY
PERMIT NUMBER 'ID-000119-8
EFFECTIVE DATE 10/21/73
SPECT_AL_ CONDITIONS:
^' Initial effluent" limitations
During the period beginning on the effective date of this permit
C-l
-------�
and lasting until September 30, 1975, discharges fioi,> outfall #001 sir ']
be limited and monitored "by the permittee as specified below:
a. The following shall be limited and monitored by the pcrraitti
as specified:
Effluent
Discharge Limitation
in kg/day iLbs/da^)
Daily Daily Other Limitation;
Monitoring
Requircnru-.fs
Measurement Sbv.p
Chacacteristic Average ' «jMaxiv..ja Average ' ' Maximum Frequency Type
Flow - - 12,100 14,500 Daily Continue,
Temperature -
Total Phosphorous 80
(as P) ' (176)
12,100 14,500
cu ra/day cu ra/day
(2.67 MGD) (3.83 MGD)
70°F
Suspended
Solids
Fluoride
163
(359)
10.9
(24)
126
(277)
326
(718)
32.7
(72)
Daily
Daily
Grab
24-hr-
Composite
Monthly 24~IIr/
Coupon jtt-
Monthly 24-Ili-.
Composite
For the purposes of this subsection, the c'.iiT.y average discharge,
except for flow and temperature, is the total discharge by weight during
a calendar month divided by the number of days in the month that the
production or commercial facility was operating. For flow, temperature,
and those parameters sampled at a frequency other-than daily,jthe daily
average is the arithmetic mean of all samples collected during-a calendar
month.
.'For the purposes of this subsection, the daily maximum discharge,
except for flow and temperature, means the total discharge by weight
during any calendar day.
b. The pH shall not be less than 6.5 nor greater than 9.0.
The pH shall be monitored daily by analyzing a grab sample.
c. The plant's intake well water shall be monitored weekly
for total phosphorous (as P) by taking samples from the individual wells
when operating and compositing according to' their actual corresponding
usage from each, well during the week.
PROCESS DESCRIPTION
The following information is taken from a source test report
(72-MM-27) for the Mbns'r ato Company.
Elemental phosphorus is-produced from phosphate rock by reduction
in an electric arc furnace. Typical ores contain 10-13% phosphorus-so
C-2
-------�
that about 10 tons of rode must be processed per ton of phosphorus prodir
Considerable quantities of coke, silica, and recycled materials are fed r
the furnaces with the beneficiated ore.
Prior to being fed to tne furnr.ce, the rock is agglomerated and heat
hardened in a kiln. The partially fused product is cooled and crushed tc
a specified siza before beinj fed to the furnace as- shown in Figure 1.
Phosphate feed is carefully proportioned with sili' a and coke before-
being transferred to feed bins directly above the furnace. The feed mixL
then moves by gravity from the bins down into the furnace as the furnace
feed is consumed.
The reaction within the furnace is approximated by the following
equation:
2 Ca3 (P04)2 + 10 C + 6 Sio2. (2300-27.00QF) ^ + 10 co + 6 CaSio3 .
f
Elemental phosphorous and carbon monoxide leave the furnace as gases
Dust is removed.'from the stream by an electrostatic precipitator and the
phosphorous vapor i-s later condensed out in direct-contact water condense
W.iste CO gas" is used as a' fuel in the kiln operation.
The molten process by-products and some coke must be periodically
removed from the' furnace by tapping. This molten material separates into
two layers inside the furnace. The lighter top layer is a, slag froia th.:
ore material. This slag has no economic value except as an aggregate. I'
is tapped alternately .from two tapholes at 15-minute intervals'. The slag
runs out into water-filled pits behind the furnace building.
Th ' heavier bottom layer is about twice the density of the slag, am'
islargely a phosphorous-iron mixture known as ferrophos. Thi~s metal by-
product is tapped from the furnace twice each day. The ferrophos is poui
into chills and then shipped to a nearby plant for vanadium recovery.
SELF MONITORING PROCEDURES
One outfall is used by the Company for discharge of cooling waters.
At the time of the survey all process waste water was being discharged to
non-overflow lagoons.
OUTFALL gOOl
Flow s measured continuously at this outfall by a Parshall flume in
the outfall line. Flow rate is recorded on a strip chart. A composite
sample is obtained daily.
C-3
-------�
SURVEY DESCRIPTION
Monsanto's outfall was monitored for one day utiliz-lnj; automatic
sampling equipment. Samples were obtained at the; same location of compai<
installed monitoring devices. Samples obtained by the ISCO's were tiir.e
composited and split with Monsanto.
Although flow proportioning of the composite was not attempted, it
is believed that a representative sample of the effluent was obtain^1..
Flow on outfall #001 was observed to ba quite stable during the saiiiplln-
period. Due to the relatively stable ope-ation of the mill processes, fit
proportioning was deemed unnecessary.
