Office of Solid Waste and EPA-542-R-11-007
Emergency Response November 2011
(5102G) www.epa.gov/tio
www.clu-in.org/optimization
Remediation System Evaluation (RSE)
Vineland Chemical Company Superfund Site
Vineland, New Jersey
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REMEDIATION SYSTEM EVALUATION
VINELAND CHEMICAL COMPANY SUPERFUND SITE
VINELAND, NEW JERSEY
Report of the Remediation System Evaluation
Site Visit Conducted at the Vineland Chemical Company Superfund Site
April 27-28, 2010
Final Report
March 11, 2011
Prepared by
GeoTrans, Inc.
U.S. Army Corps of Engineers - Philadelphia District
U.S. Army Corps of Engineers Environmental and Munitions Center of Expertise
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NOTICE
Work described herein was performed by GeoTrans, Inc. (GeoTrans) for the U.S. Environmental
Protection Agency (U.S. E.P.A) and the U.S. Army Corps of Engineers Environmental and Munitions
Center of Expertise in Omaha, Nebraska and Philadelphia District. Work conducted by GeoTrans,
including preparation of this report, was performed under Work Assignment #1-58 of EPA contract EP-
W-07-078 with Tetra Tech EM, Inc., Chicago, Illinois. Mention of trade names or commercial products
does not constitute endorsement or recommendation for use.
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PREFACE
This report was prepared as part of a project conducted by the United States Environmental Protection
Agency Office of Superfund Remediation and Technology Innovation (U.S. EPA OSRTI) in support of
the "Action Plan for Ground Water Remedy Optimization" (OSWER 9283.1-25, August 25, 2004). The
objective of this project is to conduct Remediation System Evaluations (RSEs) at selected pump and treat
(P&T) systems that are jointly funded by EPA and the associated State agency. The project contacts are
as follows:
Organization
Key Contact
Contact Information
U.S. EPA Office of Superfund
Remediation and Technology
Innovation
(OSRTI)
Kathy Yager
U.S. EPA Technology Innovation and
Field Services Division
11 Technology Drive (ECA/OEME)
North Chelmsford, MA 01863
617-918-8362 (phone)
yager.kathleen@epa.gov
Tetra Tech EM, Inc.
(Contractor to EPA)
Carla Buriks
Tetra Tech EM, Inc.
1881 Campus Commons Drive, Suite 200
Reston,VA20191
phone: 703-390-0616
carla.buriks@tetratech.com
GeoTrans, Inc.
(Contractor to Tetra Tech EM, Inc.)
Doug Sutton
GeoTrans, Inc.
2 Paragon Way
Freehold, NJ 07728
phone: 732-409-0344
dsutton@geotransinc. com
U.S. Army Corps of Engineers
Dave Becker
U.S. Army Corps of Engineers
Environmental and Munitions Center of
Expertise
Omaha, Nebraska
phone: 402-697-2655
Dave.J.Becker@usace.army.mil
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TABLE OF CONTENTS
NOTICE i
PREFACE ii
TABLE OF CONTENTS iii
1.0 INTRODUCTION 1
1.1 PURPOSE 1
1.2 TEAM COMPOSITION 2
1.3 DOCUMENTS REVIEWED 2
1.4 PERSONS CONTACTED 2
1.5 BASIC SITE INFORMATION AND SCOPE OF REVIEW 3
1.5.1 LOCATION 3
1.5.2 SITE HISTORY, POTENTIAL SOURCES, AND RSE SCOPE 3
1.5.3 HYDROGEOLOGIC SETTING 4
1.5.4 POTENTIAL RECEPTORS 5
1.5.5 DESCRIPTION OF GROUNDWATER PLUME 5
2.0 SYSTEM DESCRIPTION 7
2.1 EXTRACTION SYSTEM 7
2.2 TREATMENT SYSTEM 8
2.3 MONITORING PROGRAM 9
3.0 SYSTEM OBJECTIVES, PERFORMANCE, AND CLOSURE CRITERIA 11
3.1 CURRENT SYSTEM OBJECTIVES AND CLOSURE CRITERIA 11
3.2 TREATMENT PLANT OPERATION STANDARDS 11
4.0 FINDINGS 13
4.1 GENERAL FINDINGS 13
4.2 SUBSURFACE PERFORMANCE AND RESPONSE 13
4.2.1 PLUME CAPTURE 13
4.2.2 GROUNDWATER CONTAMINANT CONCENTRATION TRENDS 15
4.2.3 SITE-SPECIFIC GEOCHEMISTRY 17
4.2.4 CONCEPTUAL MODEL INPUT AND DATA GAPS 18
4.3 MONITORING PROGRAM EFFECTIVENESS 20
4.4 COMPONENT PERFORMANCE 21
4.4.1 EXTRACTION WELLS 21
4.4.2 EQUALIZATION TANK 21
4.4.3 CHEMICAL ADDITION AND FLOCCULATION 22
4.4.4 DISSOLVED AIR FLOTATION 22
4.4.5 FILTRATION 23
4.4.6 SOLIDS DEWATERING 23
4.4.7 SYSTEM CONTROLS 23
4.4.8 DISCHARGE OF TREATED WATER 23
4.4.9 PROCESS AND ADMINISTRATIVE FACILITIES 24
in
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4.5 COMPONENTS OR PROCESSES THAT ACCOUNT FOR MAJORITY OF ANNUAL COSTS 24
4.5.1 UTILITIES 24
4.5.2 NON-UTILITY CONSUMABLES AND DISPOSAL COSTS 25
4.5.3 LABOR 25
4.5.4 CHEMICAL ANALYSIS 25
4.5.5 OTHER COSTS 25
4.6 APPROXIMATE ENVIRONMENTAL FOOTPRINTS ASSOCIATED WITH REMEDY 26
4.6.1 ENERGY, AIR EMISSIONS, AND GREENHOUSE GASES 26
4.6.2 WATER RESOURCES 27
4.6.3 LAND AND ECOSYSTEMS 27
4.6.4 MATERIALS USAGE AND WASTE DISPOSAL 27
4.7 RECURRING PROBLEMS OR ISSUES 27
4.8 REGULATORY COMPLIANCE 27
4.9 SAFETY RECORD 27
5.0 EFFECTIVENESS OF THE SYSTEM TO PROTECT HUMAN HEALTH AND THE
ENVIRONMENT 28
5.1 GROUNDWATER 28
5.2 SURFACE WATER 28
5.3 AIR 28
5.4 SOIL 28
5.5 WETLANDS AND SEDIMENTS 29
6.0 RECOMMENDATIONS 30
6.1 RECOMMENDATIONS TO IMPROVE EFFECTIVENESS 30
6.1.1 FURTHER CHARACTERIZE EXTENT OF CONTAMINATION 30
6.1.2 CONSIDER MODIFICATIONS TO THE GROUNDWATER EXTRACTION SYSTEM TO
ASSURE CAPTURE 30
6.1.3 ADDITIONAL MONITORING OF GROUNDWATER QUALITY BETWEEN EXTRACTION
WELLS AND BLACKWATERBRANCH 30
6.2 RECOMMENDATIONS TO REDUCE COSTS 31
6.2.1 DISCONTINUE AUTOMATED SAMPLER AND Do NOT REPLACE THE UNIT 31
6.2.2 ELIMINATE ROUTINE ON-SITE ARSENIC SAMPLING 31
6.2.3 REDUCE EXTRACTION RATES TO THOSE THAT ARE NECESSARY FOR PLUME
CAPTURE 32
6.2.4 EVALUATE GROUND WATER MONITORING COSTS 33
6.2.5 CONTINUE TO OPTIMIZE GROUNDWATER MONITORING PROGRAM 33
6.2.6 Focus BUILDING HEATING AND LIGHTING ON KEY PROCESS AREA 34
6.2.7 EVALUATE CHEMICAL USAGE 34
6.2.8 CONSIDER USE OF A PLATE AND FRAME FILTER PRESS TO DEWATER SOLIDS .. 35
6.2.9 CONSIDER THE USE OF LIME FOR PH ADJUSTMENT 36
6.2.10 CONTINUE TO STREAMLINE PLANT AND PROJECT STAFFING 36
6.2.11 BASED ON OUTCOME OF OTHER RECOMMENDATIONS, CONSIDER POTENTIAL
FORDELISTING WASTE SLUDGE 37
6.3 RECOMMENDATIONS FOR TECHNICAL IMPROVEMENT 38
6.3.1 REFINE WELL REHABILITATION PRACTICES 38
IV
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6.3.2 DISCONTINUE USE OF CURTAINS AND ELECTRICAL HEATERS FOR SAND FILTERS
38
6.3.3 CONTINUE WITH PLAN TO REMOVE SOIL WASHING EQUIPMENT FROM THE SITE ..
39
6.3.4 PREPARE AN ANNUAL REPORT 39
6.4 CONSIDERATIONS FOR GAINING SITE CLOSE OUT 39
6.4.1 EVALUATE POTENTIAL FOR NATURAL ATTENUATION AND SUGGESTED
CRITERIA FOR DISCONTINUING P&T 39
6.4.2 ACTIVE IN-SITU TREATMENT FOR ARSENIC IMMOBILIZATION 43
6.5 SUGGESTED APPROACH TO IMPLEMENTING RECOMMENDATIONS 44
6.6 EXIT STRATEGY 44
6.6.1 SUGGESTED EXIT STRATEGY 44
6.7 ADDITIONAL SUSTAINABILITY CONSIDERATIONS 46
6.7.1 CONSIDER COMBINED HEAT AND POWER 46
6.7.2 CONSIDER ALTERNATIVES FOR IRON ADDITION 47
6.7.3 POSTPONE LIGHTING RETROFIT 48
Tables
Table 4-1. Summary of Trend Analyses -2000 to 2010
Table 4-2. Trend Plots in Recovery wells and Estimation of Restoration Time (EPA, 2002)
Table 6-1. Cost Summary Table
Figure 2-1. Treatment System as Designed
Figure 2-2. Treatment System as Currently Configured
Figure 4-1. Potentiometric Contours Prepared by RSE Team - 2010 Water Levels, Shallow Wells
Figure 4-2. Potentiometric Contours Prepared by RSE Team - 2010 Water Levels, Mid-Depth Wells
Figure 6-1. Potential Arrangement of Extraction, Injection, and Chemical Addition
Attachments
Attachment A - Selected Figures from Previous Site Reports
Attachment B - Plots of Arsenic Concentration Over Time
Attachment C - Arsenic Extent in the Shallow and Mid-Depth Wells for 2002-2003 and 2008-2009
Attachment D - Arsenic Trends with Linear Regression in Recovery Wells
Attachment E - Metals Concentrations in Area 5 Soils and Ground Water
Attachment F - MAROS Analysis
Attachment G - Footprint Analysis Spreadsheets
Attachment H - Assessment of Issues Related to Delisting Sludge
Attachment I - Recommended Parameters for Geochemical Analysis
v
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1.0 INTRODUCTION
1.1 PURPOSE
During fiscal years 2000 and 2001 independent reviews called Remediation System Evaluations (RSEs)
were conducted at 20 operating Fund-lead pump and treat (P&T) sites (i.e., those sites with P&T systems
funded and managed by Superfund and the States). Due to the opportunities for system optimization that
arose from those RSEs, EPA Office of Superfund Remediation and Technology Innovation (OSRTI) has
incorporated RSEs into a larger post-construction complete strategy for Fund-lead remedies as
documented in OSWER Directive No. 9283.1-25, Action Plan for Ground Water Remedy Optimization. A
strong interest in sustainability has also developed in the private sector and within Federal, State, and
Municipal governments. Consistent with this interest, OSRTI has developed a Green Remediation Primer
(http://cluin.org/greenremediation/) and now as a pilot effort considers green remediation during
independent evaluations.
The RSE process involves a team of expert hydrogeologists and engineers that are independent of the site,
conducting a third-party evaluation of the operating remedy. It is a broad evaluation that considers the
goals of the remedy, site conceptual model, available site data, performance considerations,
protectiveness, cost-effectiveness, closure strategy, and sustainability. The evaluation includes reviewing
site documents, potentially visiting the site for one day, and compiling a report that includes
recommendations in the following categories:
Protectiveness
Cost-effectiveness
Technical improvement
Site closure
Sustainability
The recommendations are intended to help the site team identify opportunities for improvements. In
many cases, further analysis of a recommendation, beyond that provided in this report, may be needed
prior to implementation of the recommendation. Note that the recommendations are based on an
independent evaluation, and represent the opinions of the evaluation team. These recommendations do
not constitute requirements for future action, but rather are provided for consideration by the Region and
other site stakeholders.
The Vineland Chemical Company Superfund Site was selected by EPA OSRTI based on
recommendations from the EPA Remedial Project Manager for the site and from the U.S. Army Corps of
Engineers (USAGE) Philadelphia District that provides oversight of remedial activities on behalf of EPA.
The site is located in Vineland, New Jersey and consists of several operable units. This RSE specifically
addresses Operable Unit 2 (OU2), which manages migration of the groundwater contaminant plume. The
OU2 remedy is in the seventh year of a Long-Term Remedial Action (LTRA). In 2014, the responsibility
for the OU2 remedy will be transferred to the State of New Jersey Department of Environmental
Protection (NJDEP).
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1.2 TEAM COMPOSITION
The RSE team consists of the following individuals:
Name
Dave Becker
Lily Sehayek
Doug Sutton
Affiliation
USAGE - Omaha
USAGE - Philadelphia
Geo Trans, Inc.
Phone
402-697-2655
215-656-6463
732-409-0344
Email
Dave.J.Becker@usace.army.mil
Lily. Sehayek@usace.army.mil
dsutton@geotransinc.com
In addition, the following individuals from EPA OSRTI participated in the RSE site visit.
Kate Garufi
Kirby Biggs
1.3 DOCUMENTS REVIEWED
The RSE team largely relied on data in electronic form provided by the USAGE Philadelphia District and
Sevenson Environmental, the operating contractor. These data included a data base of sampling results
(contaminant concentrations and geochemical parameters) for groundwater, surface water, and process
monitoring. Other electronic data provided to the RSE team included flow rates and meter readings,
operations costs, and as-built drawings. The Philadelphia District also provided several PowerPoint files
with figures of contaminant extent, hydrogeological setting, water levels, and other parameters.
Other documentation included:
Record of Decision for the Vineland Chemical Superfund Site, 1989
Explanation of Significant Differences, Vineland Chemical Superfund Site, 2001
NAD Groundwater Center of Excellence Memo dated 2-21-2010, Impacts from turning off
Vineland Superfund Site recovery wells
Operations Manual, Vineland Chemical Company Superfund Site, OU-2 Groundwater Treatment
Plant SCADA Upgrade
Classification Exception Area and Well Restriction Area Report for Vineland Chemical
Company Superfund Site, USAGE Philadelphia District, May 2007
An analysis of lighting options by Veteran Energy Technology, December 2009
1.4 PERSONS CONTACTED
The following individuals associated with the site were present for the visit:
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Name
Ron Naman
Laura Bittner
Mark Chamberlain
Eric Charlier
Steve Creighton
Steve Gillespie
Tom O'Neill
Ken Quirk
Dan Sirkis
Glen Stevens
Chad Van Sciver
Charles Van Winkle
Rich Vona
Affiliation
EPA-RPM
USACE
USACE
USACE
USACE
Sevenson
NJDEP
USACE
USACE
USACE
NJDEP
Sevenson
USACE
Phone Email
212-637-4375 Naman. ronald(g,epa. gov
1.5 BASIC SITE INFORMATION AND SCOPE OF REVIEW
1.5.1
LOCATION
The Vineland Chemical Superfund Site is located in the northwestern portion of Vineland, in Cumberland
County, south central New Jersey, in an area of mixed industrial, low-density residential and agricultural
properties. The site is bordered immediately to the north by other industrial properties and the
Blackwater Branch, a perennial stream that flows westward to the Maurice River. See Attachment A for
figures that illustrate the site location.
1.5.2
SITE HISTORY, POTENTIAL SOURCES, AND RSE SCOPE
The text in this section has been extracted from the 1989 Record of Decision (ROD) and the 2001
Explanation of Significant Difference (BSD). The Vineland Chemical Company operated from 1949 to
1994 and produced arsenical herbicides and fungicides. There were twelve buildings and five abandoned
chicken coops on the plant site. Some of these structures were used by the Vineland Chemical Company
for various manufacturing purposes.
As early as 1966, the New Jersey Department of Health observed untreated wastewater being discharged
into unlined lagoons at the Vineland site. This wastewater was contaminated with arsenic at
concentrations up to 67,000 parts per billion (ppb). Waste salts containing 1-2 percent arsenic were stored
outside in uncovered piles. Precipitation dissolved some of these salts and carried them into the
groundwater and eventually into nearby surface water bodies. Contaminated sediment was mapped 1.5
miles downstream in Blackwater Branch to its confluence with the Maurice River and then 7.5 miles
downstream to Union Lake.
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In 1988, EPA conducted a Remedial Investigation and Feasibility Study (RI/FS) to determine the nature
and extent of the contamination and to develop remedial alternatives to address the contamination. The
ROD was signed in 1989 and called for in-situ soil flushing of contaminated site soils, management of
migration for contaminated groundwater through groundwater extraction and treatment with either re-
injection or discharge to surface water of the treated water. Contaminated sediment along the Blackwater
Branch was to be excavated and treated by ex-situ soil washing following establishment of control of
contaminated groundwater through the extraction system. If natural processes do not allow attainment of
action levels, additional excavation/dredging of sediment in the Maurice River would be conducted.
Contaminated sediments near the shore of Union Lake were to be dredged and removed. The
groundwater extraction and treatment system was constructed and first started operation in 2000.
An BSD was signed in 2001 that modified the remedy for on-site soils to be ex-situ soil washing.
Excavation and treatment of soils on the Vine land Chemical Site began in 2003 and was completed in
2007. The Blackwater Branch west of the site is currently undergoing remediation. A portion of the
stream north of the site has been remediated and restored.
1.5.3 HYDROGEOLOGIC SETTING
The text in this section is extracted from the Classification Exception Area and Well Restriction Area
Report (CEA Report). The site is located in the Atlantic Coastal Plain physiographic province, which
consists of a seaward-dipping wedge of unconsolidated sediments (sand, silt, clay, and gravel) that range
in age from Cretaceous to Quaternary. Locally the site is situated on a relatively level plain that slopes
slightly from the southeast toward the northwest with topographic elevations that range from 65 to 75 feet
above mean sea level.
Groundwater levels vary seasonally at the site with an average of approximately 10 feet below ground
surface (bgs), and atypical minimum and maximum of between 4 and 19 feet bgs. Shallow groundwater
at the site occurs within the Kirkwood-Cohansey aquifer system. Three distinct hydrogeologic units have
been identified during previous investigations (including split-spoon sampling and borehole geophysical
logging) completed at the site: 1) Shallow Cohansey upper sand (0 to 70 feet bgs); 2) Banded Zone (35 to
70 feet bgs); and 3) Middle Cohansey sand (60 to 125 feet bgs). The shallow and middle Cohansey
aquifers generally consist of fine to coarse grained sand with little fine material (i.e., clay). The Banded
Zone, which is situated between the shallow and middle aquifer zones, consists of alternating layers of
sand, silt, and clay, and has an average thickness of about 10 to 25 feet. It is likely that this unit acts as a
leaky, semi-confining layer and may impede shallow contamination from migrating vertically to the
deeper aquifer zones.
Under non-pumping conditions, groundwater flow in the shallow Cohansey aquifer at the site is toward
the west - northwest (see Attachment A). Attachment A also includes figures depicting the shallow
Cohansey aquifer groundwater elevations measured in 2003 at the site shallow monitoring wells and mid-
depth monitoring wells. The groundwater elevations of the extraction wells are not included in this water
elevation contouring. The direction and gradient of flow are consistent with both previous and recent
groundwater elevation monitoring.
Groundwater modeling of the site indicates that the hydraulic conductivity at the site ranges from 350 to
700 feet per day. The hydraulic gradient ranges from approximately 0.0017 to 0.002 feet per foot.
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1.5.4 POTENTIAL RECEPTORS
The text in this section is extracted from the CEA Report. Previous investigations included well inventory
searches in the site vicinity to identify potential water users that may affect water levels at the site. The
only public well identified within a 1-mile radius of the site is owned by the Vineland Water Authority
(VWA). This well is located along Mill Road, approximately 9/10 of a mile south of the site. The VWA
has also indicated that this supply well is only used as a backup water supply source and that there are no
other VWA or industrial supply wells near the site. In addition, all residential, commercial, and industrial
properties in the area (and identified during the survey) are connected to the public water supply system
operated by the VWA.
The NJDEP Bureau of Water Allocation (BWA) database was also reviewed for potential supply wells in
the area. One well identified from this search was an irrigation well with a capacity of 400 gpm, that is
reportedly located at the intersection of Garden and Mill Roads, approximately 1 mile north of the site.
However, a visual search by the site team of this area did not reveal the location of this well.
Blackwater Branch and surface water downstream of the Blackwater Branch, including the Maurice River
and Union Lake, are the primary potential receptors of groundwater contamination. The objectives of the
Record of Decision, as discussed in Section 3.0 of this report are focused on protecting and restoring
Blackwater Branch.
1.5.5 DESCRIPTION OF GROUNDWATER PLUME
Groundwater contaminated by both organic and inorganic arsenic is generally limited to the Shallow
Cohansey aquifer. Approximately eight monitoring wells are currently sampled in the deeper Middle
Cohansey aquifer (below the Banded Zone aquitard) and arsenic has not been detected since 2006.
The Shallow Cohansey aquifer has been subdivided into shallow and "mid-depth" portions. Well pairs
consisting of shallow and mid-depth wells have generally been installed (in some cases including a deeper
Middle Cohansey aquifer monitoring well) at the site. Arsenic concentrations above the current
maximum contaminant level (10 ug/L) are more wide spread in the shallow portion of the Shallow
Cohansey and concentrations range from non-detect to approximately 3000 ug/L. Higher concentrations
are currently found in the mid-depth wells (to over 8000 ug/L). There are apparently two overlapping
arsenic plumes; one in the northern portion of the site and another in the southern portion. The plumes
extend from the former locations of production and storage of product under North Mill Road toward the
west-northwest toward Blackwater Branch. The plumes (of total arsenic concentration) are shown in
figures included in Attachment A.
Note that anomalously high concentrations greater than 2000 ug/L of arsenic have been found north of the
Blackwater Branch west of North Mill Road (MW-54S). This location near Blackwater Branch would be
expected to be a discharge point for groundwater migrating from the north to surface water, so discovery
of the contamination across the stream from the site was unexpected. The high concentrations in MW-
54S are along the projected extension of the axis of the northern plume if extended across the stream.
Note that there are records of an irrigation well with a 400 gpm capacity north of the site along North Mill
Road (near its intersection with Garden Road), though this well could not be located (USAGE, 2007). It
is not clear if the pumping of that well could pull the plume under the stream. There are also anecdotal
reports of waste disposal (presumably by Vineland Chemical Company staff) in the area across
Blackwater Branch. Recent direct-push sampling has apparently defined the northern and western limits
of the high concentrations north of Blackwater Branch, as reported by USAGE Philadelphia District staff
during the site visit.
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The speciation of arsenic is periodically done and arsenic is generally found in the arsenate form, though
arsenite concentrations can be higher. Organic arsenic compounds, are not as common. Refer to Section
4.2.3 for additional discussion of the speciation of arsenic reaching the treatment plant.
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2.0 SYSTEM DESCRIPTION
The groundwater extraction and treatment system consists of 16 extraction wells; extraction piping; a
treatment plant including oxidation, flocculation, and separation processes; and piping for discharge of
the treated water to Blackwater Branch. In addition, a monitoring well network has been established
consisting of at least 127 permanent monitoring wells sampled at some point. Each component is
discussed in more detail below.
2.1 EXTRACTION SYSTEM
The extraction system consists of 16 wells screened in the Shallow Cohansey aquifer (see Attachment A
for locations). Information about the wells is provided in table below. Most of the wells are set at the
mid-depth portion of the aquifer just above the Banded Zone. Extraction wells RW02A and 02B were
purposely set at shallower depth in areas of high concentrations in the shallowest portions of the aquifer.
The wells are 8-inch diameter stainless steel casing and wire-wrapped screen fitted with submersible
pumps and pitless adapters. A 1/2-inch "acid" pipe for the addition of chemicals to control bacterial
growth and minimize fouling is set within the borehole, but outside the well screen. A 2-inch
piezometer is installed adjacent to the 8-inch casing. The top of each well piezometer pair is encased in a
2-foot steel casing. Controls for each well are located at each well head.
Extraction well construction and pump information.
Extraction
Well
RW01
RW02
RW02A
RW02B
RW03
RW04
RW05
RW06
RW07
RW08
RW09
RW09A
RW10
RW11
RW12
RW13
Top of Casing
Elev.
(ft msl)
78.23
78.5
-
-
72.66
75.19
74.25
74.59
74.16
66.69
76.78
-
71.83
74.74
72.47
71.3
Elev. Ground
Surface
(ft msl)
76.28
76.97
76.71
74.43
70.62
73.39
72.56
72.93
72.37
64.76
75.04
66.11
70.14
73.1
70.73
69.46
Depth to Top
Screen
(ft)
53
54
25
25
37
41
37
29
24
12
20
19
21
30
29
29
Depth to
Bottom of
Screen
(ft)
73
74
45
45
57
61
57
49
44
32
40
39
41
50
49
49
Pump
Size
(HP)
7.5
7.5
5
5
5
2
2
5
2
5
7.5
7.5
7.5
7.5
7.5
7.5
Yield
(GPM)
160
160
124
125
115
100
138
105
90
145
20
150
50
50
107
63
Approx.
Pumping
Rate
(GPM)
0
65
95
65
65
55
65
40
70
65
0
60
35
0
75
0
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The extraction wells are connected to the treatment plant via buried double-walled high-density
polyethylene (HDPE) piping. Separate piping was provided for extraction wells 1 through 10 to allow
separate transport of groundwater contaminated by inorganic or organic forms of arsenic from any well.
Other extraction wells discharge through a common header. As discussed below, the treatment plant was
originally designed to allow separate treatment of these two forms of arsenic. Extraction wells 9A, and
11 through 13 can only be directed to the inorganic treatment train. Extraction wells 2A and 2B are piped
to the equalization tank. The collection headers originally ran from extraction well RW01 on the
northeast side of the system westward to RW08, southward to south of RW13 then eastward to the
treatment plant. At the site visit, it was learned that an additional header was installed from near RW03
to the treatment plant to provide additional groundwater transport capacity.
2.2 TREATMENT SYSTEM
The treatment facility consists of a 150-foot by 100-foot process building, external treatment components
in a containment area, a 30-foot by 60-foot chemical storage area, a 40-foot by 50-foot solids handling
building, and administrative building. The treatment system as originally designed is depicted in Figure 2-
1. The processes include the following:
addition of hydrogen peroxide to oxidize As(III) to As(V)
ferric chloride addition as a coagulant
sodium hydroxide addition to maintain pH ~6.5
coagulation of iron and adsorption of arsenic to coagulated iron
polymer addition and potassium permanganate to assist with flocculation
solids separation with dissolved air flotation (DAF)
additional sodium hydroxide and potassium permanganate for additional pH adjustment and floe
formation
sand filtration
discharge to surface water
solids thickening
solids dewatering with a centrifuge
off-site disposal of solids as hazardous waste
The treatment system as currently operated is depicted in Figure 2-2. It is apparent that the site team has
significantly optimized the system. System optimization by the site team has resulted in many
improvements to the treatment plant, including the following:
addition of an equalization tank
elimination of all potassium permanganate addition
elimination of both organic treatment trains (all treatment completed by the inorganic treatment
train)
elimination of pH adj ustment after the DAF
addition of polymer to the solids to aid in dewatering
upgrade to all system controls
As of the time of the RSE site visit, the plant operated 12 hours per day, 7 days per week. The plant was
staffed by a full-time plant supervisor, three full-time operators, and a maintenance technician that shares
time with other projects. A full-time chemist position and a full-time maintenance position were cut just
prior to the RSE site visit. In addition, one operator has left as of July 2010 and will not be replaced,
resulting in total operations staffing of 3.5 full-time equivalent employees. The OU2 remedy is also
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staffed by the following part-time positions: project manager, project engineer, sampling crew,
administrator, and cost-estimator.
The treatment system, individual components, and staffing are discussed in more detail in Section 4.5 of
this report.
2.3 MONITORING PROGRAM
Groundwater Monitoring
There are approximately 51 monitoring wells screened in the shallow portion of the Shallow Cohansey
aquifer, 67 mid-depth monitoring wells in the same aquifer, and 9 monitoring wells in the Middle
Cohansey that have been sampled in the last few years. In 2009, a total of 80 monitoring wells were
sampled for total arsenic; 34 shallow, 40 mid-depth, and 6 deep. These wells are generally shown on
Figure 2 of the CEA Report (see Attachment A). Most wells are sampled annually, and 11 shallow wells
appear to be sampled on a semi-annual ("bi-annual" in project electronic records) basis, though the
intervals appear to have varied. Optimization of the monitoring program has been periodically conducted.
The monitoring program therefore involves approximately 90 monitoring well samples per year. These
samples are analyzed for total arsenic but rarely for arsenic speciation. Sampling is done using low-flow
techniques and purging adequacy is based on turbidity and oxidation/reduction potential (ORP) values.
The arsenic detection limit is 9 ppb. Water levels are measured annually. Extraction wells are sampled
monthly for arsenic. Data generated from the analyses are managed via a Microsoft Access data base.
Process Monitoring
Treatment plant process monitoring involves both on-site and off-site analysis.
Samples from the following locations at the indicated frequencies are analyzed off-site in a certified
laboratory.
Each extraction well monthly for total arsenic
Speciation of arsenic in influent and effluent quarterly
Influent weekly (before oxidation tank) for total arsenic
Effluent weekly for arsenic
Effluent bi-weekly for potassium, iron, manganese, sodium, conductivity, alkalinity, pH, total
dissolved solids, total suspended solids, and chloride
After each DAF unit monthly for total arsenic
Sludge thickener overflow monthly for total arsenic
Dewatered solids once pear year for total arsenic
Samples from the following locations at the indicated frequencies are analyzed for total arsenic on-site by
the plant operators using a graphite furnace.
Equalization tank effluent each morning
Filter feed tank every two hours during the day
Plant effluent every two hours during the day
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The effluent is analyzed for total arsenic hourly with a real-time arsenic autosampler and analyzer.
In addition to the above water quality analyses, the following parameters are measured automatically
using meters and are used to control plant operations:
oxidation-reduction potential (ORP) is measured in the oxidation tank
pH is measured in the coagulation tank and the filter feed tank
turbidity is measured after each of the DAFs, prior to filtration, and after filtration
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3.0 SYSTEM OBJECTIVES, PERFORMANCE, AND
CLOSURE CRITERIA
3.1 CURRENT SYSTEM OBJECTIVES AND CLOSURE CRITERIA
The 1989 Record of Decision (ROD) discusses remediation alternatives at four operable units. Only two
of the operable units are considered herein, plant site soils control and plant site groundwater management
and migration. The following Remedial Action Objectives for contaminated soils and groundwater at the
Vineland Chemical plant site were identified in the 1989 ROD:
Prevent current or future exposure to the contaminated site soils
Reduce soil arsenic migration into the groundwater
Eliminate contaminated groundwater flowing into the stream to remediate stream water quality
The cleanup goals include the following:
The plant site soil cleanup objective is 20 mg/kg.
The plant site groundwater cleanup objective is 0.05 mg/1.
According to the ROD, the groundwater cleanup goal "will be achieved to the maximum extent that is
technically practicable. " The ROD calls for the design of a groundwater remediation system that
includes "a combination of pumping and treatment with subsequent natural attenuation of the aquifer to
reach the cleanup goal. " According to the ROD, the end point for pump and treat is when "resumption of
groundwater flow to the Blackwater Branch would not cause violation of arsenic instream standard in
that body, 0.05 mg/L. " The ROD also allows for "an application for an Alternate Concentration Limit
(ACL)... in accordance with appropriate New Jersey regulations, if, for example pumping and treatment
appears to reach a point where it is no more effective than natural attenuation. The need for an ACL and
its value would be determined during the early years of the remedial action on the aquifer. " Pumping
followed by natural flushing was evaluated in the RI/FS. The alternatives considered specified operation
of the pumping and treatment system "until the maximum groundwater arsenic concentration is 0.35
mg/l." At this concentration, based on the RI/FS information, groundwater flowing to the Blackwater
Branch would not cause the in stream standard of 0.05 mg/1 to be violated. The RI/FS estimated that
"approximately 10 years would be required for natural flushing to reduce the arsenic concentration to
0.05 mg/l after achieving the 0.35 mg/l level. "
3.2 TREATMENT PLANT OPERATION STANDARDS
The NPDES equivalency permit, dated September 23, 1997, for surface water discharge lists the
standards for discharging treated water to Blackwater Branch. The parameters, criteria, and sampling
frequency are as follows:
Flow (continuous monitoring)
Total Arsenic < 0.05 mg/l (sample two times per month)
Total Dissolved Solids < 500 mg/l (sample two times per month)
Total Suspended Solids < 40 mg/l (sample two times per month)
pH between 6.5 and 8.5 (sample weekly)
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With the exception of flow, which is monitored continuously, the site team collects and analyzes samples
for these parameters on a weekly basis, which is more conservative than the required frequency.
Additional treatment plant effluent parameters monitored on a weekly basis include:
Total metals (Iron, Manganese, Sodium, Potassium)
Conductivity
Alkalinity
Chloride
Despite the above criteria, the site team has made the internal decision to treat water to under 0.02 mg/1 in
an effort to come closer to achieving the current Federal Maximum Contaminant Level (MCL) for
arsenic.
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4.0 FINDINGS
4.1 GENERAL FINDINGS
Several overall site improvements have resulted directly from operation of the pump and treat system.
The most important of these include a general decrease in the maximum arsenic plume concentrations and
a dramatic reduction in surface water contamination in Blackwater Branch. Protection of Blackwater
Branch is a primary objective of the groundwater program and has allowed excavation for floodplain
sediment remediation (Operable Unit 3) to proceed. The groundwater treatment plant operation also
supported source removal (Operable Unit 1) in treating effluent from the soil washing plant.
The observations provided below are not intended to imply a deficiency in the work of the system
designers, system operators, or site managers but are offered as constructive suggestions in the best
interest of the EPA and the public. These observations have the benefit of being formulated based upon
operational data unavailable to the original designers. Furthermore, it is likely that site conditions and
general knowledge of groundwater remediation have changed overtime.
4.2 SUBSURFACE PERFORMANCE AND RESPONSE
4.2.1 PLUME CAPTURE
The extraction system performance was evaluated based on several lines of evidence, including analysis
of the piezometric surface contour maps, concentration contours and trend analysis, groundwater flux
estimates compared to pumping rates, and review of model results. This is generally in accordance with
EPA guidance in assessing capture zones for groundwater extraction systems (EPA, 2008).
Piezometric surface maps were constructed by the RSE team based on water levels measurements taken
in 2010 for shallow, mid-depth, and deep wells (see Figures 4-1 and 4-2). Note that questions have been
raised regarding the comparability of surveyed reference elevations for a number of the monitoring wells,
particularly those near the vicinity of Blackwater Branch west of North Mill Road. The impact of this is
not yet entirely clear. General flow directions are to the northwest. Clear indications of composite cones
of depression are apparent in the shallow and mid-depth contour maps. The pumping of the northeastern
extraction wells - RW02, 02A, 02B, 03, 04, 06, and 07 - have induced a northeasterly gradient adjacent
to the northern arsenic plume, and contours parallel Blackwater Branch in this area. Pumping of the
western wells - RW08, 09, 09A, 10, and 12 - have created a westerly gradient for the western portion of
the site, particularly along the western extent of the southern arsenic plume. A groundwater divide has
been established between these two "lines" of wells, and the northern arsenic plume sits atop this divide.
It appears that contaminant migration could occur northward toward the stream outside of the capture of
extraction wells RW07 and 08, but other lines of evidence are needed to more fully assess this possibility.
Capture appears reasonably complete to the east and south of MW31S/M. There is a lack of water level
information between the extraction wells and Blackwater Branch to the northeast that could be addressed
by additional monitoring points and/or including the water level of Blackwater Branch. Potentiometric
surface contours prepared by the site team using 2003 data and contouring software (see Attachment A)
indicate substantial flow from Blackwater Branch to the extraction wells, which might be consistent with
the RSE team potentiometric contours if water elevation information from Blackwater Branch was
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included. Site ground water model interpretations of the system capture zone are illustrated in
Attachment A.
The natural flux of groundwater under non-pumping conditions was estimated based on historical pre-
pumping groundwater contours provided by USAGE Philadelphia District (PowerPoint slides on model
development reportedly from 2004), model calibrated hydraulic conductivities (K) of 350 to 700 ft/day,
an estimated conservative maximum saturated thickness of 60 feet (erring on the side of a larger natural
flux), and a plume width of 1200 feet. The gradients estimated from the contours were 0.0017 to 0.002
and 0.002 was used in the calculation. Flux was calculated to approximately 260 gpm with K = 350
ft/day and 520 gpm with K = 700 ft/day. Total pumping for the extraction system is approximately 700 -
800 gpm. This exceeds the natural flux, so there is circumstantial evidence that at least most of the plume
is likely to be captured. Note that any water pumped beyond the natural flux through the contaminated
part of the aquifer is extracted from clean zones to the southwest or from Blackwater Branch. It is likely
the extraction system is drawing a significant amount of water from the stream, particularly with the
eastern extraction wells. Though the site groundwater model provides a more robust tool to assess
capture, these calculations are a reasonable check on the model results.
The concentrations trends were computed for the wells using both qualitative and quantitative (Mann-
Kendall) analysis. Trends for wells near and downgradient of the extraction well lines were examined for
indications of contaminant "breakthrough." Most of the applicable wells display stable or decreasing
trends, with a few exceptions. Some wells displayed an increase during and following excavation
activities on-site, with recent declines following completion of that work. This is a common observation
at sites undergoing large-scale disturbance. However, MW38S appears to have an ongoing increasing
trend, as does MW40S. MW53S has qualitative evidence of recently increasing concentrations. These
exceptions are important because these are in areas in or downgradient of broader gaps in the extraction
system (MW40S is the larger gap between RW07 and 08; MW38S is between RW02 and 03. Note that
contamination moving through these gaps may still be captured as some flow lines enter the extraction
wells from the "downgradient" side of the capture zone. Still, this analysis does raise some questions
about the adequacy of the capture in these areas.
Modeling analysis included simple analytical modeling done using a capture zone width formula and
assessment of numerical modeling of capture zones conducted by USAGE Philadelphia District. Based
on the other lines of evidence, the capture zone widths of RW07 and 08 and RW02 and 03 were computed
using the following equation:
Width = Pumping rate / (saturated thickness x gradient x K)
For RW07 and 08, the relatively small saturated thicknesses in this area and the observed flow rates
would suggest broad capture zones 620-720 feet wide, if the K values are near the modeled 400 feet/day.
However, these wells are close to an area of modeled higher K values, 700 - 1000 feet/day. If the K
values are doubled, the capture zone widths are cut in half 310 - 360 feet, slightly less than the distance
between these two wells. In the case of RW02 and 03, the capture zone widths, assuming saturated
thicknesses in this area of 45 - 60 feet and K values near 400 ft/day, are 220-320 feet, less than the
spacing between these two wells. Capture zone analysis conducted using the site numerical groundwater
model do not show such gaps in the reach of the extraction wells, though the model capture zones open
more toward the east than the southeast. Based on this analysis, there is a chance that minor gaps exist
between a few of the extraction wells.
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4.2.2 GROUNDWATER CONTAMINANT CONCENTRATION TRENDS
Of the 115 monitoring locations for groundwater and surface water that are analyzed for total arsenic,
more than half of them have reached the "non-detect" level during the remediation or were measured as
non-detects prior to the remediation. A summary of trends analyses of total arsenic concentration in
groundwater measured between 2000 and 2010 is provided in Table 4-1. Plots of total arsenic
concentrations in groundwater versus time are shown in Attachment B. Table 4-1 shows that of the wells
shown, more than a third of the monitoring locations show decreasing trends. This includes wells where
the decreasing trend was interrupted by a period of increasing arsenic concentrations during or after
excavation of contaminated soils (see Attachment B).
Six wells: MW53S, MW54S, MW38S, MW-28S, MW35S and MW40S, which are all screened in the
upper 20 feet of the aquifer (shallow zone), show increases in total arsenic concentrations with time. Four
wells have total arsenic values close to or larger than 0.35 mg/1. Locations of these wells are shown in
Figures in Attachment A. Two of the wells, MW28S and MW38S, are in the heart of the plume in the
area downgradient of the former process buildings. Well MW35S is in the area of the southern arsenic
plume. Well MW54S is on the opposite side of Blackwater Branch northwest of the site. The reason for
the arsenic increases within the zone of influence of the groundwater recovery system may be due to
redistribution of the arsenic plume (i.e. change in migration pathway) from impacted soils towards the
monitoring wells. For the one well, MW54S located along the north bank of the Blackwater Branch, it is
possible that the recent land excavation and disturbance related to floodplain remediation in the area has
contributed to the arsenic increases. However, the source of arsenic in this area is unclear. A recent
Hydropunch investigation in this area followed with installation of monitoring and sampling did not
show a widespread plume. The most recent arsenic value at MW54S is much lower than the previous
several years so additional monitoring as well as evaluation of additional data gathered as part of the data
gap analysis will be necessary to determine if any future action is necessary along the north bank of the
Backwater Branch.
There are several wells in Table 4-1 that show a relatively stable trend since the operation of the
groundwater treatment plant began. Many of these locations are downgradient of the former process
buildings within the main arsenic plume. Two of the locations with high arsenic concentrations, MW25M
and MW31M, are at a significant distance downgradient of the former process buildings and near Mill
Road (see figures in Attachment A). It is unclear why the concentrations at these wells continue to be so
high and also unclear whether the current remediation method will be able to reduce these concentrations
to levels specified in the ROD. Well EW21M is another location with a relatively stable, high arsenic
trend. Wells surrounding EW21M show non-detects or very low concentrations for arsenic. The
explanation for the continued high arsenic concentrations at this well is unknown. One potential
explanation is that these locations are along the migration path where the kinetics controlling the mass
transfer rate from groundwater to the soil were fast, but the kinetics controlling the desorption of arsenic
from the soil to groundwater are relatively slow. Under such conditions, arsenic desorption is the rate-
limiting step for aquifer restoration, and concentrations can remain elevated despite flushing the area with
many pore volumes of clean water.
The causes of the stable trends in the damaged wells MW37S, MW30S, MW49S, MW48S, MW36S, and
EW15S, prior to July 2002 (ranging from 10, 1,5, 1, 1, to 0.8 mg/1, respectively) is unknown, but the
treatment system had only been operating for a period of two years, and a discernible trend may not have
been readily apparent in that 2-year period for a site with such extensive groundwater contamination.
The first figure in Attachment C shows the 0.35 mg/1 plume in the shallow zone at the onset of the P&T
system, generated using the maximum total arsenic measured in monitoring wells between 2002 and 2003
and log kriging interpolation. The second figure of Attachment C shows the 0.35 mg/1 total arsenic plume
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generated from the maximum total arsenic measured in monitoring wells between 2008 and 2009. These
figures indicate that the decrease in the extent of the 0.35 mg/1 plume between 2002/2003 and 2008/2009
is limited to the isolated plume located along the southwest (at EW13S). The decrease in the strength and
extent of the 0.35 mg/1 plume located along the south / southeast is attributed to the removal of the six
shallow wells with elevated stable concentration MW37S, MW30S, MW49S, MW-48S, MW36S and
EW15S during soil excavation. The increase in concentrations to the northeast on the south bank of
Blackwater Branch in the area of MW30S and MW28S is possibly due to re-distribution of the plume by
the recovery system.