Samples obtained by the ISCO were ke;>t cold during tho sampling
process by packing ice into the center section. The company sampling
device does not provide for refrigeration of the s"anple.
Sampling was initiated on Tuesday afternoon. The ISCO automatic
sampler was set for a one hour sampling frequency. A 2'i-hour composite-
sample was obtained.on Wednesday afternoon.
RESULTS
Table 1 presents the analytical results of tha cample; obtained'
during the survey. Based upon these results the Company was well within
their daily maximum effluent limitation for flow, total phospho'rous,
suspended solids, fluoride .and pH. An apparent violation occurred for
temperature.
LIST OF ATTACHMENTS
Attachment' 1 "". Plant Evaluation Form
Attachment 2 Form used for purpose of record keeping
Attachments 3,4,5 Process flow charts
Attachment' 6 Facility map
-------�
TABLE 1. COMPARISON OF TOTAL COLFIROMS, FECAL COLIFOl'.MS, EECAL STKEP AMD FC/FS RATIOS
jtion
Number
153596
15356*
153550
153565
153551
153552
153553
153566
15355';
153567
153555'
153556
153568
153569
10*1
153571
15357Z
153558
15357*
1153578:
153579
153559
153560
153561
153582
153562
153583
15358*
153563
153586
1.535*9
1
II
Lab
Numbe.r
35008
35017
35009
35018
35010
35011
35012
35019
35013
35020
3501*
35015
35021
35022
35016
3503*
35035
35036
35037
35038
35039
350'iO
350*1
350*2
350*3
350*1*
350'i5
350 -'16
35001
350'i7
35002
35003
35023
Date
Coll.
8/27/*
tl
* 1 1
""
"
n
n
"
II
II
II
11
8/28/*
"
n
n
" II : :
II
II
II
II
"
."
II
II
8/27/**
8/28/*
8/27/*
n
8/28/*
Sta.tion Description
Bear R 6 Ed-V/yo Border
Boar R on Hwy 30 @ Thomas Crk
Bear R 1 mi -SW oF Peg ram
Bear R on Hwy 30 @ Alton Crk
Bear R @ Division Dam by Hwy
Bear'R @ Hwy Br Near Dingle
Bear R @ Rainbow Canal @ Br
Crockett Canal SE of Bloom ing tort
Bear Lake Outlet Blw Lifton
Pumping Plant
filoomington Cr near Bloomington
Bear Lake outlet 3 mi W of
Mont pel ier
Bear R @ Hwy 83 Br 2 mi W of
Montpel ier
Montpel ier or SW of Montpel ier
Ovid^r 3'min W of Montpel ier
Bear Canal 1i mi W of Hontpel ier
Georgetown Cr i mi W of Georgetown
Stauffer Cr 2 mi E of Movnan
Bear R 1 mi from Skinner Cr
8 mile Cr 5 misc of Soda Springs
Big Spring'Cr @ Weir of Trout Farm
Soda Spring Cr W of Soda Spr
Bear R. blw Soda Springs Res
Bear R 3 mi blw Grace Power Pit
Bear R @ Hwy Br W of Thatcher
Whiskey Cr 3 mi NE of Thatcher
Bear R W of Thatcher Powerhouse
Trout Cr i mi E of Thatcher
Williams Cr 3i mi S of Thatcher
Bear R i mi blw Oneidj
Mink Cr @ Hwy Culvert below Hwy 36'
Bear R @ Hwy 91 Bridge
U II II M
n n u ii.
Total
Col i form/
100 ml
100
200
200
330
800
110
220
810
350
170
50
500
*900
600
120
330
720
170
*30
"620 i:
- 600
60
*0
1100
1*0
150
360
*70
*00
800
220
200 .
300
Fecal
Col 1 form/
100 ml
*8
6*
62
5'-
130
3*
120
110'
2
60
.20
270
*800
110
30
170'
570
9*
150
M20 '*'.
'1*0 '
*
10
190 100
3* .
100
230
180
2
160
6*
52
100
Fecal
Strep/
100 ml
560
160
600
400
610
1100
1000
780
2
1200
130
1100
*500
*0
130
1200
1900
1500
550
;.650 .
:;120
180
980
,000
92
160.
520
350
900
9*0
120 .
830
2000
C-5
-------�
Table 1 (continued)
Storet
Station
Number
153549
153546
ii
11
"
153587
153599
1 1
II '
It
153539
153590
153545
"-3544
--,3591
153592
153593
153594
Lab
Number
35024
35027
35003
35006
35025
350/6
35048
35049
35004
35007-
35028 -
35029
3505-7
35050
35051
35052
35056
35053
35054
35055
Date
Coll.