The extent of the arsenic plume in the middle zone remains relatively unchanged between 2002-2003 and
2008-2009 (see the third and fourth figures in Attachment C), but concentrations have decreased
significantly in many wells, including many of the recovery wells. Decreases are most notable in the
wells that had the highest concentrations in 2002-2003 (i.e., source area wells). Review of the
concentration trends in Attachment B indicate that the most significant decreases occurred in the first few
years of operation, and that the rate of decrease is slowing. It is unclear if the concentrations in these
areas of significant decreases will remain low if pumping is discontinued or if they would rebound.
EPA 2002 outlines a procedure for estimating how quickly a remediation goal will be met at a site. This
procedure involves plotting concentrations versus time measured in monitoring wells on a semi log paper
and determining the rate constant (point decay rate) which can be used to estimate restoration time. Only
two wells in the shallow zone show a monotonic decreasing trend in arsenic concentrations, and all other
wells either show stable or increasing concentrations. As a result, the available results indicate that the
current P&T system is unlikely to restore the aquifer within a reasonable period specified by the ROD.
The analysis can also be applied to the recovery wells that continue to operate, recognizing that attaining
0.35 mg/1 in the recovery wells does not ensure attainment of this concentration throughout the arsenic
plume required by ROD. The time needed to reach an arsenic concentration of 0.35 mg/1, 0.05 mg/1, and
0.01 mg/1 for each well are estimated based on a linear regression of the arsenic concentration trends in
the wells extrapolated into the future (Attachment D and Table 4-2). In addition some arsenic data were
not used in the linear regression if it was determined that the data were not representative of the recent
trend. For example, several of the wells show an initial increase in arsenic concentration after plant
startup and then a decreasing trend that becomes milder over time. The linear regression for these wells
was computed using only the last 4 or 5 years of data to be consistent with the recent data trend.
Estimated time to reach an arsenic value of 0.35 mg/1 at all the recovery wells is less than a year to 20
years (see Table 4-2 and Attachment D). The longest time estimates to reach 0.35 mg/1 occur at RW02b,
RW06 and RW07. These are also the recovery wells with the highest arsenic concentrations and are
located within the heart of the main plume. The time to reach 0.05 mg/1 at all the recovery wells ranges
from 3 years to 54 years. The time range to reach 0.01 mg/1 is 6 years to 128 years. It must be noted that
the time to reach the 0.35 mg/1 in recovery wells does not represent the time to reach the 0.35 mg/1 in the
entire plume.
Eight surface water stations are monitored. Arsenic concentrations in all eight stations since July 2003
have been well below the NPDES criteria of 0.05 mg/1 with arsenic concentrations around 0.01 mg/1 in
recent sampling events. Surface water concentrations prior to July 2003 concentrations were at or above
the 0.05 mg/1 criteria at most of these locations. The recent results indicate success of the P&T remedy in
protecting Blackwater Branch.
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4.2.3 SITE-SPECIFIC GEOCHEMISTRY
EPA Document Monitored Natural Attenuation of Inorganic Contaminants in Ground Water, Volume 2,
October 2007 discusses the attenuation of arsenic in groundwater through precipitation, co-precipitation,
or adsorption to various minerals, including iron oxyhydroxides. The RSE team directs the reader to this
document for more information on arsenic in groundwater and relevant geochemistry. A number of
factors are to be considered in assessing the natural fate of arsenic and any engineered immobilization as
discussed below.
Metal Concentrations in Soil
Immobilization of arsenic is affected by the concentration of metals in aquifer soils. Available data of
metal concentrations in soil and groundwater are limited to Area 5 (the source area where soil was
excavated). The data, shown in Attachment E, indicate:
1) With the exception of one point plots of total versus dissolved arsenic show a near 1 to 1
relationship suggesting sound sampling protocol that ensure little trapping of suspended
sediments with sorbed arsenic
2) Relatively good correlation is encountered between arsenic and iron in soil. These data may be
used to develop a preliminary site specific partition coefficient. The relatively good correlation
between arsenic and iron concentration and the elevated iron concentrations in soil (as high as
2%) show that iron is likely to play a dominant role in attenuation of arsenic.
3) Sulfides concentration in soil is below 13 mg/Kg and is limited in extent (most soil samples
showing non-detect concentrations for sulfide. Sulfate concentration in groundwater ranges
between ND and 182 mg/1 with most data ranging between ~ 5 mg/1 to -15 mg/1. These data
suggests ORP (Eh) value higher than those representing sulfate reducing conditions.
Columbia indicated that, based on their work regarding enhanced arsenic mobilization, iron, aluminum
and arsenic were desorbed during their testing. Aluminum concentrations in soil were not tested in some
areas ("Area 5") and as such additional data are needed to assess the potential of aluminum to attenuate
arsenic and develop a site specific partition coefficient. Similar metals data for soil in other parts of the
site are also needed.
Arsenic Speciation in Groundwater
The speciation of arsenic present in the groundwater is important for assessing its fate or for engineering
its immobilization. Under conditions observed at the site (pH < 5) adsorption of arsenate to iron
oxyhydroxides would be the most stable form of immobilization. Speciation of arsenic at the site shows
the presence of arsenate, arsenite, MMA, and DMA. The data indicate that the fraction of organic arsenic
species (MMA and DMA) is insignificant in comparison to inorganic arsenic species. Overall, in
groundwater arsenate is the dominant form of arsenic although significant concentrations of arsenite are
present. The ratio of arsenate to arsenite in the shallow zone ranged from values >1 to 6250 in ~ 200
samples and was less than one (i.e. where arsenite > arsenate) in -60 samples. An additional -70 samples
were non-detect for arsenic and had a ratio of 1 (i.e., the ratio of two equal detection limits).
Concentrations of organic arsenic species, particularly MMA, have declined substantially in the treatment
plant influent during P&T operation. MMA concentrations in 2003 were over 0.1 mg/L but have
decreased to below 0.02 mg/L, which meets current ROD and discharge standards. By contrast, the
combined arsenate and arsenite concentration is approximately 0.3 mg/L.
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As an aside, arsenic speciation in process water prior to chemical addition shows that overall arsenate is
the dominant form of arsenic, however there are periods where arsenite is the dominant form of arsenic in
process water. The RSE team believes that arsenate is likely sorbed to the iron oxide precipitate that
routinely clogs the well screen and extraction piping. This hypothesis is supported by a comparison of
the arsenic concentrations sampled at the extraction wells and the arsenic concentration in the treatment
plant effluent. Based on extraction well sampling results and extraction well rates, the RSE team
estimates that the blended arsenic concentrations in the extraction wells is approximately 0.6 mg/L
whereas the actual blended influent concentration at the equalization tank is approximately 0.3 mg/L.
This comparison suggests that up to 50% of the arsenic (in the form of arsenate) may be removed by
precipitated iron within the extraction network. The removal of arsenate in the extraction network results
in arsenite being the dominant arsenic species in the treatment plant influent during some periods.
For in-situ immobilization at the site, the large majority of arsenite would need to be oxidized into
arsenate in order to improve the effectiveness of subsequent adsorption. Arsenite can be oxidized by
oxygen, ozone, free chlorine, hypochlorite, permanganate, hydrogen peroxide and Fenton's reagent. Air
oxidation of arsenic may be relatively inexpensive relative to the other options but is very slow and can
take weeks for oxidation (Pierce and Moore, 1982). Chemicals like the hydrogen peroxide used in the
above-ground treatment process rapidly oxidize arsenite to arsenate under wide range of conditions and
would also have the ability to oxidize the organic arsenic.
pH, ORP/ Eh, Dissolved Oxygen, and Temperature in Groundwater
Spatial plots of pH, ORP, dissolved oxygen, and temperature measured between 2009 and 2010 for the
shallow and middle zones indicate the following:
There is no clear monotonic (i.e. continuous decline or continuous increase) trend in any of the
measured field parameters. Pumping may be confusing any natural trend that might exist.
Groundwater temperatures in many monitoring wells between the extraction network and surface
water are indicative of surface water temperatures, suggesting that the extraction network is
pulling surface water into the aquifer.
DO measurements indicate aerobic conditions, ORP is positive, and the elevated values are likely
representative of the ferric/ferrous ion pair rather than the H/OH ion pair. For this reason ORP
cannot be related to dissolved oxygen measurements. Analysis of iron speciation in groundwater
can be utilized to confirm this hypothesis and demonstrate the dominance of the iron chemistry in
groundwater.
Overall the groundwater is acidic. Arsenate adsorption to iron oxides has been shown to be
effective at the pH encountered on site. However, site-specific bench scale studies are needed to
determine the optimal pH range for arsenate adsorption and the recommended procedure to attain
and maintain the optimal pH. Site-specific bench scale studies are also required to determine the
stability of the sorbed arsenic as well as the kinetic of arsenic adsorption and factors influencing
adsorption kinetics.
4.2.4 CONCEPTUAL MODEL INPUT AND DATA GAPS
Natural geochemistry at the site and historic arsenic concentration trends in groundwater, sediment, and
surface water indicate the potential for arsenic to discharge to Blackwater Branch in the absence of
remedial action. To date, the P&T system has been successful at mitigating arsenic discharges, and
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surface water concentrations are consistent with goals. However, stable but elevated concentrations
remain in many areas of the plume, and it is likely that some of the extraction wells will need to continue
operating for the foreseeable future. An improved understanding of the site geochemistry and potential
adsorption mechanisms for arsenic could lead to alternative or complementary remedies for containing
the arsenic.
This section itemizes important aspects of the conceptual model and notes some of the important data
gaps in the existing site conceptual model that would need to be addressed to develop effective alternative
or complementary remedies to the existing P&T system.
Source areas - This aspect of the site conceptual model is not fully understood due to the
complexity of the historic operations at the site. In the most highly contaminated areas, source
excavation to a depth of three feet below the groundwater table was completed. Minor source
areas may remain at other site locations and in the area below the completed source excavations.
At the time of the RSE site visit, USAGE was still investigating potential arsenic source areas on
the opposite side of Blackwater Branch. Source area characterization needs to be completed to
help distinguish those areas of the aquifer that are likely to be restored and those areas of the
aquifer that will likely need either source removal or long-term source control.
Hydrogeology and groundwater flow - This aspect of the site conceptual model is relatively well
understood. A numerical model has been constructed for the site and applied in determining the
Classification Exception Area and various pumping scenarios. There are some gaps in
understanding of groundwater flow in some areas, and unreliable survey information for some
wells complicates a full understanding of groundwater flow at the site. Collection of accurate
water levels and recalibration of the model is needed to appropriately evaluate additional
potential remedy alternatives. Additional groundwater / surface water studies are warranted in
order to confirm that the ACL of 0.35 mg/1 is protective of the Blackwater Branch and/or to
develop an alternate end point for the extraction system. The ROD states, "Additional data will
be collected during design and operation of the pumping system. If these data show that a point is
reached beyond which pumping and treatment is not more effective than natural attenuation, the
arsenic will be allowed to flush naturally to the cleanup goal, 0.05 mg/l. The pumping and
treatment maximum arsenic objective calculated in the Feasibility Study, 0.35 mg/l, will be
recalculated during design'' It is the RSE team's understanding that an evaluation of natural
attenuation and 0.35 mg/l objective has not been revisited since the Feasibility Study.
Geochemistry and contaminant fate and transport - This aspect of the site conceptual model has
been studied but needs further development. The site team researched arsenic adsorption as part
of the soil washing remedy, but this information is not sufficiently comprehensive to apply it to
site-wide contaminant fate and transport. Metals data in soil across the site and bench scale tests
regarding arsenic adsorption and desorption under various potential conditions are needed to
understand the potential and capacity for site soils to adsorb arsenic. Site geochemistry and
arsenic adsorption would be primary mechanism for natural attenuation and for evaluating the
0.35 mg/l criteria.
Receptors - This aspect of the site conceptual model is well understood. Blackwater Branch is
the primary receptor for the site. Successfully protecting this receptor will also result in
protecting other potential receptors further from the site.
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4.3 MONITORING PROGRAM EFFECTIVENESS
The monitoring program was assessed through both qualitative and quantitative means. The Monitoring
and Remediation Optimization System (MAROS) software (v. 2.2) was used to perform the quantitative
analysis of the monitoring program. The software provides an assessment of concentration trends (as
discussed above), monitoring frequency, monitoring network redundancy and monitoring network
sufficiency. Qualitative analysis of the monitoring network redundancy and sufficiency was also
conducted using professional judgment in consideration of the MAROS results.
Concentration trends computed by MAROS using Mann-Kendall trend analysis methods are summarized
in Attachment F and displayed graphically at the end of Attachment F (for the shallow, mid-depth, and
deep wells. The trends for wells in the source and up/downgradient locations are considered in a heuristic
analysis by MAROS. Based on the heuristic analysis, the monitoring program should reflect a
"moderate" level of effort for both the shallow and mid-depth portions of the Shallow Cohansey
aquifer. According to the MAROS manual (Table A.8.1), this would roughly correlate to semi-annual to
annual sampling, as is currently conducted at the site. In addition, the heuristic analysis indicates that a
sampling network of approximately 30 wells would be appropriate. Given that the monitoring networks at
both the shallow and mid-depth levels are only slightly larger than 30, the networks are not
unreasonable. The results of the trend determination and heuristic analyses are provided in Attachment
F. A qualitative review of sampling frequency supports the use of annual sampling for most wells, with
semi-annual sampling near the extraction wells and Blackwater Branch. Upgradient "clean" wells could
be sampled on a biennial (every two years) basis.
The MAROS analysis of potentially redundant wells indicated there are a few wells that may be excluded
from the program without serious loss of information on plume configuration and extent. The wells
identified include MW27S, MW5IS, EW16M, and EW17M. These are all wells outside the arsenic
plumes. MAROS is conservative in recommending removal of wells from the network (even when the
default parameters for the analysis are modified to be more liberal). Based on the qualitative review of
the data, additional wells that may be redundant include:
EW17S (non-detect, duplicates EW14S),
EW18S (non-detect, duplicates MW46S and EW14S),
EW23S (non-detect, duplicates EW22S),
MW45 S (duplicates EW19S),
EW01M (non-detect, duplicates MW32M)
EW05M or EW06M (these provide duplicate information on plume interior)
EW 13M (duplicates MW45M)
EW 18M (non-detect, duplicates MW46M and EW 14M)
EW23M (non-detect, duplicates EW22M and MW51M)
MW27M (non-detect, duplicates WW26M)
EW34M (non-detect, duplicates MW33M and EW14M)
Eliminating these sampling points would represent a reduction of 15 wells.
The MAROS analysis did not indicate significant data gaps in the monitoring network. The qualitative
review, however, did identify some additional gaps. Though the extent of contamination north of
Blackwater Branch has been characterized by direct-push sampling, additional permanent wells should be
added to allow continued monitoring of the hot spot west and northwest of MW54S/54M. In addition,
there are no monitoring wells, with the exception of MW39M, between the northern plume/extraction
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well line and Blackwater Branch. As discussed above, it seems likely the extraction wells are inducing
inflow from the stream, but additional well(s) would be useful to define the edge of the plume between
the stream and existing extraction and monitoring wells. The piezometric measurements from such wells
would also be useful.
The low-flow sampling methods are appropriate for inorganic constituents such as arsenic; however,
alternative no-purge sampling methods such as the Hydrasleeve or Snap samplers, may reduce sampling
labor costs. Such samplers also provide low-turbidity samples. A comparison study, perhaps for a
representative subset of wells, would be appropriate to assess data comparability from both existing and
proposed techniques.
The current data management approach is very good. There are apparently no periodic monitoring and
performance reports that document and interpret the results, however. There should be one entity with the
responsibility to integrate and interpret chemical and piezometric data to assess the extraction system
performance.
4.4 COMPONENT PERFORMANCE
4.4.1 EXTRACTION WELLS
The extraction wells at the site face problems with biofouling and scaling that periodically reduces the
specific capacity of the wells and ultimately the pumping rates. The project team has done an excellent
job in attempting to address these issues with a well maintenance program and experiments with various
fouling treatments and inhibitors. Currently, the wells are treated either on a continuous basis with Redux
Ferremede product (RW02, 2A, 2B, 3 and 9A, per e-mail from Steve Creighton [USAGE Philadelphia
District] on 7/20/10) to keep iron and arsenic in solution, or treated periodically with glycolic acid and
jetted. Redevelopment is conducted on a group of 3-5 wells every six months or so. The wells chosen for
redevelopment depend on performance metrics including flow rates. The jetting has been found to be
quite effective. Originally, well redevelopment consisted of treatment with sulfamic acid and surging.
The fouling problems have also affected the piping to the treatment plant such that the original piping
header requires cleaning approximately every 6 months. The Redux product is targeted for wells that are
connected to the new piping header from RW03 to the plant to provide some benefit to preventing fouling
of that header. According to the project team, the Redux product added continuously to the wells has
equivocal evidence of preventing or reducing fouling problems.
Though the current program is quite successful, the use of a mix of compounds including an acid (such as
the glycolic acid used now), and dispersant, and a disinfectant (e.g., oxidizer) may be more effective,
when used in conjunction with jetting, at delaying the decline in production. There are existing
commercial products, such as the AquaClear series of compounds from Baroid (this does not necessarily
represent an endorsement of this product) that can fill these roles. Some of these products have recently
been incorporated into the well maintenance program.
4.4.2 EQUALIZATION TANK
The equalization tank is a cylindrical steel tank with a floating roof that the site team estimates has
300,000-gallon capacity. The equalization tank was not part of the original design but was added in
anticipation of the related soil washing remedy that contributed slugs of water with higher arsenic
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concentrations. The equalization helped even out the spikes in arsenic concentration and helps even the
flow and water quality when extraction wells are brought on and offline. Extracted water from the RW-
2/2A/2B/3 area is piped directly to the tank in a new force main installed in 2007. Extracted water from
all of the other recovery wells can be diverted directly to the oxidation tank or to the equalization tank
using valves. All extracted water is currently pumped to the equalization tank where the water level is
maintained at approximately 7 to 10 feet. The tank diameter is approximately 60 feet resulting in a
residence time of approximately 3 to 4 hours for a flow rate of 750 gpm A 40-horsepower (HP) pump
with a variable frequency drive (VFD) set at 20% load conveys the water from the equalization tank to the
oxidation tank.
4.4.3 CHEMICAL ADDITION AND FLOCCULATION
A 50% hydrogen peroxide solution is added to the oxidation tank to maintain an ORP setpoint of
approximately 320 to 350 mV. Typical hydrogen peroxide use is approximately 27 gallons per day. The
tank has a volume of 10,000 providing residence time of over 12 minutes at the current flow rate and a 3
HP mixer. The peroxide oxidizes the arsenic from As111 to Asv. The operators indicate that the hydrogen
peroxide feed pump has problems with off-gassing at low peroxide usage rates.
The water from the oxidation tank flows by gravity to the coagulation tank. A 37% ferric chloride
solution is added as a coagulant at a rate of approximately 125 gallons per day. The ferric chloride
addition is controlled by historic knowledge and visual observation. A 25% sodium hydroxide is also
added at a rate of approximately 275 gallons per day to maintain a pH set point of 6.5. At this pH, the
ferric hydroxide formed from the ferric chloride and hydroxide ions is Fe(OH)2+ and Fe(OH)3 and the
arsenate is H2AsO4"andHAsO4"2. The arsenate complexes with the ferric hydroxide. The 10,000-gallon
coagulation tank has a 3 HP mixer. Process water from the coagulation tank flows by gravity to two the
two-stage flocculation tanks arranged in parallel (a total of four tanks). Cationic polymer is added to the
second-stage tanks at a rate of approximately 5 gallons per day (prior to polymer dilution with potable
water) to facilitate flocculation. The two first-stage flocculation tanks have 5 HP mixers with VFDs set at
30 Hz, and the two second-stage flocculation tanks have 0.5 HP mixers with VFDs set at 30 Hz.
Chemical addition, coagulation, and flocculation occur in the concrete containment area outside of the
process building.
4.4.4 DISSOLVED AIR FLOTATION
Process water from the flocculation tank flows by gravity to two DAF units arranged in parallel located
inside the process building. Compressed air is provided to DAF recirculation water. A 7.5 HP pump
provides the flow and high pressure to dissolve additional air in the recirculation water. Upon discharge
to the bottom of the DAF, the pressure is relieved from the recirculation water forming fine air bubbles
that attach to the iron/arsenic floe and bring it to the surface. The floating solids are raked off of the DAF
units and pumped to the sludge thickening tank. Process water is used either for recirculation or is
discharged to the sand filter feed tank.
Treatment plant operators measure turbidity continuously to monitor DAF performance. The treatment
plant operators indicate that all recent plant upsets are indicated by elevated turbidity. Excess turbidity
can overwhelm the sand filters.
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4.4.5 FILTRATION
Process water in the filter feed tank is pumped with a 28 HP pump with a VFD set at approximately 45
Hz through three continuously backwashing sand filters arranged in parallel in the concrete containment
area outside of the process building. A fourth sand filter is currently not used. The continuous backwash
requires an air scour flow rate of 3-4 cubic feet per minute at 15 to 25 psi per filter. Filtered water flows
by gravity to the effluent tank. The backwashed solids are pumped to the equalization tank. The
operators maintain curtains and electrical heaters around the conical bottom of the filters to help avoid
freezing problems. The operators report that freezing is not an issue while the plant is running, but does
become a problem during cold temperatures when the plant is down for an extended period of time.