8/28/4
n
8/27/4
n
8/28/4
"
n
Station Description
Bear R g Hwy 91 Bridge
n n n j.i
Bsar R S of Preston Airport
ii n n M
n n ii n
M n n n
n n M n
Total '
Col i form/
100 ml
270
150
170
140
110
130
50
" Sprin S of Oneida Rd W of PrestonlO.OOO
8/27/4
11
-a/28/4
II
1 1
1 1
1 1
1 1
1 1
1 1
II
II
.Bear R 3 mi W of Fairview
n n n n
Illl II II:
n ii n n
Cr N of West Pump Canal
Worm Cr abv Preston STP
Worm Cr below P;cston STP
Cub Canal S of Preston
Worm Cr g Culbert 2. mi W of
Frankl in
Cub R @ Diversion Dam 4 mi NE of
Frankl in
Cub R Hwy 91 Br i mi N of Franklin-
Cub R blw Del f'onte Discharge
390
320
130 -
140 '
4700
520
TNTC. 50
330
5700
690
200
430
Fecal
Co 1 i f o rm/
100 ml
100
120
50
56
64
90
10
2700
170
120
92 ;.;
no -
1300
90
,000
60
870
260
igd
130
Fecal
Strep/
100 ml
510
190
370
200
100
110
82
7800
350
650
56;.
390"
3800
2000
21,000
490
3500
620
1600
810
C-6
-------�
lABLE 2 - Comparison of bacterial populations from both residential and
rural areas on the Bear River ' '
Residential
Areas (1)
(12 samples)
Rural
Areas
(41 samples)
Total Coliforms
Mean -
Range .
5700
120->:50,000
kO~57CC
Fecal C ol i
Mean
Range
^500
60-50,000
150
. 2~k8QO
Fecal Strept
Mean
Range
3^00
*iO-21,000
3200
2-100,000
FC/FS Ratios
Mean
Range
0-8
0.1-2.8
0.3
0.01-1.6
1. Within ca. 3-~b sq miles radius of Montpcl iar, So-da Springs, Preston snd
Franklin.
C-7
-------�
TABLE 3 Isolation of Pseudomonas Aeruginasa and Staphyloccuj^.Xureus from the
Static;.
N uT.be r
153556
153568
153571
153561
153583
Ir358';
153587
153599'
153589
1535^5
153591
Lab.
Number
35068
35070
35071
350f,9
35072
35073
35061
35066
- 35062
35060
35063
Bear River
Date Station Description P. Aurug i nos~./( 1 ) S. Aurcus/l'
Collected <. 100 ml (confirmed) (Confirmed)
8/23/71) Bear R 0Hwy 89 Br 2 mi 0 0 .
* W. of Hontpel ier
" MontpeJier Cr SW of 0 1800
Moni;pel ier
" Georgetown Cr imi WO 0
of Georgetown
" Bear R @Hwy Br W of '*» kOO
Thatcher
" Trout Cr i mi E of 1 800
Thatcher
" W) 1 liams Cr 3i mi S of 0 700-
Th.'tcher
" Spring's S of Oneida'Rd 0 -0
W of Preston
" Bear R 3 mi W of F-airview 0 600
" " Cr N of West pi. p'canal iC 20 " .'..1200
" Worm Cr below Preston STP 10 0
" Worm Cr gculvert 2 mi W of AO 200 '
153592 3506'i
153593 35065
Franklin
Cub R ^Diversion Dam 4 mi
NE of Frank!in
Cub R Hwy 91 Br t mi N
of Franklin
80
1. Confirmed on Milk Agar
2. Confirmed by DfJase Acitivity t Coagulasc Reaction
C-8-
-------�
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1 ni 7
MFAN
3.50
3.00
l.ftO
3.70
2.45
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370.0 '
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410.0
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30.0
20.0
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1 535 7 1
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3 HI *g M
7n/ n.n
1119C050
DATF
MNT^F. |FK
/4/OH/27
STAT IHN
SU V«A>T,/L 1
140.0
I4O.O
CL
Ml. / L
7.0
7.0
IS04-II.T
1 .!<;/ L
H.O
M.O
I (1II4M) 1 01C 1 O0927 »
IFi.UimluE IZIMC (MfiMSUiM
l '^.DISS I/M.TIIT IHU.HJT
1 M./L | 01, /L 1 Mi./L »
0.12
0.12 .
1 Ml NF OF HFSM
o / o.n
1 1 ivcii5n
1
AT HI) H«
io/ n.n
1 114Cn50
STmlf-^FH CM AT HM ? M|
202. 5n/ 0.
1535/2
F. H,MT«IL.F. C«
1 h*>. sn/ o.