Treatment plant operators measure turbidity continuously to monitor filter performance. The treatment
plant operators indicate that all recent plant upsets are indicated by elevated turbidity.
4.4.6 SOLIDS DEWATERING
Solids from the DAF are pumped with an air-operated diaphragm pump to a 25,000-gallon solids
thickening tank located outside adjacent to the solids handling building. Thickener overflow is pumped
back to the equalization tank. Thickened solids are pumped with a 17.5 HP pump to the centrifuges
running in the solids handling building. Anionic polymer is added at a rate of approximately 6 gallons
per day (prior to dilution with potable water) to the solids stream, which is pumped to one of two
centrifuges. The operators indicate the centrifuges run continuously, relatively problem free during plant
operation hours. Operators indicate that at the current flow rate (approximately 800 gpm) and arsenic
loading (approximately 0.3 mg/1) the centrifuge operation requires approximately 10 hours per day, 5
days per week to keep up with solids production.
The centrifuges produce approximately 10,000 pounds per week of sludge with slightly over 20% solids
content. Solids are disposed of off-site as hazardous waste at the EQ facility in Bellevue, Michigan,
approximately 700 miles from the site. Trucks carrying solids are weighed on the facility scale before
leaving the facility.
4.4.7 SYSTEM CONTROLS
The supervisory control and data acquisition (SCADA) system was updated in 2004. The new controls
are appropriate for the treatment system and offer an appropriate degree of control, operator interface,
data management, and remote operation capabilities.
4.4.8 DISCHARGE OF TREATED WATER
Treated water in the effluent tank is pumped to a restored portion of Blackwater Branch by a 20 HP
pump. The pump capacity is currently one of the capacity limiting factors for the treatment plant. This is
because the discharge line has been moved, due activities related to realigning Blackwater Branch, to a
higher elevation. The higher elevation limits the amount of flow the pump can provide. A larger pump
could be used if an increase in plant capacity is necessary.
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4.4.9
PROCESS AND ADMINISTRATIVE FACILITIES
The treatment plant operations and activities associated with other operable units are managed out of an
administrative building that contains a reception area, conference rooms, and offices for site staff. The
facility is heated by electric resistive heating.
The 150-foot by 100-foot process building houses the two DAF units associated with the inorganic
(currently used) treatment train and the two DAF units associated with the two organic treatment trains
(not currently used). The process building also houses the control room, electrical room, laboratory, and
restrooms. The laboratory contains the graphite furnace used for on-site samples as well as other
instrumentation used for analysis associated with other operable units.
4.5 COMPONENTS OR PROCESSES THAT ACCOUNT FOR MAJORITY OF
ANNUAL COSTS
The annual cost for the OU2 remedy on a move-forward basis is approximately $1.8 million as presented
in the following table.
Item Description
Project management and engineering support
Operator labor (assume 3.5 full-time equivalent staff)
Utilities
- Electricity (2009 electricity bills)
- Potable water (2009 bills)
- Natural gas (2009 bills)
Telecommunications
Renewable energy certificates (assumes $0.03 per kWh)
Treatment process materials and chemicals
Hydrogen peroxide ($2.70 per gallon)
Ferric chloride (assuming $ 1 . 3 0 per gallon of 3 7% solution)
Sodium hydroxide (assuming $0.72 per gallon)
Cationic polymer (assuming $ 16 per gallon)
Anionic polymer ($17 per gallon)
Waste disposal
Process monitoring analysis
Groundwater sampling, including analysis
Well-maintenance (including well maintenance chemicals)
Various parts/materials
Other Costs
Total
Approximate Annual Cost
$250,000
$350,000
$189,000
$13,000
$28,000
$4,000
$41,000
$27,000
$59,000
$72,000
$29,000
$37,000
$80,000
$20,000
$115,000
$365,000
$83,000
$1,300,000
$3,062,000
4.5.1
UTILITIES
Electricity is provided by the Vineland Municipal Electric Utility from a coal-fired power plant at an
approximate cost of approximately $0.13 to $0.15 per kilowatt-hour (kWh), depending on season.
Approximately 1.35 million kWh were used during the 12-month period from February 2009 through
January 2010. Natural gas is provided by South Jersey Gas at and approximate cost of $1.00 to $1.33 per
therm. Approximately 31,000 therms were used during the 12-month period from February 2009 through
January 2010, and approximately 90% of the natural gas is used between December and April.
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Electricity usage from conventional resources is "converted" to electricity from renewable resources
through the purchase of Renewable Energy Certificates at an assumed cost of $0.03 per kWh.
4.5.2 NON-UTILITY CONSUMABLES AND DISPOSAL COSTS
Chemical costs for treatment and for well maintenance are the predominant consumable costs. Treatment
process chemicals cost approximately $217,000 per year, with sodium hydroxide, ferric chloride, and
anionic polymer comprising almost 75% of that cost. Chemicals for well maintenance include
approximately $60,000 for the sequestering agent injected around wells and approximately $3,500 for
glycolic acid used for maintenance of the other wells.
Disposal costs are approximately $80,000 per year for approximately 260 tons per year for a rate of
approximately $310 per ton for transport and disposal.
4.5.3 LABOR
Operator labor reductions have significantly decreased costs leading up to the RSE site visit as a result of
optimization conducted by the site team. The project team estimates approximately $100,000 per full-
time equivalent employee in the treatment plant.
The project management and engineering support costs are reported by the site contractor for the year
2009. The costs cover the part time administrator, part time project engineer, part time project
management, and part time cost accountant. A small portion of this cost also includes office supplies and
utility bills for the administrative building. The site team reports that the project management costs (not
necessarily technical support costs) for 2011 are approximately $112,000. Additional cost is likely spent
for engineering support.
4.5.4 CHEMICAL ANALYSIS
The total chemical analysis cost was provided by the project team, which estimates that total arsenic
sample analysis costs approximately $15 per sample with a standard turn-around time and $30 per sample
for an expedited turnaround time.
4.5.5 OTHER COSTS
Total expenditures for EPA for the OU2 Long-Term Remedial Action were approximately $3 million
calendar year 2009 and over $4 million through the first 8 months of calendar year 2010. The $1.3
million of "other costs" in the above table were determined by subtracting the contractor costs of
approximately $1.7 million from the approximate outlays by EPA of $3.0 million. Review of these other
costs is outside the scope of this RSE, so the RSE team cannot comment on the use of those funds.
However, the RSE team is aware of several other activities associated with the remedy that may be
associated with those costs, including project administration by USAGE, research on arsenic mobilization
by Columbia University, modeling support provided by USAGE, and additional field characterization
conducted by USAGE.
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4.6 APPROXIMATE ENVIRONMENTAL FOOTPRINTS ASSOCIATED WITH
REMEDY
4.6.1
ENERGY, AIR EMISSIONS, AND GREENHOUSE GASES
A series of spreadsheets was used to calculate the footprints for energy, air emission, greenhouse gas, and
other environmental parameters for the OU2 remedy (see Attachment G). Highlights of the analysis are
summarized in the following table.
Remedy Component
Extraction system
Treatment plant
Long-term monitoring
Total
Annual Footprint
Energy
(MMbtus)
5,200
17,200
<100
-22,400
Greenhouse Gas
(Ibs CO2e)
276,000
1,770,000
5,000
-2,051,000
Criteria Pollutant*
(Ibs)
4,400
16,200
<100
-20,600
Hazardous Air
Pollutants
(Ibs)
155
373
<1
-528
MMbtus = millions ofbtus
* Refers only to emissions nitrogen oxides (NOx), sulfur oxides (SOx), and particulate matter.
Reported values include greenhouse gas, NOx, and SOx offsets from purchasing renewable energy credits
The following table provides a more detailed breakdown of air emissions by remedy component using
CO2e as an indicator parameter.
Remedy Component
On-site emissions1
Electricity generation2
Transportation3
Chemical and material production4
Off-site services5
Total
Annual CO2e Emissions (Ibs)
289,000
555,000
132,000
792,000
284,000
2,052,000
% of Total
14%
27%
6%
39%
14%
100%
predominantly natural gas combustion for building heat
2 electricity generation offset by purchase of renewable energy certificates for all electrical use
3 transportation for personnel, chemicals, and hazardous waste
4 production of treatment materials (e.g., process chemicals) and fuels (e.g., diesel and natural gas)
5 waste disposal (excluding waste transportation), laboratory analysis, electricity transmission, etc.
Electricity generation contributes significantly to the energy and air emission footprints. Although
Renewable Energy Certificates (RECs) are bundled with grid electricity from the Vineland Municipal
Electric Utility to provide renewable electricity to the site, the electricity provided by this utility is from
coal, which has higher net emissions than the electricity produced throughout the rest of the New Jersey
area electrical grid. The emission offsets from purchasing RECs for total electricity usage are calculated
from www.epa.gov/egrid plus 10% to account for resource extraction (e.g., coal mining). Of the CO2e
emissions reported above, approximately 50% of them are directly tied to the extraction rate. The
remaining 50% are tied to building heat, operator transportation, well maintenance, and other activities.
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4.6.2 WATER RESOURCES
The groundwater extracted by the remedy would discharge to the surface water of Blackwater Branch in
the absence of pumping, and extracted water is discharged to Blackwater Branch. Therefore, the remedy
has little or no effect on the local water resource other than the positive effect of restoring water quality.
Significant potable water is used for blending and diluting chemicals prior to addition to the treatment
system. Approximately 13 million gallons of potable water are used each year for this purpose. This
potable water use is directly tied to the system extraction rate.
4.6.3 LAND AND ECOSYSTEMS
The activities of the site-wide remedy have an extensive affect on local land and ecosystems due to soil
excavation, sediment remediation, and realignment of Blackwater Branch. The activities of the OU2
remedy, however, have little or no direct effect on the local land and ecosystem use. The only effects of
remedy activities are the presence of the treatment buildings and what influence they may have over the
long-term to redevelop the property for beneficial use. The remedy's ability to achieve the remedial
action objectives of preventing contaminant migration to Blackwater Branch has contributed to the
restoration of large areas of the local ecosystem, including Blackwater Branch, the Maurice River, and
Union Lake.
4.6.4 MATERIALS USAGE AND WASTE DISPOSAL
Materials usage at the site is extensive because of the treatment chemicals used in the process.
Approximately 600,000 pounds of refined manufactured product are used as part of the remedy each year.
Approximately 260 tons of waste is disposed of as hazardous waste.
4.7 RECURRING PROBLEMS OR ISSUES
Well fouling is one of the more problematic issues for the remedy. Extensive operator labor,
subcontractor use, and chemical usage is required to maintain the wells.
4.8 REGULATORY COMPLIANCE
There have been five effluent releases with total arsenic values larger than 0.05 mg/1 since plant startup in
2000. The releases were reported and corrective actions were taken. No harm to human health or
permanent harm to the environment resulted from these isolated incidents. Since mid-2006, all effluent
releases have been less than 0.025 mg/1.
4.9 SAFETY RECORD
Health and safety topics are discussed at each bi-weekly progress meeting. From October 14, 1999 to
June 8, 2010, atotal of 299,084 hours were worked with no recordable or reportable injuries. No health
and safety issues were identified as part of the RSE investigation.
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5.0 EFFECTIVENESS OF THE SYSTEM TO PROTECT HUMAN
HEALTH AND THE ENVIRONMENT
5.1 GROUNDWATER
There are no current, known exposures to groundwater contamination. The classification exception area
and other land-use controls should prevent groundwater use in the vicinity of the site. The groundwater
extraction system is achieving its primary goal of protection of surface water quality, though there are
some subtle questions about the completeness of the capture of the entire plume as discussed above. The
groundwater contamination north of Blackwater Branch is currently uncontrolled, but does appear to be
defined. The exact source and fate of this contamination is not known. The current extraction system is
making limited progress toward attainment of cleanup goals for on-site groundwater. Though the mid-
depth wells are generally displaying decreasing concentrations, shallow monitoring wells are generally
stable. Projections based on these trends, as discussed previously, indicate that it may take decades to
attain the site groundwater goal for arsenic, even though the goal is well above the current MCL.
5.2 SURFACE WATER
Based on the surface water sampling results, surface water quality in the vicinity of the site appears to be
meeting goals for protection of ecological and human receptors. The treatment plant is more than
meeting the discharge standards (50 ug/L) set in the ROD for surface water and is generally almost
meeting the current arsenic MCL of 10 ug/L.
5.3 AIR
There are no apparent current risks to human or ecological receptors via air pathways. No sampling
results for air impacts were reviewed for this analysis. Presumably all near-surface contaminated soils
have been addressed so as to prevent unacceptable contaminated dust transport to the surrounding areas.
Although there were general air permits that apply to construction activities at the site, there are no active
permits associated with the treatment plant operation. Unlike a treatment system that addresses volatile
organic compounds (VOCs), there are no releases of air pollutants from the system that would merit a
permit.
5.4 SOIL
This analysis did not involve a detailed evaluation of the adequacy of soil remediation at the site. There
are no apparent unacceptable health risks due to exposure of shallow soils remaining at the site following
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soil treatment. It is understood from discussions during the site visit that significantly contaminated soil
extended to depths below the water table and the depths accessible to excavation techniques used in the
soil remediation efforts. These soils may represent a continuing (for some time) source of arsenic
contamination to groundwater.
5.5 WETLANDS AND SEDIMENTS
The remediation of sediments in and adjacent to Blackwater Branch is on-going and no evaluation of the
adequacy of the work was undertaken. The restored section of Blackwater Branch east of the North Mill
Road bridge appears to offer healthy habitat.
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6.0 RECOMMENDATIONS
Cost estimates provided herein have levels of certainty comparable to those done for CERCLA Feasibility
Studies (-30%/+50%), and these cost estimates have been prepared in a manner generally consistent with
EPA 540-R-00-002, A Guide to Developing and Documenting Cost Estimates During the Feasibility
Study, July, 2000. The costs presented do not include potential costs associated with community or
public relations activities that may be conducted prior to field activities. The costs and sustainability
impacts of these recommendations are summarized in Tables 6-1 and 6-2.
6.1 RECOMMENDATIONS TO IMPROVE EFFECTIVENESS
6.1.1 FURTHER CHARACTERIZE EXTENT OF CONTAMINATION
The groundwater contamination found near monitoring wells MW54S/M north of the Blackwater Branch
is currently uncontrolled. Permanent monitoring wells are needed to allow future definition of the
northern and western extent of this plume, and would be based on the recent direct-push sampling
results. It is assumed that two new permanent monitoring wells would be sufficient. The source of this
contamination is not known and additional characterization should be conducted to assure there is no
residual soil contamination that would represent a risk to human and ecological receptors or to
ground/surface water. The cost for installing the two assumed monitoring wells might be on the order of
$30,000, including planning, preparation, oversight, waste disposal, and well development. Continued
sampling of these wells on an annual basis might increase annual costs by approximately $1,500. The
RSE team has not estimated the additional costs for source area investigation.
6.1.2 CONSIDER MODIFICATIONS TO THE GROUNDWATER EXTRACTION SYSTEM TO
ASSURE CAPTURE
There are two areas that appear to have some evidence of incomplete plume capture, as discussed above;
between extraction wells RW02 and 03, and between RW07 and 08. If operation of the current extraction
system is to be continued, it is recommended that additional study, including both trend analysis for
concentrations in monitoring points near these locations and groundwater modeling, be conducted to
evaluate the conditions in these areas. Refer to Recommendation 6.4.1 for considers regarding a
hydrogeological evaluation for improving understanding of groundwater flow and model calibration.
Additional piezometers may be useful to better define the capture zone in both the shallow and mid-depth
portions of the aquifer. If deemed necessary following the study, additional groundwater extraction wells
could be installed midway in these "gaps" to increase confidence of capture in these areas. These new
wells would be constructed in a similar manner to the existing extraction wells, though would not need to
pump at as quite a high rate as nearby wells, provided the existing wells also continue to operate. These
new wells could use the same header pipeline that serves the nearby wells. Flow rates could be allocated
among new and existing wells as per the optimization study recommended in Section 6.2.3.
6.1.3 ADDITIONAL MONITORING OF GROUNDWATER QUALITY BETWEEN EXTRACTION
WELLS AND BLACKWATER BRANCH
In order to verify that the extraction wells in the northeastern part of the site are drawing contaminated
water back from Blackwater Branch (and to determine the degree of induced recharge from the stream), it
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is recommended that two to three additional monitoring wells be installed north and northeast of
RW04/06 and MW28S/M. This would support not only the understanding of the current system
performance, but also the assessment of the potential consequences of the use of treated water injection
(with amendments) to help stabilize contaminants in the core of the northern arsenic plume (discussed
elsewhere in this section). This recommendation might be appropriate to implement in conjunction with
Recommendation 6.4.1. The cost for installing two monitoring wells might be on the order of $30,000,
including planning, preparation, oversight, waste disposal, and well development. Continued sampling of
these wells on an annual basis might increase annual costs by approximately $1,500.
6.2 RECOMMENDATIONS TO REDUCE COSTS
6.2.1 DISCONTINUE AUTOMATED SAMPLER AND Do NOT REPLACE THE UNIT
The treatment plant has had extensive process sampling, especially compared to other treatment plants in
the Superfund program. This extensive process sampling has allowed the site team to develop a very
good understanding of the system and its reliability. One component of this process sampling is the use
of an autosampler that collects hourly total arsenic samples of the plant effluent. The unit has reportedly
worked well for approximately 5 years but is becoming troublesome, requiring attention on a daily basis
by one of the USAGE staff and new parts. In 2009, approximately $4,200 was spent on parts for the
autosampler. The site team is considering replacing the unit at a cost of approximately $65,000.
Very few sites within the Superfund program (regardless of complexity) have autosamplers on the plant
effluent because experience with the plant and routine process sampling on a weekly or monthly basis is
adequate to evaluate plant performance. In most cases in the Fund-lead program where autosamplers
were in place, they are no longer used. In the case of Vineland, the autosampler has served an important
purpose. It has generated off-hours alarms due to system upsets, but the site team reports that, in each
instance, the turbidity meter provided adequate information for the site alarm. The autosampler has
therefore played an important role in the site operators learning to control the plant and the causes of plant
upsets. This additional level of sampling, however, is no longer needed. The plant performance can be
evaluated visually and by ORP, pH, and turbidity data when staff are present, and the various SCADA
alarms are adequate to warn of system upsets during off hours.
The RSE team recommends that the site team discontinue use of the existing autosampler and advises
against replacing the unit. The RSE team estimates that implementing this recommendation will save
approximately $65,000 upfront and an unspecified amount of additional savings associated with parts,
reagents, and time. Discontinuing use of the autosampler should not expose EPA, USAGE, or the
contractor to additional liability. The permit equivalency requires sampling twice per month, and the site
team already chooses to sample on a more frequent basis (weekly). In addition, as stated above, the plant
operators have more than adequate experience in operating the plant to remain in compliance.
6.2.2 ELIMINATE ROUTINE ON-SITE ARSENIC SAMPLING
Arsenic samples are collected from the equalization tank each morning, from the filter feed tank every
two hours while the plant is staffed, and from the plant effluent every two hours while the plant is staffed.
The samples are analyzed on-site with a graphite furnace. The real-time ORP, pH, and turbidity data
combined with operator experience, the new SCADA system, and the regular sampling with off-site
analysis are sufficient to evaluate the plant performance. It is for these same reasons that the plant is no
longer staffed 24-hours per day. Like the autosampler, the on-site graphite furnace has given the
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operations team the ability to troubleshoot and learn plant performance and gain confidence in the
reliability of plant operation. However, after almost 10 years of plant operation and 6 years of operation
with the new SCADA system, this frequency of sample collection and analysis should no longer be
required. The RSE team reviewed the results of the analyzed grab samples, and the results confirm
reliable operation of the treatment plant. There are instances of "spikes" in arsenic contamination, but
many of them are either explained by plant modifications that were made (e.g., replacement of an air
fitting on a sand filter in February 2010 and replacement of the polymer mixer on March 20, 2010) or
appear spurious and uninformative.
In 2009, the site team spent approximately $5,000 on lab supplies and graphite furnace parts. More
importantly, the process of collecting and analyzing the samples likely requires 2.5 to 3 hours of operator
attention each day. Eliminating this frequent sampling and analysis will help the site team appropriately
reduce operations staff. Implementation of this recommendation alone will not likely allow further staff
reduction, but implementation of this recommendation plus other streamlining could likely help the site
team reduce staff to two full time equivalent employees.
The RSE team suggests maintaining the graphite furnace but only using it occasionally when
troubleshooting an issue or testing the plant under different operational parameters, such as significant
adjustments to the extraction system or considering alternative chemical additions. The site team could
also choose to collect and analyze a sample with the graphite furnace prior to conducting the formal
discharge sampling. However, the operator experience with the site and the more aggressive voluntary
target of 0.02 mg/L relative to the compliance standard of 0.05 mg/L is sufficiently conservative to be
confident in plant performance prior to the formal sampling. The RSE team discussed the operation of
graphite furnace instruments with a chemist who confirmed that these instruments can operate effectively
when shut down and restarted on an occasional basis as long as the instrument is kept clean. The site
team could discuss this further with the manufacturer if they have additional concerns about this type of
operation schedule.
6.2.3 REDUCE EXTRACTION RATES TO THOSE THAT ARE NECESSARY FOR PLUME
CAPTURE
The current extraction system is likely pumping more water than necessary overall than is necessary to
capture the arsenic plumes. Further analysis of the potential changes in the pumping rates and locations
should be conducted, preferably using automated tools compatible with the code used for the site
groundwater model. New locations for pumping wells should be explored in addition to the existing
wells and injection well placement options could be explored as well. Cost analyses should be conducted
in conjunction with the model optimization to account for the cost of new extraction wells and necessary
piping, and the cost savings for treatment based on the revised total flow rates. Assuming the existing
model can be effectively linked with optimization software (e.g., MODMAN), the cost for a flow model
optimization analysis would be on the order of $20,000; however, the potential savings may be several
multiples of that amount saved in a single year of operation of the plant if it can be operated at a lower
flow rate. Prior to use of the model for these purposes, the site team should recalibrate the model based as
discussed in Recommendation 6.4.1.
The cost breakdown in Section 4.6 indicates $456,000 is spent on items that scale directly with the system
flow rate, including process system electricity, chemicals, and waste disposal. Therefore, a decrease in the
extraction rate will translate to direct savings. In addition, with reduced flow rates there may be potential
for additional savings. The extraction rate required for plume capture is not currently known, but is
estimated to be approximately 500 gpm using the current extraction well layout, but might be under 300
gpm using an optimized extraction system. As an example of the potential cost savings associated with
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reducing the extraction rate, the RSE team assumes a 50% reduction with extraction occurring in the same
number of wells.
A 50% reduction in the extraction rate would result in a direct costs savings of approximately $228,000
per year. Modifications would likely be needed to the treatment plant, including use of one DAF, use of
one or two sand filters, and replacement of chemical feed pumps. If flow is dropped below 400 gpm (or
some other similar value determined by the site team), it may be appropriate to switch flow from the
inorganic treatment train to one of the two organic treatment trains. Alternatively, it may make sense to
divert flow from the existing inorganic treatment train through one of the smaller DAFs associated with
the organic treatment train. It is noted, however, that these types of changes would require some
modification prior to use. The RSE team has not estimated the costs for making these various changes.
As the extraction rate decreases, the residence time in the equalization tank increases, allowing for further
stabilization of the flow rate which will further facilitate plant operations. At a flow rate of 400 gpm and
using the full capacity of the 300,000 gallon tank, the residence time in the equalization tank exceeds 12
hours.
6.2.4 EVALUATE GROUNDWATER MONITORING COSTS
The site team reports an annual budget of $115,000 per year for groundwater monitoring of 90 wells with
low-flow sampling. Using the following reasonable assumptions, the RSE estimates that this sampling
scope should cost approximately $60,000 per year.
90 samples collected per year
Low-flow sampling with non-dedicated pumps and tubing
4 wells per 10-hour day for a two-person sampling team (site records indicate 5 to 6 wells per
day)
$80 per hour per technician
$2,500 per week for equipment and materials
120 samples to be analyzed (including quality assurance samples)
$15 per sample for analysis
$200 per day for travel
The RSE-team estimated $60,000 per year and the budgeted $115,000 per year is a large discrepancy and
merits evaluation to determine the cause of the additional expenditures. The RSE team believes that
careful evaluation of the sampling budget and scope will review the inefficiencies and that the site team
will be able to identify appropriate means of addressing these inefficiencies. If this is the case, savings of
approximately $55,000 per year might be realized.
6.2.5 CONTINUE TO OPTIMIZE GROUNDWATER MONITORING PROGRAM
The project team has done an excellent job in periodically reassessing the monitoring program to assure
that it efficiently supports site decisions. Based on the analysis conducted for this RSE, some
modification to the monitoring network is recommended that may allow reductions in monitoring costs
while maintaining a strong basis for evaluating remedy performance. Potentially redundant wells have
been identified, including EW01M, EW05M (or 06M), EW13M, EW16M, EW17M and 17S, EW-18M
and 18S, EW23M and 23S, MW27M and 27S, MW34M, MW45S, and MW5 IS. Cost savings due to this
change would be conservatively estimated at $10,000/year, assuming annual sampling at $670/sample.
This cost savings is consistent with the sampling costs estimated by the RSE team. Estimated savings
based on the current sampling budget would be on the order $19,000 ($1,280 per sample). These wells
should not be abandoned as they can provide valuable (and inexpensive) piezometric data.
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The project team should evaluate the potential use of the Hydrasleeve or SNAP samplers in lieu of the
low-flow sampling currently done. This has the potential to provide comparable data on arsenic with a
significant reduction in costs. A reduction of 30 minutes per well in the sampling time would translate
into a reduction of 90 person-hours/year (0.5 hours x 2 people x 90 samples), which could translate into a
cost reduction of over $7,000/year assuming $80/hour and accounting for a rough cost for the
samplers. A comparability study would be necessary at a select subset of wells. This would temporarily
increase costs, but the long-term nature of the project would assure a large payback.
6.2.6 Focus BUILDING HEATING AND LIGHTING ON KEY PROCESS AREA
The process area is approximately 7,500 square feet with a 20-foot high clearance for a total of 150,000
cubic feet. However, due to past optimization by the site team, approximately half of this area is no
longer used. The potassium permanganate room is no longer used and neither are the two DAFs for the
organic treatment train. The site team might consider localizing or target process area heating on the parts
of the system that are used in an attempt to reduce natural gas usage. The site team could hang curtains to
separate the areas that require heating from areas that do not require heating. Assuming the volume to be
heated is approximately 50% of the current volume but that the heat containment by the curtains is only
50% efficient, the site team might reduce natural gas usage by approximately 6,100 therms per year or
approximately $6,900 per year. The RSE team does not have an accurate cost for the curtains or other
partitioning that the site team may devise. The RSE team believes this would be cost-effective if effective
partitioning or other focus of process area heating can be implemented for under $25,000. This
recommendation should be considered after the treatment process is optimized and refined based on the
recommendations from Sections 6.1 and 6.2.
6.2.7 EVALUATE CHEMICAL USAGE
Arsenic removal by oxidation and adsorption to iron is a relatively complex process, and the chemical
usage from site to site will vary based on water quality. At the Vineland site, the chemical usage is higher
than would be expected based on a stoichiometric analysis, and the hydrogen peroxide usage is higher
than expected by the widest margin as discussed below. The ferric chloride usage is higher than typically
reported, but given the low concentrations sought by the project team and the variation in the influent
water quality, the ratio of ferric chloride to arsenic is not unreasonable. The sodium hydroxide use is
about double what would be expected based on the ferric chloride addition but could likely be explained
by other constituents in the water. The plant operators have reportedly arrived at the current chemical
dosages based on experience, and have learned that reductions in the chemical usage result in increases in
the effluent arsenic concentration.
Although hydrogen peroxide is the smallest contributor to chemical costs, it is the chemical that has the
most potential for use reduction. Approximately 27 gallons per day of 50% hydrogen peroxide is used to
oxidize constituents in the influent process water. The RSE team estimates that the actual hydrogen
peroxide usage exceeds the stoichiometric hydrogen peroxide usage for influent arsenic (0.3 mg/L) and
ferrous iron (2 mg/L) by 18 to 1. The extra usage may be due to other oxidant demand in the influent
and/or potentially for higher concentrations needed to oxidize the organic arsenic. It may also result from
the relatively short residence time in the oxidation tank (approximately 15 minutes). Aeration could
effectively oxidize the ferrous iron, and potentially other constituents in the influent, which would reduce
the oxidant demand for hydrogen peroxide. Therefore, the hydrogen peroxide usage could likely be
reduced by the use of aeration. Hydrogen peroxide use might be further reduced by either extending the
contact time of the process water with the hydrogen peroxide prior to ferric chloride addition or slightly
raising the pH by adding a limited amount of neutralizing agent (e.g., sodium hydroxide) in advance of or
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during the oxidation stage. The RSE team suggests bench scale jar testing to evaluate the following
possibilities for optimizing the oxidation stage:
Aeration of the process water prior to the addition of hydrogen peroxide
Additional residence time after hydrogen peroxide addition and prior to ferric chloride addition
Aeration of the process water prior to the addition of hydrogen peroxide plus additional residence
time after hydrogen peroxide addition but prior to ferric chloride addition
Aeration and pH adjustment of the process water prior to the addition of hydrogen peroxide
Aeration and ferric iron addition (e.g., recovered iron sludge) prior to the addition of hydrogen
peroxide
If the testing suggests a significant reduction in hydrogen peroxide use, then the site team could evaluate
the costs for modifying the treatment train and the potential savings resulting from the change. The site
team could use some of the unused tanks in the treatment compound as part of these modifications.
The RSE team estimates that the cost for bench scale testing and documentation of the results might be on
the order of $20,000. Plumbing additional tanks into the treatment train and adding a 5 HP blower and air
distribution manifold might cost on the order of $30,000. An additional $10,000 might be needed for
trouble shooting, sampling, and refining chemical usage once the change is in place.
Hydrogen peroxide addition currently costs approximately $27,000 per year. Assuming half of this
demand ($13,000) could be accomplished by aeration, the RSE team estimates that electricity costs for
blower operation would be on the order of $6,000 per year for a net savings of $7,000 per year, resulting
in a payback period of 8 to 9 years. This may not be sufficiently favorable to implement, but reducing the
hydrogen peroxide use by 75% would save approximately $14,000 per year for a payback period of
approximately 4 years.
The site team also suggests revisiting the dosage of ferric chloride. This could be done by a series of
OO O O J
bench scale testing and possibly with treatment plant operation. If the dosage for the treatment plant is
modified, the dosages and resulting effects on arsenic treatment should be documented so that the
evidence for the arsenic dosage is not anecdotal. The focus on ferric chloride is important because ferric
chloride is a significant cost, it directly affects the amount of sodium hydroxide use (which is also a
significant cost), and it directly affects waste disposal (which is also a significant cost).
6.2.8 CONSIDER USE OF A PLATE AND FRAME FILTER PRESS TO DEWATER SOLIDS
The current solids dewatering process has the benefit of operating without much operator attention.
However, there are disadvantages as well.
The centrifuge generates sludge with slightly over 20% solids.
The centrifuge requires approximately $37,000 per year in anionic polymer to maintain current
solids production.
The addition of polymer requires potable water addition.
The centrifuge requires approximately $3,500 per year in electricity usage.
A commonly used alternative for dewatering is a plate and frame filter press. The filter press might
achieve dryer sludge cake and should not require the use of anionic polymer. However, operation would
likely require additional labor. Assuming the filter press is capable of providing sludge with 30% solids
content, the RSE team estimates that approximately 4 cubic yards of solids would be generated per week.
This might translate to running a 20 cubic foot filter press once a day. This would not be a significant
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increase in labor, and the energy required to operate the filter press is likely similar to the energy for the
centrifuge and conveyors. The site team might expect a 30% decrease in hazardous waste for a cost
savings of approximately $24,000 per year in addition to a savings of approximately $37,000 per year
from avoided polymer use. The RSE team therefore estimates total savings might be on the order of
$60,000 per year for a relatively minor increase in labor.
The capital cost for acquiring and installing the filter press is highly dependent on the available
government-owned filter presses and compressors. The site team states that the soil washing remedy,
which will soon be dismantled, has plate and frame filter presses. The RSE team did not review the
specifications of these filter presses to determine if they are of appropriate size for this application. If
they are not, RSEs conducted at Fund-lead Superfund sites identified several filter presses that are not
being used. USAGE has previously maintained a list of used equipment, and this may be a starting point
to identify this equipment.
Prior to investing in permanent changes, the site team should pilot dewatering with the sludge to evaluate
performance and costs and determine if the change is warranted.
6.2.9 CONSIDER THE USE OF LIME FOR pH ADJUSTMENT
The site currently uses approximately 260,000 pounds of sodium hydroxide per year for pH adjustment at
a cost of $72,000 per year, and the unit cost of sodium hydroxide was recently much higher suggesting
future unit cost increases are likely. The same degree of pH adjustment could be achieved using
approximately the same weight of lime, but lime should cost approximately $0.10 per pound (bulk) to
$0.15 per pound (bagged) for an annual cost of $26,000 to $39,000 per year. This represents a potential
savings of $33,000 to $46,000 per year. Capital costs would be required for acquiring a lime storage and
feed system, and further costs would be required for adjusting treatment plant operations to this substitute
process and troubleshooting. The RSE team estimates that it might cost $200,000 to design, procure, and
implement a lime feed system based on bagged lime or up to $400,000 to design, procure, and implement
and automated lime feed system. This approach therefore has a payback of approximately 6 to 10 years.
However, this payback only applies at the current groundwater extraction rate, chemical usage rate,
current sodium hydroxide cost, and assumed lime cost. A decrease in the extraction rate and chemical
usage rate would decrease the return on investment (ROI). An increase in the sodium hydroxide cost
and/or a lower estimated lime cost would make the ROI better. The site team might want to obtain lime
costs from local vendors and refine the cost estimate for constructing an appropriate lime storage and feed
system. If the investment based on this refined analysis appears favorable, the site team could then
evaluate other factors, including potential for scaling and increased operator time.
6.2.10 CONTINUE TO STREAMLINE PLANT AND PROJECT STAFFING
The site team has done an excellent job streamlining the treatment plant and streamlining plant operations
staff, and the RSE team believes that further improvements will be made due to implementation of some
of the RSE recommendations and additional ideas from the site team. Further streamlining in project
management, technical support, and reporting should also be feasible. As a point of comparison, the RSE
team provides the following representative information from select EPA or State-lead Superfund Sites
that can be compared to $250,000 per year for project management and technical support by the
contractor, data evaluation provided by USAGE (cost unknown), and 3.5 full-time equivalent treatment
plant staff for O&M of an optimized system. This information is provided to help the Vineland site team
establish a goal or target for project management, technical support, and O&M labor. Each site is
different and has its own complexities, but continued optimization from the site team and from
implementing the RSE recommendations can help achieve these goals.
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Site Name
Baird and McGuire
(100 gpm naphthalene and arsenic removal)
Selma Pressure Treating
(200 gpm iron co-precipitation system)
Groveland Wells
(90 gpm metals removal, filtration, UV/OX)
ARGO
(Acid mine drainage with problematic system)
Havertown PCP
(product recovery, metals removal, UV/OX,
and GAC)
Greenwood Chemical
(metals removal, UV/OX, and GAC)
Pentawood Products
(90 gpm chemical addition, DAF and GAC)
Relevant Site Information
$635,000 in labor in 2008 for O&M, PM, consulting,
sampling, and reporting
PM and technical support under 40 hours per month
Operated effectively by one FTE
$150,000 for two layers of PM, technical support, data
evaluation, and reporting
1.5 FTEs for O&M
$60,000 for project management and administration
5 FTEs for O&M (includes engineering support)
$75,000 per year for project management, technical
support, data evaluation, reporting, administration, and
design upgrades
1 FTE for O&M plus 1 part-time engineer to upgrade plant
$100,000 per year for PM, technical support, data
evaluation, and reporting
2 FTEs for O&M
$150,000 per year for PM, technical support, data
evaluation, and reporting
1.25 FTEs for O&M
One of the primary reasons for the additional operations staff is the frequent attention given to
maintaining and rehabilitating the extraction system. If this and other practices can be streamlined, the
plant operation staff could likely be decreased. For project management and technical support, the RSE
team suggests that the site team should strive for a target PM budget of approximately $100,000 per year
($30,000 for managing plant logistics, $30,000 for preparing monthly reports, $30,000 for technical
support, and $10,000 for additional meetings or communication). Additional, non-routine PM/support
funding can be added for specific tests or circumstances, such as adjusting plant operations when some of
the RSE recommendations are being tested or implemented (e.g., operating the plant at a reduced flow
rate or using lime in place of sodium hydroxide).
6.2.11 BASED ON OUTCOME OF OTHER RECOMMENDATIONS, CONSIDER POTENTIAL FOR
DELISTING WASTE SLUDGE
The potential for the sludge produced by the treatment plant to be delisted as a hazardous waste was
investigated. A detailed analysis is provided as Attachment H. The ROD addressed the delisting issue
for soil and sediment, but not specifically for waste generated by treatment of groundwater. The
contaminated soil, groundwater, and sediment are considered K031 listed waste, and the sludge would
also be considered waste under the "contained-in policy" but the sludge does not fail the toxicity
characteristic leaching procedure (TCLP) test. The delisting of the sludge may require either an BSD or
ROD Amendment. A ROD Amendment may open a number of issues related to the change in the MCL
for arsenic and more recent NJDEP soil remediation standards. The process to delist waste (or to do a
ROD Amendment) is complex and time consuming. The potential cost savings in delisting the sludge and
allowing it to be disposed of in a Subtitle D facility instead of a Subtitle C facility would have to be
carefully weighed relative to the time and cost for delisting and preparation of any ROD Amendment or
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BSD. Cost savings would be highly dependent on the outcome of other recommendations, including
optimization of the extraction system, using a plate and frame filter press, and potential use of combined
heat and power (see Section 6.7). Under the current operating parameters, the RSE team believes that
annual costs might decrease from approximately $80,000 per year to under $30,000 per year for a savings
of more than $50,000 per year. However, if the extraction rate is decreased by 50%, this savings would
likely be less than $25,000 per year, and if a plate and frame filter press is used in addition to reducing the
extraction rate, the savings would be decreased to under $20,000 per year. The RSE recommends that this
recommendation be considered after the other recommendations that affect waste generation are fully
addressed.
6.3 RECOMMENDATIONS FOR TECHNICAL IMPROVEMENT
6.3.1 REFINE WELL REHABILITATION PRACTICES
The well rehabilitation process has been improved by the project team, but currently represents a
significant investment in time and project funds. The use of the prophylactic treatments of the extraction
wells by glycolic acid may want to be reconsidered. A more aggressive redevelopment treatment
approach that builds on the successful use of jetting, but includes rigorous disinfection and use of
dispersants with acids to break down biomass "slime" may allow longer periods between treatments and
reduce costs for well maintenance. It is recommended that such changes be considered by the project
team. Establishment of a clear threshold for the aggressive redevelopment based on changes in specific
capacity of the well and other indicators such as BART test kits would be appropriate. Products are
available to support this work (e.g., the Baroid AquaClear series). Additional information, including
some on the chemicals used in well maintenance programs, is available in USAGE Engineer Pamphlet EP
1110-1-27, Operation and Maintenance of Extraction and Injection Wells at HTRW Sites, Chapter 6 (see
http://140.194.76.129/publications/eng-pamphlets/eplllO-l-27/toc.htm). The cessation of the continuous
treatment of some of the wells with the Redux product may also be warranted in the absence of clear
evidence for benefit to the well performance. No estimate is made on the potential cost savings for this
recommendation due to the uncertainty on the performance of such treatment, but pilot testing for specific
"problem" wells would be appropriate.
6.3.2 DISCONTINUE USE OF CURTAINS AND ELECTRICAL HEATERS FOR SAND FILTERS
The site team currently uses curtains and electrical resistive heaters around the bottoms of the sand filters
to help avoid freezing while the plant is down during the winter. The plant, however, is rarely down for
an extended period of time unless there is a power outage, and in these cases electricity is not available
for the heaters. The RSE team suggests improving the insulation in the subject areas and discontinuing
continuous electrical heating. The site team could purchase and keep radiant propane heaters on-site to
prevent against freezing during power outages. Propane is a more efficient source of heat than electricity,
the heaters need only be used while the plant is not operating for an extended period of time, and the
heaters can work in the absence of electricity. If recommendation 6.7.1 (combined heat and power) is
implemented, a reservoir of hot water plus hydronic heating elements can be used to provide the
necessary heat during limited power outages. The costs and savings associated with this recommendation
are likely negligible and difficult to quantify because they would be based on the number and duration of
system shutdowns and power outages.
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6.3.3 CONTINUE WITH PLAN TO REMOVE SOIL WASHING EQUIPMENT FROM THE SITE
The site team indicated that operations staff time is being used to exercise the equipment associated with
the soil washing remedy. The site team also indicated that the equipment will not be used again for the
site and that they are planning on selling or transferring the equipment to another site. This will free-up
more operator time and allow the site team to optimize staffing for the treatment plant.
6.3.4 PREPARE AN ANNUAL REPORT
Groundwater data, extraction well performance, and modeling are reviewed relatively frequently at the
site to determine a path forward, but the RSE team is not aware of this analysis being documented or
summarized in an annual report as is done at most other Superfund sites with long-term groundwater
remedies. The RSE team suggests that the data analysis, site conceptual model, and remedy performance
be documented in an annual report on an annual basis. EPA document EPA-542-R05-010 O&M
Template for Groundwater Remedies can be used as guidance for this report. The USAGE also has
sample contract language to require contractors to collect and report the necessary data to support
performance evaluation. At many sites of reasonable complexity, the reports cost on the order of
$25,000 to manage and evaluate the data, prepare tables and figures, and provide interpretive text. Along
similar lines, the site team should finalize the Five-Year Review that remains in draft form.
6.4 CONSIDERATIONS FOR GAINING SITE CLOSE OUT
6.4.1 EVALUATE POTENTIAL FOR NATURAL ATTENUATION AND SUGGESTED CRITERIA
FOR DISCONTINUING P&T
The ROD states that the effectiveness of natural attenuation and P&T to protect Blackwater Branch
should be compared. The ROD also states the need to reevaluate the maximum arsenic criteria of 0.35
mg/1 to determine if it is sufficiently protective of Blackwater Branch in the absence of pumping. The
RSE team believes that the next several years is the time frame to conduct these studies and offers a
suggested path forward consisting of the following elements:
Hydrogeological analysis
Geochemical analyses
Fate and transport simulations
Potential pilot testing
Hydrogeological Analysis
The site team has an existing model, but the recognizes that the model is somewhat limited due to the
transient nature of the groundwater system at the site due to a relatively flat hydraulic gradient and
changes in the stage of Blackwater Branch. The site team further recognizes potential anomalies in the
surveyed points used for developing water levels at the site. These items need to be addressed before
applied to the evaluations natural attenuation and the 0.35 mg/1 criteria. The RSE team suggests the
following items to address these concerns:
Resurvey all site monitoring wells and stream gauges
Conduct the following four synoptic rounds of water level events
o Non-pumping conditions during low regional groundwater flow
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o Non-pumping conditions during high regional groundwater flow
o Pumping conditions during low regional groundwater flow
o Pumping conditions during high regional groundwater flow
(Note: The extraction system should be discontinued for a full week or longer prior to the
non-pumping water level events to give the aquifer a chance to rebound from pumping
conditions.)