153174
io/ n.n
llisr.050
SI BK l MI
HO/ n.n
1 1 1SC050
/4/OW/27
74/OM/77
STAT ION
KIK MU'IITH
74/OH/77
74/n«/27
STATiriN
E NIIUMAN
74 /o H/ 2 7
STATION
AHV M'lUTH
7<./OH/?7
STATION
I3on
1 3n5
MEAN
1515
15?0
MEAN
1540
MEAN
1640'
MFAM
2.700
7.700
2.700
0.030
O.TI70
0.075
0.010
o.oio
O.O20
0.020
o.iuo
O.dlO
0.010
O.H80
O.H70
O.H75
n.o6o
0.060
o.ioo
0. 100
0.130
1). 130
0.130
0.140
0.210
0.700
O.OHO
O.OHO
0.040
0.040
55.00
55.00
55.00
34.00
34.00
42.00
42.00
247..0
253.0
250.0
244 .0
2C2.0
265.5
136.0
136.0
176.0
176.0
13.0
14.0
13.5
3.0
1.0
2.0
5.0
5.0
3.0
3.n
24.0
24.0
24.0
44. O
4h.O
45. O
4.0
4.0
2.0
2.0
HIT, C1*. a THI1IIT FA*,<1
I7s.no/ n.
153577
uii. i^s. CK a
I7s.no/ n.
15357R
SnOft CxFFK .2.
I74.2fl/ 3.
H153S75
SniiA CK a HX
174.20/ 0.
153574
40/ 0.0
1114C050
WE IK riF
4o/ n.o
1 1 1 4C050
5 MI HI.W
oo/ n.n
Hl4Cn5o
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20/ r,.o
1119C050
74/OH/2H
74/OH/7H
STAT ION
TMIMIT FARM
74/IIH/7H
74/OH/7K
STATION
hOOHFK SPK
74/OH/2H
STATION
MOUTH
74/08/2H
74/OH/2H
STAT ION
M450
0455
MEAN
mm
1015
MEAN
0425
MEAN
1150
1155
MEAN
0.020
0.020
0.070
0.730
0.260
0.245
0.100
0.100
0.070
O.OHO
0.075
2. BOO
2 .400
2.H50
7.400
2.400
2.400
0.540
0.540
0.750
0.740
0.745
0.040
0.050
0.045
0.040-
0.100
0 . 09 5
0.050
0.050
0.500
0.520
0.510
1.00
3.00
2.00
2.00
3.00
2.50
2.00
2.00
3.00
3.00
3.00
546.0
534.0
540.0
531.0
524.0
527.5
541.0
541.0
588.0
5H5.0
5fi6.5
52. n
53. n
52.5
45.0
46.0
45.5
5.0
5.0
3.0
1.0
2.0
UJH.O
110^0
109 .0
106.0
106.0
106.0
26.0
26.0
70.0
70.0
70.0
0.23 20.0 23.00
0.23 10.0 23.00
0.23 15.0 23.00
0.20 15.0 19.00
0.19 40.0 19.. 00
0.14 27.5 14. OO
0.11
0. 11
O.07
0.07
0.25
0.26
0.25
0.27 20.K 61.00.
0.27 30.0 61.00
0.27 25.0 61.00
0.2H 20.0 74'. 00
0.7H 20.0 74.00
0.42 - '
0.42
0.42
-------�
*
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» STnqFT
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IVF* MILFS
AC.FNCY «
OATF SUMMAMY
JHISKFY CK "AT HWY 34 HKIIH.F
145. «.o/ 1, in/ n.n 74/OH/?n 1315
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STATION MFAN
TKOIIT C*
134. 40/
4153SB3
WILLIAMS
134 .Mil/
M|f.iK CR
i<.
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f.FAN
MFAN
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1 00610 1 0062O | 006A 006HO | 0114 110 | OO94O ,| OO445 I
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1 TriFAL 1 TOTAL 1 1 C 1 CAC03 1 CL |SM4-lin 1
1 MU/I. | MI;/L I MI;/L v 1 Mf,/L 1 nr./L 1 M-./I. | «I;/L 1
0.070 2.300
0.030 2.300
0.075 2.300
O.O40
0.040
i
0.070
0.070
0.040
0.040
O.O'IO
n.090
0.030
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1 .300
1.300
1 .7no
1 .401)
1 .550
1 .000
1.000
0.170
0.120
o.6no
0.600
0.430
0.930
0.100
0.100
0.520
n.szn
0.740
o.2')n
0.64O
0.630
n.iin
0.110
0.110
0.040
0.040
0.1)30
0.030
O.OHO
O.OHO
O.OHO
O.OHO
0.060
0.100
0.100
0.750
0.750
1.170
1.120
1.145
3.00 366.0 40.0
3.00 374.0 40.0
3.00 370.0 40.0
3.00
3 . 0(1
4.00
4 . 00
5.00
5.00
4.00
4. on
4.00
4.00
4.00
4.00
19.00
19 .00
16.00
16.00
16.0O
306.0
306.0
21H.O
.21H.O
215.0
215.0
?B4.n
2B4.0
324.0
329.0
179.0
179.0
768.0
2H6.0
2H3.0
2«4.5
16. O
16. n
5.0
11.0
126. n
126.0
52.0
52. n
2.0
2.0
11.0
11.0
25.0
25.0
7,5.0
73.0
BO.O
76.5
37.0
32.0
7.0
2.0
12.0
12.0
62.0
62. fl
911.0
90.0
14.0
1.4.0
lf.0
16.0
20.0
24.0
22.0
004^)0 I 01092 00927 «
;l.linKIUE IZI\C iGMSIIIM *
t-.lMSS UN. TUT |Mf,.lUT »
if./L 1 IK./L 1 MU^L »
0.27
0.26
0. 11
0.11
0.07
0.07
0.24
0.74
0. 36
0.36
fl
0.74
0.24
0.12
0.12
0.32
0. 1?
Cl . 3 1
P.. 12
0.31
-------�
O
I-1
K)
*
Si IM'I NAMF
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Cllrt h a (>| w
7.nnx 7
»151SH|
Cllrt M :\ HWY
n.o X o
153544
r»Arc SIII'MAHY
DAM 4 M| NF FXANKI. IN
.OOX 4.4O 7<-XOH/?4 ]]4O
1 1 14C05II STAT ION MFAN
41 HH AMV
.0 X. 0.0
1 1 14C05(l
CHtt K V KD MK .5 M| HL
77. 7i)/ 20. 4DX 0.0
153542 111VC050
WOKM C*< il CH
77.7nx 1*,
Cllrt CAN a C"
77. 7n/ 15
o.n / o
HIlllt'F^ SPW-
i.n x o
« 1 5357*>
S^"* I " << .5 M|
n.n / (i
-1535HO
0.0 X 0
LU 3 Ml w
.50X O.O
LV .5K| w
. 10X 0.0
.0 X 0.0
1 MI M OF
.OX 0.0
1114C050
riei .-UINTF
7'-XnH/?4 0435
STATION MFAN
IIFI. MONTF.
74XHHX74 1070
/4XOHX24 in?5
STATION MFA^4
74xnHX7'; 1055
74XMHX24 .1 10(1
STATION MFAN
OF HHITNFY
74/OHX74 1115
74/OHX74 117O
STATION MFAN
74/nH/?7 1555
74XOHX77 lh()0
STATION MFAN
SIM1A S^H.
74XOMX7H O415
STAT ION MFAN
K CiF.M VALLFY CUFFS?
.0 / o.n ?4xoHx?H 1750
1119Cn5n STATION MEAN
S>J (IF NITF
.0 / 0.0
1 119C050
a
74XORX78 1310
STATION MFAN
1 nilMd |
1 TIITAI. 1
1 -i-Xi. 1
0.070
0.070
O.070
O.O20
O.O7O
0.070
0.020
0.030
0.030
O.030
(I.OSO
n.o5o
O.II5O
0.030
0.030
ti.ri30
0.50O
0.5(10
0.070
0.070
6.030
0.030
O(lft7(l 1 OOC- 1 ()06h() 1 00900 1 00440. | 00445 1 10SSO 1 (Vl(l4' Od<>27 »
NO3-M IPHUS- ,IT n«r, c ITOI HAKnicHLHMinFisiiLHAie IH.HHHIIIEIIINC .MIIMSIUM '
TOTAL 1 1 f. I CAC.n.3 | CL ISII4-TIIT | r.UISS I2N.TIIT |n(,.THT *
Mi;XL 1 MriXL f 1 Mt.XL 1 Mf.XL 1 MflXL 1 i-llXL 1 '-(-/I. | in.XL 1 v'I/L *
1.170
1 .170
0.740
0.240
0. 170
0.170
0.170
0.510
0.570
O.515
0.43O
0.450
0.440
3.4OO
3.400
3.400
0.010
0.010
2.600
3.000
3.000
0.370
0.370
0.04O
0.04O
O.O30
0.030
0.030
0.04O
0.040
0.040
0.750
0.250
0.750
' 0.10O
0.090
0.095
0.300
0.30O
1 .H40
1.R40
0.170 '
0.170
7.00 204.0
7.00 2(14.0
2.00 176.0
2.0O 176.0
2.00 175.0
2.00 173.0
2.0(1 . 1.74.0
. 3.0(1
3.U(i
3.0(1
10.00 212.0
H.OO 212.0
9.00 212.0
306.0
305.0
305.5
777.0
777.0
471.0
421.0
429 .0
429.0
11.0
11 .0
2.0
2.0
1.0
2.0
1.5
24. fi
24.0
24.0
1 .0
3.0
2.0
1.0
1.0
53.0
53.0
47.0
47.0
2H.O
12.0
12.0
14.0
12.0
13.0
16.0
1H.O
1V.O
4H.O
4H.O
4H.O
54.0
54.0
102. (1
102.0
92.0
42.0
0.32
0.32
0.10
0.10
o.tm
0.1)7
0.07
0.35
0.35
0.2*5
0.73
0.73
0.23
0.43
0.43
0.34
0.:-t9
0.27
0.27
20.0
20.0
20.0
25.0
20.0
22.5
10.0
20.0
15.0
10.0
10.0
15.0
15.0
25.0
25. o'
13.00
17.00
13.00
22.00
77.0W
27.00
77.00
71.00
71.50
12H.OO
12H.OO
62.00
63. OO
63.00
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* .