Calculation of stream flow at up to five or six locations during the above four events
Monitoring of transient water levels during system shutdown and startup
Recalibration of the groundwater model based on the four new static water level events and
stream flow calculations
Calibration of the groundwater flow model to the transient data from the shutdown and/or restart
tests
Geochemical Analyses
Site geochemistry plays a significant role in arsenic adsorption and therefore arsenic fate and transport.
Furthermore, the geochemistry can be altered via chemical amendments to create more favorable
conditions for arsenic immobilization and associated arsenic plume attenuation. The goals of these
analyses are as follows:
Obtain site-wide information about the magnitude and distribution of iron, aluminum, and arsenic
concentrations in saturated soils and groundwater
Obtain geochemical parameters in groundwater to assess the buffering capacity of the system and
the presence of species that may compete with arsenic for adsorption sites
Conduct bench scale testing, including complete-mix reactors and column studies to estimate
partitioning coefficients for arsenic in different areas of the site and determine the rate transfer
coefficient and diffusion characteristics required for fate and transport analysis
Simulate arsenic fate and transport given existing aquifer conditions
Conduct bench scale tests to determine the natural oxidative demand of the soil and the ability to
oxidize arsenite to arsenate in-situ
Conduct bench scale testing to determine the effect of chemical addition (e.g., iron, pH
adjustment, and various types of oxidizing agents that may be needed to convert arsenite to
arsenate in order to increase the effectiveness of immobilization) on the arsenic partitioning
coefficients
Simulate arsenic fate and transport given aquifer conditions enhanced with chemical addition
If results of the above studies are favorable, conduct field scale pilot studies to determine
performance in the field and to estimate scale-up costs
Determine the areas of the site most suitable for arsenic immobilization, and, consequently, areas
most suitable for continued P&T
To achieve these goals, this recommendation has the following components.
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The site team could mobilize a direct-push rig to collect soil samples from many locations throughout the
site. The RSE team suggests a broad study across the approximate 1,500-foot by 1,500-foot plume area,
perhaps on an approximate 250-foot by 250-foot grid with soil samples collected from both the shallow
and mid-depth zones. This would be a total of approximately 100 samples (50 from each zone). Samples
from these locations and/or adjacent monitoring wells should be analyzed for the parameters outlined in
Attachment I. An optimized list of samples and analyses from Attachment I could be developed at the
work plan stage to limit the total number of analyses conducted but still obtain the needed information.
Based on appropriate groupings, the site team should take a subset of these samples and conduct
equilibrium-based and mass-transfer based jar and/or laboratory column tests (refer to Sanchez 2003) to
estimate the arsenic partitioning coefficient. Similar subsets of soil samples should receive varying
chemical treatments including 1) additional iron in the form of ferric chloride, additional iron in the form
of ferrous chloride, and additional iron in the form of ferric oxyhydroxides, 2) pH adjustment, 3)
additions of oxygen, ozone, free chlorine, hypochlorite, permanganate, and/or hydrogen peroxide in order
to improve the effectiveness of adsorption by oxidizing arsenite to arsenate. The samples should then
undergo testing to evaluate the changes in the arsenic partitioning coefficient and determine the rate
transfer coefficient and diffusion characteristics required for fate and transport analysis. Samples with
adsorbed arsenic can then undergo reasonable changes in conditions (e.g., modifications to pH and/or
ORP to evaluate adsorption stability).
Fate and Transport Modeling and Simulations
Results from simulations with site groundwater model that indicate flow paths under natural and various
pumping schemes should be combined with the measured partitioning coefficients to estimate time of
travel for arsenic to reach surface water. For sensitive areas of the site, the contaminant transport
modeling can be conducted. A site-wide transport model may or may not be necessary. However, a site-
wide model that can reproduce the changes in the arsenic concentrations in the mid-depth monitoring
wells between 2002/2003 and 2008/2009 will increase the confidence in the predictive capabilities of the
model. The ability of the model to reproduce these conditions reasonably assumes that P&T is primarily
responsible for the concentration changes the mid-depth wells and that source removal may have had
some influence on concentration changes at specific shallow wells. Relatively simple transport models
using MODFLOW and MT3D might be appropriate to simulate idealized "study areas" to predict the
concentrations of arsenic that would discharge to surface water. The output could then be modeled using
a tool such as CORMIX to evaluate surface water mixing. Results of the mixing would need to be
compared to the 0.05 mg/1 standard established in the ROD or any other surface water Applicable or
Relevant and Appropriate Requirements (ARARs). Discussions would likely need to occur with NJDEP
to determine the appropriate regulatory mixing zone for this discharge to Blackwater Branch.
These simulations, which are based on the analyses discussed above, should provide a thorough
evaluation of the 0.35 mg/1 criteria and the point at which natural attenuation can replace P&T in
accordance with the ROD.
The above simulations can be repeated with the fate and transport parameters derived from lab testing
with chemical amendments. These simulations would evaluate the effect of chemical addition on arsenic
immobilization and help determine areas of the site that would be well-suited for arsenic immobilization
to either reduce the extent of P&T or reduce the time frame of P&T.
Potential Pilot Testing
If any suitable areas are identified, one or more of them should be subject to field-scale pilot testing. The
pilot tests should likely take the form of a recirculation cell to help isolate the study area from natural
contaminant migration. The recirculation cell would likely take the form of an extraction well, an
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injection well, and several monitoring points between the two wells. Distances should be sufficiently
small to see results in a timely manner with groundwater flow rates that are not substantially higher than
natural groundwater flow rates. The test should likely begin with oxidation to determine the effectiveness
of oxidizing the arsenite to arsenate. Oxidation should likely be tested with air sparging, hydrogen
peroxide, and other oxidants independently. Samples should be taken to quantify the remaining arsenite
concentrations and evaluate the effectiveness of the oxidation. The next step of the test will likely involve
iron addition and pH adjustment. There are several possibilities for iron addition, and further evaluation
is needed to determine the most appropriate means. Some possibilities include the following (in no
particular order of preference):
Inject a ferrous iron solution that can migrate through the subsurface some distance from the
injection point and provide sufficient oxygen and alkalinity to allow it oxidize to ferric iron.
Inject an acidic solution of ferric iron and let it migrate into an area with sufficient alkalinity to
allow it to precipitate.
Create a permeable barrier with a mixture of coarse sand and iron hydroxide sludge, which is a
waste product from some water treatment processes and has the benefit of being relatively cheap
and sustainable).
Add nano-iron that can migrate some distance from the injection point and provide sufficient
oxygen to oxidize it.
Recirculate arsenic impacted groundwater through the test area and monitor the test area's ability to
immobilize the arsenic. If arsenic immobilization is demonstrated, then test the same area with variations
in ORP and pH to determine if the arsenic will remain immobilized under natural conditions.
The RSE team has not determined a full-scale cost for this recommendation, but it seems that costs would
be on the order of $500,000. The RSE team estimates that likely under $100,000 of this amount is needed
to update the groundwater flow model to help confirm capture of the existing system and help determine
the optimized system that minimizes the extraction rate while maintaining capture. As stated in
Recommendation 6.2.3, the RSE team estimates that reducing the system extraction rate by 50% could
save more than $228,000 per year.
Furthermore, the RSE team estimates that significantly more than half of the $500,000 cost is required to
effectively evaluate the 0.35 mg/1 maximum arsenic criteria. The results of the above studies could have
a number of outcomes, including (but not limited to) the following:
Confirmation that a site-wide maximum arsenic concentration of 0.35 mg/1 is protective
Demonstration that a lower site-wide maximum arsenic concentration is protective
Demonstration that a higher site-wide maximum arsenic concentration is protective
Demonstration that a maximum arsenic concentration of 0.35 mg/1 is appropriate within 100 feet
of Blackwater Branch but that a higher maximum arsenic concentration is appropriate further
from Blackwater Branch
If a lower site-wide maximum arsenic concentration is derived, then completion of this study will have
helped prevent the site team from prematurely discontinuing pumping. If a higher maximum arsenic
concentration is determined, then the site team may be able to reduce the operational time frame for the
system. At a cost of $1.7 million per year (or even $1 million per year for an optimized system), reducing
the operational time of the remedy by 5 to 10 years could save close to $10 million.
42
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Other portions of the $500,000 involve evaluating the effectiveness of chemical addition to enhance
arsenic immobilization and design a cost-effective remedy that uses enhanced arsenic immobilization to
significantly reduce the operating extent of the P&T system and/or the operating life of the system. If
P&T operation can be reduced to $500,000 per year for 10 years or the duration of active treatment can be
reduced by 5 to 10 years, significant savings could be realized even with potential significant capital
expenditure for chemical addition.
The RSE team suggests the following approximate timeline for conducting the above activities:
Hydrogeologic analysis field work - complete within 12 month period
Groundwater model update - complete within 6 months following completion of the
hydrogeologic analysis field work
Geochemical analysis - complete field work and laboratory analysis leading up to but not
including the pilot test within a 12 month period
Fate and transport simulations - complete within 6 months following completion of the
geochemical analysis field work and groundwater model update
Pilot testing - if study results are favorable complete pilot testing design, installation, and results
in a 12 month period following the fate and transport simulations.
The field work for the hydgeological and geochemical analyses can be conducted simultaneously because
they do not depend on each other, but the fate and transport simulations need to occur after the
groundwater model has been updated. The pilot testing, if appropriate, would need to follow the
simulations. Accounting for these suggested time periods and potential delays, the study should be
completed within a five-year period.
6.4.2 ACTIVE //V-^/TT/TREATMENT FOR ARSENIC IMMOBILIZATION
The RSE team finds it unlikely that the evaluations in Recommendation 6.4.1 will lead to immediate
discontinuation of the P&T system in favor of natural attenuation. However, the RSE team is hopeful that
the above information will indicate that enhanced arsenic immobilization can play an important role in
cost-effectively reducing the extent of groundwater extraction and the duration of groundwater extraction.
The current groundwater extraction and treatment system could be used, following some modification, to
extract and treat contaminated groundwater from portion of the plume, inject water in strategic locations
to create a hydraulic barrier between the contamination and the creek, and deliver chemical amendments
to the appropriate areas of the subsurface.
One possible configuration would be to inject (via wells or trenches) treated water with amendment
between the northern extraction well line and Blackwater Branch. The injection would help create a
hydraulic barrier to prevent contaminant flux toward the stream while ultimately creating an in-situ zone
for treatment following cessation of active treatment. Extraction would continue from the western
line. Flux of amended water would move from the injection lines westward through the core of the
highest groundwater concentrations, immobilizing some of the mass. This configuration would also
reduce the amount of water requiring treatment while providing control of the plume. Additional
injection of amended water would occur near the source area for the southern and northern
plume. Ultimately, the dissolved arsenic concentrations should diminish and active treatment could be
terminated. Natural flux of upgradient groundwater will maintain stability of iron and arsenic. Figure 6-1
illustrates the possible locations of injection and extraction. The model development discussed in the
previous section and the use of optimization software discussed in Recommendation 6.2.3 could help
43
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determine an optimal strategy. No costs are included with this as there is much uncertainty on the
feasibility and chemistry involved.
6.5 SUGGESTED APPROACH TO IMPLEMENTING RECOMMENDATIONS
The RSE team has provided a number of recommendations that each have individual merit, but that may
conflict with each other if implemented together. The RSE provides the following section for prioritizing
and implementing the recommendations.
The RSE team suggests that the site team address Recommendations 6.1.1, 6.1.3, 6.2.3, 6.4.1, and 6.4.2 as
part of developing a site exit strategy (see next section). Collectively, these recommendations address
plume delineation and optimizing the use of geochemistry and groundwater extraction to contain the
arsenic plume. Based on the results from addressing these recommendations, the site team will have an
understanding of the groundwater extraction rate, the influent water quality, and the extraction (and
possibly injection) wells that will be used. Recommendations 6.3.1 can then be considered for the wells
that will be operating. If the results suggest that the extraction system will remain unchanged, then the
site team should address Recommendation 6.1.2 to confirm the system is providing adequate capture and
6.2.5 to optimize the groundwater monitoring program. If the results suggest reduce flow rates and water
quality, the site team can address the cost-effectiveness and appropriateness of Recommendations 6.2.4,
6.2.6, 6.2.7, 6.2.8, 6.2.9, 6.2.11, 6.7.1, and 6.7.2. Collectively, these recommendations involve
optimization of the groundwater monitoring program and the treatment plant, but they cannot be fully
considered until the site team has settled on a long-term strategy and know the parameter for treatment
plant operation.
Recommendations 6.2.1, 6.2.4, 6.3.2, 6.3.3, and 6.3.4 can occur at any time without interfering with the
other recommendations and should be implemented a soon as possible without detracting from the
resources needed to address the other recommendations.
Recommendation 6.2.10 has two components. Treatment plant staffing should likely remain at its current
level until the remedial strategy has been selected and the treatment plant modified accordingly. The
project management and technical support budget should likely be reviewed and refined as soon as
possible, so that routine effort (project logistics, monthly reporting, basic technical support, and basic
communication) is budgeted separately from special projects and tasks.
6.6 EXIT STRATEGY
6.6.1 SUGGESTED EXIT STRATEGY
The current approach to achieving site closure involves the containment of the groundwater plumes,
source mass removal at and above the water table, and efforts to maximize mass removal from the
saturated zone. Ultimately, the goal is to achieve a concentration (nominally 0.35 mg/1, a value above the
former and current MCL) in groundwater at the site that would prevent the exceedance of 50 ug/L in
surface water. The removal of source materials from the vadose zone has certainly improved the chances
for attainment of these goals, and significant progress has been made in the reduction of concentrations in
the mid-depth portion of the impacted aquifer. Still, efforts to significantly reduce the concentrations and
footprint of the arsenic plume in the shallowest part of the aquifer have had more limited
success. Though bench-scale results have been promising, the results so far for field-scale testing of
methods to increase the mobility of arsenic compounds in the aquifer have been mixed. Increasing
44
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mobility is potentially feasible, but estimates of the time to attain cleanup goals in groundwater are long,
as described above.
As an alternative exit strategy, this study is proposing consideration of ways to leverage the natural
geochemistry of the aquifer in ways that allow stable immobilization of the arsenic in the subsurface, all
while maintaining control of the plume to prevent unacceptable impacts on the Blackwater Branch. If
feasible, the immobilization of arsenic would result in reduction in dissolved arsenic concentrations and
would allow cessation of active remediation at some earlier time compared to the current approach. As
described above, the existing extraction and treatment system may be integrated into the effort to
immobilize the arsenic.
The first steps in the new approach would be to gather data to more fully understand site hydrogeology,
the geochemistry of the interactions between the arsenic and the native soils, and the ability for the
aquifer to naturally attenuate the arsenic through immobilization processes. This would be followed by
efforts to refine the estimate of the acceptable levels of dissolved arsenic in the aquifer that would not
cause unacceptable impacts on the stream. This is consistent with the approach identified in the
ROD. Contaminant transport modeling (that reflects the revised conceptual model based on the
investigations) would be highly beneficial for the task of assessing a new cleanup goal. During these
investigations, the current extraction and treatment system would continue to operate, although
implementation of certain proposed changes meant to optimize its cost-effectiveness would proceed as
appropriate.
If the investigation of the geochemistry and alternative cleanup goal for the aquifer shows that natural
processes could prevent unacceptable impacts on the stream, then the active extraction and treatment
could be terminated (though the extraction and treatment system could be mothballed in case unexpected
impacts on surface water occurred). If the natural processes are determined to be incapable of controling
the release of arsenic to the stream, either the current strategy could be continued or the implementation
of efforts to engineer the processes of immobilization could be pursued. Engineered immobilization of
the arsenic would have to be demonstrated on a pilot scale, and if successful could be implemented in a
way that targets both the source areas (below the water table) and areas near the stream and in areas of
high dissolved arsenic concentrations. It is presumed that a modified groundwater extraction and
treatment system would continue to operate. Once dissolved arsenic concentrations reach the revised
cleanup goals in the aquifer, active remediation would cease, but monitoring would continue for some
period to assess protectiveness.
Throughout the process, periodic optimization of the monitoring program would be necessary, as has been
conducted by the project team to date. The emphasis should be on collecting only the data needed to
support site decisions. Specific rationale can be used to verify that sampling of each well included in the
monitoring network is needed and that the frequency of sampling is still appropriate. Note that sampling
frequency may need to be increased in some locations during major changes in the remedy (e.g.,
implementation of treated and amended groundwater injection, or cessation of pumping).
Ultimately, site groundwater concentrations may reach levels that allow unrestricted use of the site,
though this may not be possible. If not, the Classification Exception Area designation and restrictions on
groundwater use will have to remain in effect indefinitely. Five-year reviews would have to be done on a
recurring basis. However, the level of effort required for the project will have diminished to minimal
levels, including limited sampling to support the five-year reviews and periodic verification of
compliance with land-use restrictions.
45
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6.7 ADDITIONAL SUSTAINABILITY CONSIDERATIONS
6.7.1 CONSIDER COMBINED HEAT AND POWER
Electricity used by the site is generated from coal by the Vineland Municipal Electric Utility at a cost of
approximately $0.14 per kWh. As discussed in Section 4.6, despite offsetting electricity usage with
RECs, electricity use of 1.35 million kWh per year at the site translates to annual emissions of
approximately 560,000 pounds of carbon dioxide equivalents per year, plus emissions criteria pollutants
and hazardous air pollutants.
Generating electricity with natural gas results in fewer emissions than generating electricity with coal, and
generating electricity on-site can be a more efficient use of energy if the waste heat is used for beneficial
purposes (otherwise referred to as combined heat and power). One beneficial purpose is to use the waste
heat for space heating, which eliminates the need for natural gas for heating. Another beneficial purpose
would be to use the heat to evaporate some of the water from the process sludge to reduce the weight of
hazardous waste produced by the remedy. Therefore, the use of combined heat and power could use
energy more efficiently and could result in from substantial reductions in hazardous waste generation.
Because electricity is no longer obtained from the grid, the purchase of RECs is no longer appropriate. If
the site team would like to offset the carbon dioxide emissions from the natural gas combustion, carbon
offsets could be purchased and/or trees could be replanted at the site to store carbon in biomass.
Once the recommendations in the above sections are considered and the site team has determined the
long-term extraction rate for the site, the site team should consider the use of combined heat and power.
In 2009, electricity from the grid averaged $0.14 per kWh and natural gas averaged $1.13 per therm. In
addition, approximately 130 tons of waste that was 75% water was disposed of 700 miles from the site as
hazardous waste at a cost of approximately $80,000. The following analysis holds for the 2009 electricity
usage, natural gas usage, and waste generation and would need to be modified to account for a lower
extraction rate and lower electricity use.
Item
Capital cost for 175kW system
Additional capital for heating applications
Electricity generated (kWh)
Grid electricity avoided (kWh)
Natural gas required (therms)
Natural gas for heating avoided (therms)
Net natural gas used (therms)
Hazardous waste disposal generated from original process (tons)
Hazardous waste disposal avoided (tons) (assume 50% reduction)
Natural gas cost ($)
O&M cost ($)
Carbon offsets ($) (assumes $0.005 per pound)
Annual costs
Electricity cost avoided
Quantity
$385,000
$100,000
1,350,000
1,350,000
162,189
24,400
137,789
260
130
$183,274
$27,000
$8,500
$218,774
$189,000
46
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Item
Natural gas cost avoided ($)
Hazardous waste disposal cost avoided ($)
Avoid costs for purchasing RECs ($) (assumes $0.03/kWh)
Annual avoided costs
Net annual savings
Financial position after 10 years
Quantity
$27,600
$40,000
$40,500
$297,100
$78,326
Savings of $298,260
All combined heat and power values approximated from Technology Characterization:
Reciprocating Engines, prepared for the Environmental Protection Agency, Combined Heat and Power
Partnership, December 2008. The purchased carbon offsets offset carbon dioxide emissions from all
natural gas usage.
As indicated in the above table, the project would result in savings of approximately $300,000 over a 10-
year period. The analysis includes offset of all carbon dioxide emission from natural gas combustion,
which would represent a significant reduction in the remedy's carbon footprint. It also reduces the
hazardous waste generated and the diesel fuel used to transport that waste 700 miles from the site.
The 175 kW system would generate adequate heat for building heat and evaporation. The useful heat
output at temperatures over 200 F is approximately 6,000 btu per kWh of electricity generated for a total
of 8,100 million btus. By contrast, 24,400 therms of natural gas that is currently used for building heat is
equal to 2,440 million btus, and the amount of heat needed to heat 130 tons of sludge and evaporate 65
tons of water (130,000 pounds) is approximately 700 million btus assuming a 25% heating efficiency.
The site team would need to devise a custom heat exchanger to transfer the heat from the combined heat
and power system to the sludge boxes and allow adequate ventilation for the resulting moisture.
6.7.2 CONSIDER ALTERNATIVES FOR IRON ADDITION
A significant portion of the O&M costs and the environmental footprint are associated with the addition
of ferric chloride, the addition of sodium hydroxide, and the disposal of the solids generated by the
treatment plant. One of the primary practices of green remediation is to identify opportunities for
recycling and reuse to minimize use of materials and generation of waste. The site team could consider
obtaining iron hydroxide sludge from other sites that would not add new pollutants to the Vineland
process stream. An example would be iron hydroxide sludge from an acid mine drainage site that has
high iron hydroxide sludge production. This iron hydroxide sludge could be added to the process stream
in addition to or in place of ferric chloride and sodium hydroxide. If effective, using this sludge could
eliminate or significantly reduce the amount of ferric chloride and sodium hydroxide that are added.
Although the total amount of waste generated from Vineland might not be reduced, net waste disposal to
a landfill would be reduced because the sludge from the other site would be used at Vineland prior to
disposal.