*
*
*
s
s
riiiN N»«F
H I VFS MlLFS
iTM.. M| rfEST OF fHFST'Vi
0.0 / 0.0 / 0.0 74/OH/29 OSOO
1535R7 111<*C050 STATION NFAN
1 00610
I NM3-N
1 TilTAI.
ir I MI; /i.
1 OOA70
1 NO3-N
1 TOTAL
i *I;/L
1 or s |
IPHIJS IT IT
1 1
1 »-/!. » 1
OO6BO
nun c
c
1 oog oo |
(MVI4.O |
O044>> |
ITOT HAKUir.Hl(li>!.OEISllOATe |l
I r.Acns I
r.l. ISU4-THT |
ftinio
1 010
-I.IMI1IDEIZINC
F.IHSS
I/\.T.IT
1 00427
IW.NS1UH «
IK;, TUT .«
nr,/L | Mf;/|. | h«;/L 1 iT./L 1 *«./'. I 1K./L 1 W-/L «
-
l.POO
r.?oo
H.600
7.^00
* t
o .070
0.02O
o.otn
o.(wo
0.300
O.OIO
0.1S5
4 .300
4.300
0.050
0.050
0.060
0.050
0.1)55
O.OHO
O.OhO
1.0(1
1.00
2.00
3.00
3.00
333.0
333.0
662 .0
326.0
4<>4.0
25V.O
. 251.0
546.0
546.0
6670.0
7430.0
7050.0
13.0
13.0
24(1.0
240.0
34.0
7H.O
56.0
24.0
24.0
1.00
1.00
4.40
5.40
5.15
0.34
0.34
20.0
20.0
50,0
5'>.0
50.0
50. ft
50.0
2H.OO
2H.OO
27.00
25. OO
26.00
34.00
34.00
.0
-------�
n
ST
M I Vf- W
» STiMFI a
nvin c- a HM
215. so/ 2
» 1 5 1S->4
FLil>4|Nr. HFLL
II. r) / O
.IS3S70
IIM NAMF
"IIFS
AUFNCY
3 M| Mv MO
. 70/ 0.0
1 114C050
1 MI NF OF
.') / 0.0
1114C050
t
iiFn-H.t-TOw.M CK AT an UK
21M.M'/ o
* 1 5 '< 5 7 I
SToMFFhK CH
202. Sri/ o
153->/2
Fli.riTMlLF C«
i-s.sn/ . n
* 1 S }> 74
. 1 0 / O.I)
1114C050
AT UK 7 M|
.10/ 0.11
1 1 l4Cnsn
a R« i MI
.HO/ O.O
II14COSO
IIATF SO-MAKY
74/dH/?7 1325
STAT ION MFAN
HFUN
74/nR/?7 lino
74/OH/77 1 3OS.
STATION WFA'4
NX WljlTH
/4/MB/77 1SI5
7t/iM/7.7 1520
STATION MFAN
E NOIiMAfj
74/OH/77 1540
SI AT ION MFAN
AhV MOUTH
74/dH/77 1641)
STA T ION MpAM
1 oonio I
1 WATFK 1
1 THMP |
1 CC-K'T 1
?1 .0
71.0
4 .7
4.7
4.7
17. R
17. S
17.6
20.5
70.5
17.0
17.0
OOO7I1
TIIMrt
JKSM
.ITU
2
7
2
7
7
7
12
12
7
?
1 ODD' |
ICNDIIC i . 1
IFIFLD 1
HICKOMMOI
360
360
6HO
6Hn
ftM0
5110
5 on
500
240
240
360
360
'003(IO 1 0040(1 |
DU 1 PH |
1 1
MT,/L- 1 Sll 1
7.2
.7.2
? H H A
1.5 6.6
2.1 6.6
7.4 7.6
7.4 7.4
7.6 7.5
10.6 7.fl
10.6 7.H
H . ft 7.5
H.6 7.5
OO410.
T AH
CAC.U3
fllWi.
2>*O .11
24H.O
264;0
237.0
247.0
234.5
135.0
135.0
1RO.O
IHO.O
I (HI SOU
(RESIDUE
1 TOTAL
1 KI./L
IHO.d
1 Hll.O
331 .(1
243.0
312.0
245.0
401 .0
34M.O
224.0
224.0
235.0
235.0
HII. LM. a TMIIUT FAMM
17S.nO/ 0
.153577
UK. V< CK
1 75. ()()/ (1
«1S1S7H
SO.IA OFFK .
1 7 4' . 6 CK a 8»
174. 2
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* 1 00010 1
* S ION NAME 1 WATF.H 1
* K|Vf-K MILFS 1 TEMP I
* STOrtET » AGFNC.Y l OATF SHiiMAKY 1 CFMT 1
**aaa*aa****a***aaa»aa«oa*«aaaaaa»a*v»»*aa**»««««**a«
CHn H a OIV 0AM 4 M| NE FKANKLIN
7.00/ 7.00/ 4.40 74/OH/J") 1140
1535-n 111VC050 STATION KF.AN
ClIH X a HWY Ml RR AHV (1FL MONTF
O.O / (1.0 / O.n 7'/(>H/?.<< OS35
*1535<«4 Iimco50 STATION MEAN
C"tt K a Rll RK .5 Ml Rl OFI. MONTR
77. 70/ 2d. ^O/ 0.0 Y4/rm/2v 1100
STATION MEAN
Clio CAM a CULV . 5Mi w OF '-IHITNFY
77.7fiv 15. io/ o.n 74/nn/?y ins
15354* 1114f.n5n 7«-/nH/?y ll?n
STATION MFAN
StMINi; 1.5 MI w. OF GEOHi-FTOWN
n.n / o.n / n.n 74/nH/?7 1555
151571 1119CO5O V4/nH/27 IftOO
STATIDN MEAN
Hd.iPHri SHR- i HI N in- SIIIIA SPR.
o.o / n.n / o.n 74/im/7n om5
is^syi uii<
o.o / 0,0 / n.n 74/on/7H mn
K1535H1 111SCOV) STATION UFAN
Ift
1ft
11
13
11
1 1
11
1«
IH
IR
.1ft
14
15
17
12
1?
11
11
14
14
14
14
.5
.5
.ft
.ft
.ft
.4
.5
.0
.0
.0
.5
.0
.?
.1
.5
3
.ft
.ft
.0
.0
.0
.0
onoyn i no i 00300 I 00400 1 004 m i 00500 I 00505
TIIXIV ICNUIH. . jv\ on \ CH IT AL< IRESIUUE. IMFSIUKE
,IKSN IFIFLI) I.I 1 CAf.113 1 TllTAL |T"lT VIIL
JTll JHICKOMHOI MT./L 1 Stl 1 M(J/i. 1 W./L 1 'M(-/L
ft5
ft5
ft
ft
1
2
2
)
3
3
11
10
11
4
5
5
3
3
2
?
1
1
ft?n
ft?0
400
400
400
3Hn
3-
115.0
?3l.O
173.0
3Bh.O
^hh.O
7O7.O
707.0
IHft.O
IHh.O
1 005: 1 O0535 *
Hill Nl-LTIVIIL NFLT*
***»a *****«*«****«
12*. 0
' 12H.O
3.0
3.0
2.0
10.0
ft.O
3ft. 0
2H.O
32.0
20.0
l^.o
is -«.
ft.O
ft.O
1.0
1.0
2.0
2.0
12.0
12.0
1.0
1.0
1.0
2.0
1.5
ft.O
K.O
7.0
3.0
2.0
2.5
2.0
2.0
1.0
1.0
2.0
2.0
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,
STATION
a i vm H
STIiuFT
NAMF
H.F1
A(,F»-CY flATF
SUMMARY
1 OOO1D 1
1 WATFK |
I TFMf |
i C.EWT i
00070 I or. |
TIIMH ir.NOiiciVYi
JK'iN (FIELD 1
JTII IMICHI1MHIII
OO3IIO | OO4OO |
no i fh i
1 1
MO/L I SU 1
00*10
T ALK
r.*r.ii3
MG/L
| OOMIO | OU5O5
1 OOS
(MESIIHlE IKF^IIUiE 1 WE SI DUc
1 TOTAL ITIIT VUL
1 r(,/L | Ml, /I.
(Till N
1 Mr,/
^LT
L
1 0(1535
IKtSIDUE
ivnt ^4FLl
1 M(./L
*
*
F»
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O.O / O.O
i-nsHS
Suiiau HUT Sf*
0.0 / 0.0
1S3S47
SfrtlM. l.S Ml
0.0 / O.O
al53S«7.
/ n.O 74/OH/2H
1114C050 STATION
3 Hi NW (Ih fUrSTri*
/ 0.0 7*/OH/2S
11.14C05II 74/MH/24
STAT ION
WEST (IF MMFST'KI
/ 0.0 -74/dH/?9
1 1 1SC050 STAT ION
1*30
MFAN
4
OH^S
(IH30
MEAN
0900
MEAN
13.0
13.0
hS .0
M? .0
73.5
U.5
11.5
I f> AOO
1ft ^00
3 1000
31 1000
17 1000
H I30O
H 1300
.15.9
15. V
.
ft. 3
ft. 2
ft. 2
7. ft
7.h
3^4.0
3H<< .11
5«5 .0
570.0
577.5
250.0
250.0
1M}*.0 110. 0
IH3"..0' 110. 0
15343.0 .1H7*.0
IMTl.fl 3450.0
15757.0 3ftft2.0
*5/.0 151.0
457.0 151.0
2
2
13
3
H
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S
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2.0
2.0
3.0
l.n
2.0
2.0
' 2.0
n
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*
* STA .N NAMF
* 4ivFM MII.FS
» ST'wFT * AI;FNCV
I 011)0?