There are several aspects to using sludge that require additional consideration, including composition of
the sludge, its effectiveness of adsorbing arsenic, the amount to add relative to system flow rate, how to
adjust existing chemical addition, the capacity of the DAF units for handling in the increased solids
loading, and the properties of the sludge that would be generated. The site team might consider
conducting bench scale jar tests at the treatment plant, using extracted groundwater, appropriate iron
hydroxide sludge from another site, and the on-site graphite furnace for testing results. Based on the
results, the site team can determine if a pilot test is appropriate. If a pilot test is conducted, the site team
could consider conducting it in one (not both) of the currently operating DAF treatment trains or in one of
47
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the currently unused organic treatment trains. The bench and pilot scale testing should be focused to
avoid it from becoming open-ended and expensive.
6.7.3 POSTPONE LIGHTING RETROFIT
The site team has proactively pursued energy efficiency measures including having a lighting survey done
and replacing some fluorescent lighting at the site with the more efficient light-emitting diode (LED)
lights. A recent lighting survey recommended further retrofit of fluorescent lights with LED lights.
Although the RSE team supports the pursuit of energy efficiency measures such as the use of energy
efficient LED lights, there may be substantial changes to the remedy in the next few years based on the
recommendations in this report. The RSE team suggests focusing on the RSE recommendations above
before pursuing further lighting retrofit. The money that would be spent on the lighting retrofit may be
better spent from a green remediation perspective on pursuing reductions in the extraction rates, an in-situ
remedy, or improvements to the treatment process. In addition, one of the recommendations suggests
focusing heating and lighting on the portion of the building that is used. The RSE team believes the
efforts to reduce lighting and heating need should take precedence over lighting and heating efficiency.
Once the above recommendations have been considered and the site team has relative certainty on the
future lighting and heating needs and funding is not constrained, then the site team can revisit the lighting
retrofit.
48
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TABLES
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Table 4-1. Summary of Trend Analyses - 2000 to 2010
Mon.
Loc.
EW04M
EW06M
EW07M
EW10M
EW13M
EW20M
MW39S
MW42M
MW45S
MW48M
MW49M
MW52M
MW52S
EW04S
EW06S
EW08M
EW19M
EW21M
MW28M
MW29S
MW31M
MW32S
MW53M
MW54M
WW25M
WW25S
Concentration
Trend
Decreasing
Decreasing
Decreasing
Decreasing
Decreasing
Decreasing
Decreasing
Decreasing
Decreasing
Decreasing
Decreasing
Decreasing
Decreasing
Stable
Stable
Stable
Stable
Stable
Stable
Stable
Stable
Stable
Stable
Stable
Stable
Stable
Total
Arsenic
(mg/1)
1.37
0.265
0.275
0.009
0.046
0.876
0.41
0.009
0.019
0.009
0.029
0.226
0.242
1.75
0.222
0.031
0.028
0.527
9.56
0.016
2.93
0.016
0.009
0.02
1.39
0.232
Mon.
Loc.
MW37M
MW39M
MW41M
MW45M
EW05M
EW07S
EW08S
EW11M
EW11S
EW13S
EW19S
MW30S
MW31S
MW33S
MW34S
MW47M
WW24S
MW28S
MW38S
MW40S
MW53S
MW54S
MW35S
MW56D
MW56S
Concentration Trend
Decreasing - increase post excavation, then
decrease
Decreasing - increase post excavation, then
decrease
Decreasing - increase post excavation, then
decrease
Decreasing - increase post excavation, then
decrease
Stable - increase post excavation, then decrease
Stable - increase post excavation, then decrease
Stable - increase post excavation, then decrease
Stable - increase post excavation, then decrease
Stable - increase post excavation, then decrease
Stable - increase post excavation, then decrease
Stable - increase post excavation, then decrease
Stable - increase post excavation, then decrease
Stable - increase post excavation, then decrease
Stable - increase post excavation, then decrease
Stable - increase post excavation, then decrease
Stable - increase post excavation, then decrease
Stable - increase post excavation, then decrease
Increasing
Increasing
Increasing
Increasing
Increasing, then abrupt decrease recently
Increasing, then dropping off recently
First sample
First sample
Total
Arsenic
(mg/1)
0.025
0.019
0.016
0.395
0.222
1.72
1.32
0.06
0.075
0.052
0.02
0.545
0.009
0.026
1.17
0.162
0.102
5.7
3.5
0.177
0.018
0.341
1.33
0.011
0.045
Table 4-1 does not include monitoring wells with non-detect, and it does not include wells where recent
measurements of arsenic are not available. Specifically the six wells with stable elevated arsenic concentrations
between 2000 and 2002 are not included in the table below due to limited data set. The arsenic data sets for these
six wells (MW37S, MW30S, MW49S, MW48S, MW36S, andMWISS) are available for the period extending from
2000 to 2002 and are shown in Attachment A. These six wells were damaged during the soil removal and therefore
data for these wells are not available subsequent to 2002. Concentrations in these wells prior to 2002 were elevated
and fairly stable ranging from 10, 1, 5, 1, 1, to 0.8 mg/lfor wells MW37S, MW30S, MW49S, MW48S, MW36S, and
MW15S, respectively (see attachment A).
Table 4-1 includes the trends since pumping at the groundwater treatment plant began and the most recent total
arsenic concentration. Bold, highlighted values are larger than 0. 35 mg/l.
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Table 4-2. Trend Plots in Recovery wells and Estimation of Restoration Time (EPA, 2002)
Ext.
Loc.
RW01*
RW02
RW02a
RW02b
RW03
RW04
RW05
RW06
RW07
RW08
RW09a
RW10
RW11*
RW12
RW13*
Total
Arsenic
(mg/1)
0.222
0.593
0.502
1.22
0.478
0.622
0.288
1.33
0.951
0.698
0.011
0.257
0.009
0.152
0.187
Concentration Trend
Initial increases, stable, pumping reduction caused large
decrease, stable
Initial increases, decreasing
Decreasing
Mild decrease
Initial increase, decrease becoming milder over time
Initial increase, decrease becoming milder over time
Initial increase, decrease becoming milder over time
Significant decrease event in early 2001, decrease becoming
milder over time
Initial increase, decrease becoming milder over time
Significant decrease event in late 2000, decrease becoming
milder over time
Decreasing with recent large fluctuations
Decreasing
Significant decrease in 2003-2004, ND for last 2 years
Initial increase, mild decrease
Initial increase, significant decreases in 2001 and 2002,
increasing
Time to
0.35 mg/1
(yrs)
-
1
<1
14
<1
3
-
20
13
4
-
-
-
-
Currently
below
0.35 but
Increasing
Time to
0.05 mg/1
(yrs)
Stable at
0.222
9
3
36
21
12
27
54
41
21
-
11
-
54
Increasing
Time to
0.01 mg/1
(yrs)
Stable at
0.222
16
6
54
39
20
41
83
65
35
<1
22
-
129
Increasing
^Recovery discontinued.
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Table 6-1. Cost Summary Table
Note: The approximate costs included in this table reflect estimates for individual recommendations given
the current operating system. Implementation of some recommendations could affect or completely
eliminate potential cost savings associated with other recommendations.
Recommendation
6.1.1 FURTHER
CHARACTERIZE EXTENT OF
CONTAMINATION
6.1.2 CONSIDER
MODIFICATIONS TO THE
GROUNDWATER EXTRACTION
SYSTEM TO ASSURE CAPTURE
6.1.3 ADDITIONAL
MONITORING OF
GROUNDWATER QUALITY
BETWEEN EXTRACTION
WELLS AND BLACKWATER
BRANCH
6.2.1 DISCONTINUE
AUTOMATED SAMPLER AND
DO NOT REPLACE THE UNIT
6.2.2 ELIMINATE ROUTINE
ON-SITE ARSENIC SAMPLING
6.2.3 REDUCE
EXTRACTION RATES TO
THOSE THAT ARE
NECESSARY FOR PLUME
CAPTURE
6.2.4 EVALUATE
GROUNDWATER
MONITORING COSTS
6.2.5 CONTINUE TO
OPTIMIZE GROUNDWATER
MONITORING PROGRAM
6.2.6 FOCUS BUILDING
HEATING AND LIGHTING ON
KEY PROCESS AREA
Reason
Effectiveness
Effectiveness
Effectiveness
Cost Reduction
Cost Reduction
Cost Reduction
Cost Reduction
Cost Reduction
Cost Reduction
Additional
Capital
Costs ($)
$30,000
Estimated
Change in
Annual Costs
($/yr)
$1,500
Estimated
Change in
Life-Cycle
Costs
S*
$75,000
Discounted
Estimated
Change in
Life-Cycle
Costs
$**
$59,000
Not quantified
$30,000
($65,000)
$1,500
Not quantified
$75,000
More than
($65,000)
$59,000
More than
($65,000)
Reduction not specifically quantified
Not
quantified
$0
$0
<$ 10,000
($228,000)
Assumes 50%
reduction in
flow
($55,000)
($10,000)
($6,900)
Not quantified
($1,650,000)
($300,000)
($197,000)
($1,078,000)
($197,000)
($125,000)
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Recommendation
Reason
Additional
Capital
Costs ($)
Estimated
Change in
Annual Costs
($/yr)
Estimated
Change in
Life-Cycle
Costs
Discounted
Estimated
Change in
Life-Cycle
Costs
6.2.7 EVALUATE CHEMICAL
USAGE
Cost Reduction
Requires more study. See text for details.
6.2.8 CONSIDER USE OF A
PLATE AND FRAME FILTER
PRESS TO DEWATER SOLIDS
Cost Reduction
Not
quantified
($60,000)
($1,800,000)
($1,176,000)
6.2.9 CONSIDER THE USE
OF LIME FOR PH
ADJUSTMENT
Cost Reduction
$200,000
($33,000)
($790,000)
($447,000)
6.2.10 CONTINUE TO
STREAMLINE PLANT AND
PROJECT STAFFING
Cost Reduction
$0
($150,000)
($4,500,000)
($2,940,000)
6.2.11 BASED ON OUTCOME
OF OTHER
RECOMMENDATIONS,
CONSIDER POTENTIAL FOR
DELISTING WASTE SLUDGE
Cost Reduction
Not
quantified
($50,000)
($1,500,000)
($980,000)
6.3.1 REFINE WELL
REHABILITATION PRACTICES
Technical
Improvement
Not quantified
6.3.2 DISCONTINUE USE OF
CURTAINS AND ELECTRICAL
HEATERS FOR SAND FILTERS
Technical
Improvement
Negligible
6.3.3 CONTINUE WITH
PLAN TO REMOVE SOIL
WASHING EQUIPMENT FROM
THE SITE
Technical
Improvement
Negligible
6.3.4 PREPARE AN ANNUAL
REPORT
Technical
Improvement
$0
$25,000
$750,000
$490,000
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Recommendation
Reason
Additional
Capital
Costs ($)
Estimated
Change in
Annual Costs
($/yr)
Estimated
Change in
Life-Cycle
Costs
Discounted
Estimated
Change in
Life-Cycle
Costs
6.4.1 EVALUATE
POTENTIAL FOR NATURAL
ATTENUATION AND
SUGGESTED CRITERIA FOR
DISCONTINUING P&T
Site Closeout
-$500,000
Not quantified but potentially substantial
6.4.2 ACTIVE IN-SITU
TREATMENT FOR ARSENIC
IMMOBILIZATION
Site Closeout
Not quantified
6.7.1 CONSIDER
COMBINED HEAT AND
POWER
Sustainability
$485,000
($78,000)
($295,000)
After 10 years
($178,000)
After 10
years
6.7.2 CONSIDER
ALTERNATIVES FOR IRON
ADDITION
Sustainability
Not quantified
6.7.3 POSTPONE LIGHTING
RETROFIT
Sustainability
Not quantified
Costs in parentheses imply cost reductions
* assumes 30 years of operation with a discount rate of 0% (i.e., no discounting)
** assumes 30 years of operation with a discount rate of 3%
-------�
FIGURES
-------�
Figure 2-1. Treatment Process as Designed
Organic Treatment
Train #1
400 gpm Max.
H202 }
Addition 1
1
FeCl3 Addition
1
pH Adjustment
with NaOH
1
Coagulation
1
1
Flocculation
1
_
1
Flotation
I
NaOH and 1
KMnO4 Addition
Organic Treatment Inorganic
Train #2 Treatment Train
400 gpm Max. 1,400 gpm Max.
H202 1 ( H202 1
Addition Addition
t J V J
1 1
FeCl3 Addition FeCl3 Addition
1 1
pH Adjustment pH Adjustment
with NaOH with NaOH
^ J V J
1 1
Coagulation Coagulation
1 1
1C }
Polymer and
KMnO4 Addition
V J
1 1
Flocculation Flocculation
1 1
Dissolved Air L^J Dissolved Air L^H
Flotation 1 Flotation 1
I I
1^1
NaOH and
KMnO4 Addition
V, J
±
T
Sand Filtration
1
Surface Water
Discharge
I 1
Dewatering via
Centnfuge
1
| Off-site Solids
1 Disposal
-------�
Figure 2-2. Treatment plant as currently operated
Equalization
Tank
H202
Addition
FeCl3 Addition
pH Adjustment
withNaOH
Coagulation
Polymer Addition
Flocculation
Dissolved Air
Flotation
Sand Filtration
Surface Water
Discharge
\
Flow by
gravity
Solids
Solids Thickening
Solids
Dewatering via
Centrifuge
All treatment conducted with inorganic
train (1,400 gpm max. capacity).
Organic and inorganic streams are
blended in equalization tank System
operated at approximately 800 gpm.
Pumped
Filter backwash
Thickener overflow
Centrate
Pumped to
next stage
Off-site Solids
Disposal
-------�
~JJ Blackwater Branch
Diverted
Blackwater Branch
60,22 \ **f>-12 /C*3^ \\
! MMMS&j j f9 60.58 \ \ \
?*"*=[* I
---..>=..'
Natural channel is dry.
Shallow Water Elevations (ft)1
April 19, 2010
68.0
Gro^fndwater
eatment
Plant
J5S.O
Values without an asterisk = 2003 survey
' 56.0 Values with an asterisk = 2010 survey
EW16S
66.76
-------�
-------�
N
Skating
Rink
MW54
WW24
Approximate location of reinjection/recharge
(Potentially with chemical addition)
Continued extraction
WW27
VVW251
I
B ackwater Branch
Wheat Rd.
RW09
I
MW42
* MW38 RW026
EW06 MW4B«B MW49
RW02b
MVV4
RW1
MW45
RW13
EW19
Ground water
Treatment
Plant
Soil
Washing
Plant
1000 Feet
EW16
Figure 6-1
Potential Distribution of Extraction,
Injection, and Chemical Addition
Vineland Chemical RSE
-------�
ATTACHMENT A
-------�
, ' ,.-,..,,.-: V
';t - M. ~r~^r~trr^
Vineland Chemical Company Site
;; / :',M' Kn»iin»ir. - V-
"i '*"
^ . -u- -p-
^.. .,.,fa-;)..:,"*
-' -
Figure 1
Site Location
Vineland Chemical Superfund Site
August 2009
-------�
Vineland Chemical Ground Water Elevations - August 1999 Pre-Pumping
Water Level
64.00
Blackwater Branch
-------�
N
Skating
Rink
Vineland Chemical Superfund Site
Recovery and Monitoring Well Locations
MW54
WW24
WW27
O Monitoring well
Extraction well
Operational 2000: RW01-RW13
Operational 2007: RW02a, RW02b, RW09a
VVW25 |
I
B ackwater Branch
MW53
MVV31
EW04
RW07
MW40
Wheat Rd.
RW09
I
MW42
EW21 I
RW10
* MW38 RW026
EW06 MW4B«B MW49
RW02b
RW09a
EW20 MW43
MW44
RW12"
MW45
RW13
EW19
Ground water
Treatment
Plant
Soil
Washing
Plant
Figure 4
Well Locations
Vineland Chemical Superfund Site
August 2009
1000 Feet
-------�
Skating
Rink
Vineland Chemical Superfund Site
Max. Total Arsenic Cone.
Shallow Monitoring Wells
2009
WW27
EW23
o
Shallow Contours (ppb) - 2009
10
A/50
100
1000
Surface Water (ppb)- 2009
A
A 9-50
50-100
A 100-1000
A 1000-10000
10000- 100000
Shallow well (ppb) - 2009
O ND
O 9-50
50-100
O 100-1000
O 1000-10000
10000- 100000
Area 5 Residual Contamination
20-50 mg/kg
50-100 mg/kg
100-250 mg/kg
250-500 mg/kg
500-1000 mg/kg
Extraction wells
Wells abandoned
EW15S- 600 ppb in 6/2002
M W36S - 4130 ppb in 3/2006
Figure 17
Shallow Arsenic Concentrations
Vineland Chemical Superfund Site
October 2009
-------�
Skating
Rink
o
N
Vineland Chemical Superfund Site
Max. Total Arsenic Cone.
Mid-Depth Monitoring Wells
2009
MW54
WW27
o
2b
O
EW17
o
1000
1000 Feet
Mid-Depth Contours (ppb) -2009
10
A/50
100
1000
Mid-Depth wells (ppb) -2009
O ND
Q 9-50
50 - 1 00
(~~) 100 -1000
Q 1000 - 10000
0 10000-100000
Area 5 Residual Contamination
PJyTl 20-50 mgflcg
50-1 00 mgJkg
100-250 mg/kg
250-500 mg/kg
500-1000 mg/kg
Extraction wells
Figure 19
Mid-Depth Arsenic Concentrations
Vineland Chemical Superfund Site
October 2009
-------�
GW Contours - Shallow Zone - January 21 2003
Posting GW Elevations
GW Elev. (ft NAVD) GW Elev. Contours (ft NAVD)
1QP D 100 200
SCALE IN FEET
-------�
GW Contours-Shallow Zone-January 21 2003
Total Arsenic Posting, ppb - Max 2002 - 2003
As (ppb) GW Elev. Contours (ft NAVD)
100 0 100 200
SCALE IN FEET
-------�
Skating
Rink
MW54
Vineland Chemical Superfund Site
Max. Total Arsenic Cone.
Shallow Monitoring Wells
2009-2010
WW
EW23
o
Capture zones
No sample from 2004-2009
EW15S - 600 ppb in 6/2002
1000
1000 Feet
Shallow Contours (ppb) - 2009
10
A/50
100
1000
Surface Water (ppb) - 2009
A ND
A 9-50
50-100
100- 1000
1000-10000
10000- 100000
Shallow well (ppb)- 2009
ND
9-50
50-100
100- 1000
1000- 10000
10000- 100000
Area 5 Residual Contamination
JJ3 20-50 mg/kg
50-100 mg/kg
100-250 mg/kg
250-500 mg/kg
500-1000 mg/kg
Extraction wells
Well
RW01
RW02
RW03
RW04
RW05
RW06
RW07
RW08
RW09
RW10
RW11
RW12
RW13
RW09a
RW02a
RW02b
Total
GPM
0
70
65
70
70
40
70
50
50
75
50
100
100
810
-------�
Skating
Rink
Vineland Chemical Superfund Site
Max. Total Arsenic Cone.
Mid-Depth Monitoring Wells
2009-2010
O
o
Mid-Depth Contours (ppk>) - 2009
10
A/50
100
1000
Mid-Depth wells (ppb) - 2009
O ND
f) 9 - 50
A 50-100
(~~) 100 -1000
f~\ 1000 - lOOt??118
A 10000 -100000
Area 5 R esidual C ontam ination
[£73 20-50 mg/kg
50-100 mg/kg
100-250 I
250-500 I
500-1 000 mg/kg
Extraction wells
Well
RW01
RW02
RW03
RW04
RW05
RW06
RW07
RW08
RW09
RW10
RW11
RW12
RW13
RW09a
RW02a
RW02b
Total
GPM
0
70
65
70
70
40
70
50
0
50
0
75
0
50
100
100
810
-------�
ATTACHMENT B
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
10
"Area 2 and 3
Vineland Chemical
Location: EW01D
'Area 1
Area 5
.RW09a, RW02a,
RW02b Drilled
UTJTJ"'
OU3
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Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
10
"Area 2 and 3
Vineland Chemical
Location: EW01M
'Area 1
Area 5
.RW09a, RW02a,
RW02b Drilled
UTJTJ"'
OU3
ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^o
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Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
o
'E
o>
1000 ---
100
Vineland Chemical
Location: EW04D
RW09a, RW02a,
RW02b Drilled
10 - ---
000-^000-^000-^000-^000-^000-^000-^000-^000-^000-^0
^^^O^^-^O-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vIO-^
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Time
o
Total Arsenic
-------�
Vineland Chemical
Location: EW04M
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a,
RW02b Drilled
100
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: EW04S
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a,
RW02b Drilled
100
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
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Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
10 --
/
ITT
"Area 2 and 3
Vineland Chemical
Location: EW05D
'Area 1
Area 5
.RW09a, RW02a,
RW02b Drilled
OU3
S
1t
"TJ
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Time
o
Total Arsenic
-------�
Vineland Chemical
Location: EW05M
100000
10000
Q.
Q.
O
'E
o>
1000
RW09a, RW02a,
RW02b Drilled
100
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
10
'Area 2 and 3
Vineland Chemical
Location: EW05S
'Area 1
Area 5
OU3
H
tr
,,RW09a, RW02a, _.
RW02b Drilled
oooooooooooooooooooooooooooooooooooooooo
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Time
o
Total Arsenic
-------�
Vineland Chemical
Location: EW06M
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a,
RW02b Drilled
100
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
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Time
o
Total Arsenic
-------�
Vineland Chemical
Location: EW06S
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a
RW02b Drilled
100 --
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: EW07D
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
10 --
RW09a, RW02a,
RW02b Drilled
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: EW07M
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a, _
RW02b Drilled
100
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: EW07S
100000
10000
Q.
Q.
O
'E
o>
1000
RW09a, RW02a,
RW02b Drilled
100
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Time
o
Total Arsenic
-------�
Vineland Chemical
Location: EW08M
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a
RW02b Drilled
100
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
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Time
o
Total Arsenic
-------�
Vineland Chemical
Location: EW08S
100000
10000
Q.
Q.