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<;HM»AKY i IK./I.
I 01077 ( 1)104' O1045 I 01051 I 7 IV'tO I DO'' 2-v I nciv 1 J I 3-1 JIO 712?"
ICAHHIIIM ICIICfeK . IMflN (LEAD iMfKf.llkV ISIIIlllIM (P1SSHIH I STA^H ,r AfllR *
ico.inr ICII.TMT IFF.. TOT IPH.TOT IMG, HHALINA. mi -IK.IHT MH« CUMI-I w*TtK *
i ur,/t I ur./L I IH;/L I U<;/L I nr./L I «U/L I «c;/i. I /IOOHL
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n.n /
153S76
st-mMr, .>
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1S3SHO
SfKIM. 1
n.n /
«l"5«I
n.n / o.n 74/nH/?8 nvis
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M| fc GFM Vil.LFY f.HFF.SF
n.o / o.o /4/OH/pH i25o 1.10
lllyCOSO STATION MRAN 1 . HO
MI SW OF NITFH
O.O / O.I) 74/llM/?H 13ln ?.20
111«H.UO
I '1.0(1
13.00
K.CIO
H . DO
6. /O
6. 70
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n.o /*
«l->3-5«S
SUUaW HUT
0.0 /
153S47
t^ 0.0 /
I'l^SHY
O.I) / O.O 74/OH/7H 1410 7O.OO
IHSCOSO STATION MFAN 7O.OO
Sk"< 3 Ml NW n\r CK^STON
o.n / o.^ /4/(iM/?v (\H?"I 25.no
U1SCOS,, 74/OH/7^ OH3O 32. OO
STAT ION MFAN 2^.50
5 M| riFST OF KKFSTON
n.o / o.n 74/on/?9 oyoo S.AO
1UWC050 74/nH/2<< 1015
STATION MFAN 5. 60
h.OO
6 .00
24.00T
25.00
24.50
4.00
4.00
S .(10 Q6O.O
1.OO 4611. U
47.00 NOO.O
65.00 235O.O
56.00 1575.0
W.OO 5HO.O
A. 00 5SO.O
45.0
45.0
1 10.0
\00.0
105.0
20.0
20.0
0.6O
O.hO
O.HO
1.70
1.00
O.20
0.20
SMI. (HI
JM) .0(1
5000.00
5000.00
29.00
21.00
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HO. (ID
7M>. 00
760.00
fl
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O.O 0.0
H.OO O.O 0.0
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I 1110(12 I OHM/ I did'
I
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01045 I 01O51
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714(1(1 J 0(1424 I 00447 I 31710 7122O
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*
Mil
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141
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7 7.
151
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7.
151
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/4/OK/24
STATION
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74 /OH/24
STATION
E FKANO 111
0.0 74/OH/79 '1115
4CO'jo /V08/24 1 170
STATION MFAN
IIP (,F(IK(,FTOWN
0.0 74/OH/77 1555'
<*C05O 74/HM/27 160O
STATKIN MFAN
5.00
4.50
4.75
I .70
2.00
1 .60
2.0O
2.0()
2.00
6.00
6. (10
6.00
4.00
4.00
4.00
. 710.0
570.0
640.0
520.0
560.0
540.0
15.0
15.0
15.0
20.0
20.0
20.0
V
0.6O
O.60
0.6(1
37.00
37.00
37.00
6.50
6.40
6. 45
7. MO
7. HO
7. MO
1.30
1.30-
1.30
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* ' ,1 OHM (I I 00*70 I 00 '< | 00*HO | 00900 I 00940 I 0(1445 I 00950 I 0Ul | n(i<>27 *
* .' ; I ON NAME | NH3-N | N03-N IPHOS (TIT OMB C I TOT HAKIll CHtU« I lit I SMl>A I E I H.l«m IDEIi IMC (HGNSIUM *
* HI.VFU MILFS I TOTil. I TflTAL I I C I CACH3 I CL ISII4-THT | »:.lilSS UN.TUT |h BR 1 "-i NE
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I4 3
0.200
0.140
0.195
0.050
O.OhO
O.OhO
0.057
o.nhn
0.070
0.0*5
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O.OHO
0.070
o.n77
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0.070
O.OH5
5H.oo
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4.00
21.33
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5.00
5.50
5H.OO
8. on
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24.00
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5.00
h.50
339.0
32H.O
325.0
33n.7
310.0
312.0
31 1 .0
340.0
337.0
3 1*. 0
311.0
32H.O
330.0
329.0
3H.O
3H.O
3H.O
3H.O
3H.O
39 .0
3H,5
39.0
40.0
34.0
39.1
41.0
40.0
40.5
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90.0
7H.7
42.0
92.0
92.0
40.0
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77.7
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0. 19
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0.20
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0. 14
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0. 19
0.20
0.20
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