O
'E
o>
RW09a, RW02a,
RW02b Drilled
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: EW09D
IUUUUU -
innfifi -
IUUUU
Q mnn -
o I UUU
Q.
c
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rf 4 /\n
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3 C
9::
It..
I 1
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~C!/ O~~C-
^^^
riC
rv
L
30-^000-^000-^000-
^Area 1
Area 5
F
F
*W09a,
*W02b
S1
RWO
Drillec
-tOOO-^OOO-^OOO->
2a, __
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i
ou
3
|:::::
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».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
10 -
"Area 2 and 3
Vineland Chemical
Location: EW09M
'Area 1
Area 5
.RW09a, RW02a,
RW02b Drilled
"
OU3
S
1t
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Time
o
Total Arsenic
-------�
Vineland Chemical
Location: EW09S
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a
RW02b Drilled
100
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
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Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
10 --
"Area 2 and 3
Vineland Chemical
Location: EW10D
'Area 1
Area 5
.RW09a, RW02a,
RW02b Drilled
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S
1t
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Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 --
100 :--
Vineland Chemical
Location: EW10M
RW09a, RW02a
RW02b Drilled
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
10
'Area 2 and 3
Vineland Chemical
Location: EW10S
'Area 1
Area 5
OU3
H
tr
,,RW09a, RW02a, _.
RW02b Drilled
oooooooooooooooooooooooooooooooooooooooo
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Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000
100
Vineland Chemical
Location: EW11M
RW09a, RW02a
RW02b Drilled
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: EW11S
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a,
RW02b Drilled
100
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
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Time
o
Total Arsenic
-------�
Vineland Chemical
Location: EW12M
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
RW09a, RW02a,
RW02b Drilled
10 -
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: EW12S
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a,
RW02b Drilled
100
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: EW13M
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a,
RW02b Drilled
100
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: EW13S
100000
10000
Q.
Q.
O
'E
o>
1000 --
100
RW09a, RW02a,
RW02b Drilled
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: EW14M
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
10 -
"Area 2 and 3
'Area 1
Area 5
.RW09a, RW02a,
RW02b Drilled
fff
OU3
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
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Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
Vineland Chemical
Location: EW14S
"Area 2 and 3
'Area 1
Area 5
.RW09a, RW02a,
RW02b Drilled
OU3
10-
1 ............. T O"' ~---
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Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
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1000 ---
100
10 - THTr4-
Vineland Chemical
Location: EW15D
RW09a, RW02a,
RW02b Drilled
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Time
o
Total Arsenic
-------�
Vineland Chemical
Location: EW15M
100000
10000
Q.
Q.
O
'E
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1000 ---
100
RW09a, RW02a,
RW02b Drilled
10 - --*"-
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 --
100
Vineland Chemical
Location: EW15S
RW09a, RW02a,
RW02b Drilled
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
10 -
"Area 2 and 3
Vineland Chemical
Location: EW16M
'Area 1
Area 5
.RW09a, RW02a,
RW02b Drilled
OU3
S
1t
ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^o
^^^O^^-^O-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vIO-^
BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB
oooooooooooooooooooooooooooooooooooooooo^:
oooo-».-».-».-».i\ii\ii\ii\icocococo*».*».*».*».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
10 -
Vineland Chemical
Location: EW16S
RW09a, RW02a,
RW02b Drilled
ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^o
^^^O^^-^O-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vIO-^
BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB
oooooooooooooooooooooooooooooooooooooooo^:
oooo-».-».-».-».i\ii\ii\ii\icocococo*».*».*».*».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
O
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
"Area 2 and 3
Vineland Chemical
Location: EW17M
'Area 1
Area 5
.RW09a, RW02a,
RW02b Drilled
OU3
oooooooooooooooooooooooooooooooooooooooo:
oooo-».-».-».-».i\ii\ii\ii\icocococo*».*».*».*».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
Vineland Chemical
Location: EW17S
RW09a, RW02a,
RW02b Drilled
oooooooooooooooooooooooooooooooooooooooo:
oooo-».-».-».-».i\ii\ii\ii\icocococo*».*».*».*».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: EW18M
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
10 --
RW09a, RW02a
RW02b Drilled
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: EW18S
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
10 --
RW09a, RW02a
RW02b Drilled
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: EW19M
100000
10000
Q.
Q.
O
'E
o>
1000 --
RW09a, RW02a
RW02b Drilled
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: EW19S
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a
RW02b Drilled
100
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: EW20M
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a,
RW02b Drilled
100
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
100000
Q.
Q.
O
'E
a)
Vineland Chemical
Location: EW20S
uu -
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uu
nn
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IU
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0
±cc_: .: . .
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Area 2 and 3
_u_t_
r^\
1 \
N
"tJ-cn
r r
Area 1
Area 5
F
*W02b
RWO
Drillec
2a, __
L
OU
3
IEEEI
-H|.«
^ ""
ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^o
^^^O^^-^O-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vIO-^
BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB
oooooooooooooooooooooooooooooooooooooooo^:
oooo-».-».-».-».i\ii\ii\ii\icocococo*».*».*».*».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: EW21M
100000
10000
Q.
Q.
O
'E
o>
1000 -
RW09a, RW02a
RW02b Drilled
100
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
10 -
'Area 2 and 3
Vineland Chemical
Location: EW21S
'Area 1
4'"''"'u-rt-
Area 5
OU3
H
tr
,,RW09a, RW02a, _.
RW02b Drilled
'
ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^o
^^^O^^-^O-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vIO-^
BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB
oooooooooooooooooooooooooooooooooooooooo^:
oooo-».-».-».-».i\ii\ii\ii\icocococo*».*».*».*».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
10 -
"Area 2 and 3
Vineland Chemical
Location: EW22M
'Area 1
Area 5
.RW09a, RW02a,
RW02b Drilled
OU3
ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^o
^^^O^^-^O-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vIO-^
BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB
oooooooooooooooooooooooooooooooooooooooo^:
oooo-».-».-».-».i\ii\ii\ii\icocococo*».*».*».*».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
Vineland Chemical
Location: EW22S
RW09a, RW02a,
RW02b Drilled
ncr
10 -
ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^o
^^^O^^-^O-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vIO-^
BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB
oooooooooooooooooooooooooooooooooooooooo^:
oooo-».-».-».-».i\ii\ii\ii\icocococo*».*».*».*».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
10 - r4"J"J
"Area 2 and 3
Vineland Chemical
Location: EW23M
'Area 1
Area 5
.RW09a, RW02a,
RW02b Drilled
OU3
ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^o
^^^O^^-^O-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vIO-^
BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB
oooooooooooooooooooooooooooooooooooooooo^:
oooo-».-».-».-».i\ii\ii\ii\icocococo*».*».*».*».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
10 - -fr-lll--,
Vineland Chemical
Location: EW23S
RW09a, RW02a,
RW02b Drilled
ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^o
^^^O^^-^O-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vIO-^
BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB
oooooooooooooooooooooooooooooooooooooooo^:
oooo-».-».-».-».i\ii\ii\ii\icocococo*».*».*».*».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW28M
100000
10000 --
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a, _
RW02b Drilled
100
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW28S
100000
10000
Q.
Q.
O
'E
o>
1000 -
RW09a, RW02a
RW02b Drilled
100
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW29M
IUUUUU -
innfifi -
IUUUU
£ 1000 -
Q.
c
o>
e
< 100 -
1
-\
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. _|_ _. A
L 111 1 11 1 1 1 1 1 1
::
It[[[
It
If
1
1
gt
I
f
D-
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ITTTTT TT TT TT IT IT IT IT TT IT IT TT IT IT IT IT T
LJ
f
n
To
U"T "IU ° J U U"
Oy
K
M
^ooo-^ooo-^ooo-^ooo-^oo
I T "T T T ] ]
ea 5 ! !
,RW09a, RW02a,
RW02b Drilled
^^ ^r" ^^
O-^OOO-^OOO-^OOO-^OOO-^C
ooooooooooooooooooooooooooooooooooooooooc
oooooooooooooooooooooooooooooooooooooooo
».aia
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
Vineland Chemical
Location: MW29S
RW09a, RW02a
RW02b Drilled
000
000-^000
000-^000
000
000-^000
000-^000
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW30S
100000
10000
Q.
Q.
O
'E
o>
1000 - + +-X-
RW09a, RW02a,
RW02b Drilled
100
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
100000
10000 J~
Q.
Q.
O
'E
o>
1000 ---
100
Vineland Chemical
Location: MW31M
RW09a, RW02a, _
RW02b Drilled
oooooooooooooooooooooooooooooooooooooooo
oooo-».-».-».-».i\ii\ii\ii\icocococo*».*».*».*».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW31S
100000
10000
Q.
Q.
O
'E
o>
1000 -
RW09a, RW02a, _
RW02b Drilled
100
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW32M
IUUUUU -
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IUUUU
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1_
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71
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F
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Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW32S
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
RW09a, RW02a
RW02b Drilled
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW33M
IUUUUU 1 1 1 1 1 1 Area 2 and 3 ' '-" ' Area 1
1 nnnn - - - . . . - - -
£ 1 000 -
Q.
c
0)
rf 4 {\{\ __ 5i_ __. ___ ___ ___ ._. __. ___ ___ __. ___ ._. __. ___ ___ ._. .__ .__ __
-* TOO B*r ---)?
XJ -vJL/*\
*tC *D ^ -\
& ]jQQ J
HO O 3
N
1 n - . - -X-. r". .. .-- «/
-|U .. . .. ... . . .-..-. ^-. .__!._ -1 1
000-^000-^000-^000-^000-^
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Area 5 ! !
_ ,RW09a, RW02a,
RW02b Drilled
^^ ^r" ^^
1*" tam B^_ __ .-<-<< _^K __.-<-« _ _ _^_ _^K
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100000
10000
Q.
Q.
O
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1000 ---
100
10 ---
Vineland Chemical
Location: MW33S
RW09a, RW02a
RW02b Drilled
oooooooooooooooooooooooooooooooooooooooo
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Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
0>
1000 ---
100
"Area 2 and 3
Vineland Chemical
Location: MW34M
'Area 1
Area 5
.RW09a, RW02a,
RW02b Drilled
"Q"
OU3
ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^o
^^^O^^-^O-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vIO-^
BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB
oooooooooooooooooooooooooooooooooooooooo^:
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Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW34S
100000
10000
Q.
Q.
O
'E
o>
1000
RW09a, RW02a,
RW02b Drilled
100
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
10 - H
Vineland Chemical
Location: MW35M
RW09a, RW02a
RW02b Drilled
oooooooooooooooooooooooooooooooooooooooo:
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Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW35S
100000
10000
Q.
Q.
O
'E
o>
1000 L
100
10 --
RW09a, RW02a,
RW02b Drilled
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
10 -----*- +-
"Area 2 and 3
Vineland Chemical
Location: MW36M
"O
'Area 1
Area 5
.RW09a, RW02a,
RW02b Drilled
OU3
S
1t
ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^o
^^^O^^-^O-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vIO-^
BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB
oooooooooooooooooooooooooooooooooooooooo^:
oooo-».-».-».-».i\ii\ii\ii\icocococo*».*».*».*».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW36S
100000
10000
Q.
Q.
O
'E
o>
1000 --
RW09a, RW02a,
RW02b Drilled
100
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100 --
Area 2 and 3
10- tof-rcri~-iii
Vineland Chemical
Location: MW37M
'Area 1
Area 5
.RW09a, RW02a,
RW02b Drilled
OU3
S
1t
ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^o
^^^O^^-^O-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vIO-^
BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB
oooooooooooooooooooooooooooooooooooooooo^:
oooo-».-».-».-».i\ii\ii\ii\icocococo*».*».*».*».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
10
"Area 2 and 3
Vineland Chemical
Location: MW37S
'Area 1
Area 5
.RW09a, RW02a,
RW02b Drilled
OU3
S
1t
ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^o
^^^O^^-^O-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vIO-^
BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB
oooooooooooooooooooooooooooooooooooooooo^:
oooo-».-».-».-».i\ii\ii\ii\icocococo*».*».*».*».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW38M
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a
RW02b Drilled
100
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW38S
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a
RW02b Drilled
100 - -hT~
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
100000
Vineland Chemical
Location: MW39M
RW09a, RW02a
RW02b Drilled
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW39S
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a,
RW02b Drilled
100
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
10
'Area 2 and 3
7
Vineland Chemical
Location: MW40M
'Area 1
Area 5
,,RW09a, RW02a, _.
RW02b Drilled
OU3
ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^o
^^^O^^-^O-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vIO-^
BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB
oooooooooooooooooooooooooooooooooooooooo^:
oooo-».-».-».-».i\ii\ii\ii\icocococo*».*».*».*».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW40S
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a, _
RW02b Drilled
100
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW41M
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a
RW02b Drilled
100
000
000-^000
000-^000
000
000-^000
000-^000
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
10
CCKKC i Tm
'Area 2 and 3
Vineland Chemical
Location: MW41S
'Area 1
Area 5
,,RW09a, RW02a, _.
RW02b Drilled
tr
OU3
n-
ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^o
^^^O^^-^O-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vIO-^
BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB
oooooooooooooooooooooooooooooooooooooooo^:
oooo-».-».-».-».i\ii\ii\ii\icocococo*».*».*».*».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100 ---
Vineland Chemical
Location: MW42M
RW09a, RW02a
RW02b Drilled
oooooooooooooooooooooooooooooooooooooooo:
oooo-».-».-».-».i\ii\ii\ii\icocococo*».*».*».*».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW42S
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
10 --
RW09a, RW02a
RW02b Drilled
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
10 --
Vineland Chemical
Location: MW43M
RW09a, RW02a, _
RW02b Drilled
oooooooooooooooooooooooooooooooooooooooo
oooo-».-».-».-».i\ii\ii\ii\icocococo*».*».*».*».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW43S
IUUUUU -
innfifi -
IUUUU
Q mnn -
o I UUU
Q.
c
0)
rf 4 /\n
^ nuu
in -
nu
k
1_
w
1
f
,
V
0
/
/
r
j_L_J_-
Area 2 and 3
-crcr
^^^m
U
TIP "T
ft
...
._.
ooo-^ooo-^ooo-^ooo-
^Area 1
J.
"C
I""*"
1
...
Area 5
._.
F
F
*W09a,
RW02b
T-L-
RWO
Drillec
-^OOO-^OOO-^OOO->
2a, __
^m ^^m
._.
T
ou
...
3
|:::::
-TCT---
-i- -r- -r-
OOO-^OOO-^OOO-^G
ooooooooooooooooooooooooooooooooooooooooa
oooooooooooooooooooooooooooooooooooooooo:
».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW44M
IUUUUU -
innfifi ---
o 1 UUU
Q.
c
0)
rf 4 nn
in -
nu
IT
o
..
0
. L__L_
Area 2 and 3
-crcr
^^^m
U
TIP "T
FSSSS
...
._.
ooo-^ooo-^ooo-^ooo-
^Area 1
L
"C
r"*"
l
...
Area 5
._.
F
F
*W09a,
*W02b
T-L-
RWO
Drillec
-^ooo-^ooo-^ooo->
2a, __
^H ^^H
._.
T
ou
...
3
|:::::
-TCT---
-i- -r- -r-
OOO-^OOO-tOOO-^G
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo:
».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW44S
IUUUUU -
innfifi -
IUUUU
Q mnn -
o I UUU
Q.
c
0)
rf 4 /\n
^ nuu
in -
nu
1_
...
v-/
cr
. L-J--
Area 2 and 3
T_7\J
^^^m
U
TIP "T
ft
...
._.
ooo-^ooo-^ooo-^ooo-
^Area 1
J.
"C
I""*"
1
...
Area 5
._.
F
F
*W09a,
RW02b
T-L-
RWO
Drillec
-^OOO-^OOO-^OOO->
2a, __
^m ^^m
._.
T
ou
...
3
|:::::
-TCT---
-i- -r- -r-
OOO-^OOO-^OOO-^G
ooooooooooooooooooooooooooooooooooooooooa
oooooooooooooooooooooooooooooooooooooooo:
».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 --
100
Vineland Chemical
Location: MW45M
RW09a, RW02a,
RW02b Drilled
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100 ---
Vineland Chemical
Location: MW45S
RW09a, RW02a
RW02b Drilled
oooooooooooooooooooooooooooooooooooooooo:
oooo-».-».-».-».i\ii\ii\ii\icocococo*».*».*».*».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW46M
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
RW09a, RW02a
RW02b Drilled
10 -
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW46S
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a
RW02b Drilled
100
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100 - -
10 -----
Vineland Chemical
Location: MW47M
RW09a, RW02a
RW02b Drilled
000
000-^000
000-^000
000
000-^000
000-^000
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
'Area 2 and 3
Vineland Chemical
Location: MW47S
'Area 1
Area 5
:==::
,,RW09a, RW02a,
RW02b Drilled
OU3
'
000-^000-^000-^000-^000-^000-^000-^000-^000-^000-^0
^^^O^^-^O-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vIO-^
BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB
oooooooooooooooooooooooooooooooooooooooo^:
oooo-».-».-».-».i\ii\ii\ii\icocococo*».*».*».*».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW48M
100000
10000
Q.
Q.
O
'E
o>
RW09a, RW02a
RW02b Drilled
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW48S
100000
10000
Q.
Q.
O
'E
o>
1000
RW09a, RW02a,
RW02b Drilled
100
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW49M
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a
RW02b Drilled
100
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW49S
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a,
RW02b Drilled
100
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW50M
100000
10000
Q.
Q.
O
'E
0>
1000 ---
100
"Area 2 and 3
(J
'Area 1
Area 5
.RW09a, RW02a,
RW02b Drilled
OU3
s
1t
000-^000-^000-^000-^000-^000-^000-^000-^000-^000-^0
^^^O^^-^O-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vIO-^
BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB
oooooooooooooooooooooooooooooooooooooooo^:
oooo-».-».-».-».i\ii\ii\ii\icocococo*».*».*».*».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
10
"Area 2 and 3
Vineland Chemical
Location: MW50S
'Area 1
Area 5
.RW09a, RW02a,
RW02b Drilled
OU3
S
1t
ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^o
^^^O^^-^O-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vIO-^
BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB
oooooooooooooooooooooooooooooooooooooooo^:
oooo-».-».-».-».i\ii\ii\ii\icocococo*».*».*».*».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW51D
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a,
RW02b Drilled
100
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW51M
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a,
RW02b Drilled
100
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW51S
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a,
RW02b Drilled
100
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW52M
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a
RW02b Drilled
100
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
10
"Area 2 and 3
Vineland Chemical
Location: MW52S
'Area 1
Area 5
.RW09a, RW02a,
RW02b Drilled
OU3
S
1t
ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^o
^^^O^^-^O-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vIO-^
BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB
oooooooooooooooooooooooooooooooooooooooo^:
oooo-».-».-».-».i\ii\ii\ii\icocococo*».*».*».*».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW53M
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a,
RW02b Drilled
100
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
Vineland Chemical
Location: MW53S
RW09a, RW02a,
RW02b Drilled
000-^000-^000-^000-^000-^000-^000-^000-^000-^000-^0
^^^O^^-^O-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vIO-^
BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB
oooooooooooooooooooooooooooooooooooooooo^:
oooo-».-».-».-».i\ii\ii\ii\icocococo*».*».*».*».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
10
"Area 2 and 3
Vineland Chemical
Location: MW54D
'Area 1
Area 5
.RW09a, RW02a,
RW02b Drilled
OU3
ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^o
^^^O^^-^O-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vIO-^
BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB
oooooooooooooooooooooooooooooooooooooooo^:
oooo-».-».-».-».i\ii\ii\ii\icocococo*».*».*».*».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW54M
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a
RW02b Drilled
100
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: MW54S
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a
RW02b Drilled
100
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: PE
100000
10000
Q.
Q.
O
'E
o>
1000 --
RW09a, RW02a
RW02b Drilled
100 ---
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: RW01
100000
10000
Q.
Q.
O
'E
o>
1000 1
RW09a, RW02a, _
RW02b Drilled
100 ---
000
000-^000
000-^000
000
000-^000
000-^000
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100 ---
Vineland Chemical
Location: RW02
RW09a, RW02a, _
RW02b Drilled
fflfc
000-^000-^000-^000-^000-^000-^000-^000-^000-^000-^0
-t^^O-t^^O-t^^O-t^->JO-t«k-vlO-t«k-vlO-t«k-vlO-t«k-vlO-t«k-vlO-t«k-vlO-t
BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB
oooooooooooooooooooooooooooooooooooooooo^:
oooo-».-».-».-».i\ii\ii\ii\icocococo*».*».*».*».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: RW02A
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a, _
RW02b Drilled
100
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: RW02B
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a, _
RW02b Drilled
100
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: RW03
100000
10000
Q.
Q.
O
'E
o>
1000 eg- -,-? --
RW09a, RW02a, _
RW02b Drilled
100 ---
000-^000-^000-^000-^000-^000-^000-^000-^000-^000-^0
^^^O^^-^O-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vIO-^
BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB
oooooooooooooooooooooooooooooooooooooooo^:
oooo-».-».-».-».i\ii\ii\ii\icocococo*».*».*».*».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: RW04
100000
,RW09a, RW02a, _
RW02b Drilled
**- ^>jiowoju
000
000-^000
000-^000
000
000-^000
000-^000
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: RW05
100000
10000
Q.
Q.
O
'E
o>
1000
100
10 ---
RW09a, RW02a, _
RW02b Drilled
ooo-*ooo
ooo-*ooo
ooo-*ooo
ooo-*ooo
ooooooooooooooooooooooooooooooooooooooooo
0000000000000000000000000000000000000000
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: RW06
100000
10000 ---
Q.
Q.
O
'E
o>
1000 -
,RW09a, RW02a, _
RW02b Drilled
100
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: RW07
100000
10000
Q.
Q.
O
'E
o>
1000 ---
,RW09a, RW02a, _
RW02b Drilled
100
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: RW08
100000
10000 ---
Q.
Q.
O
'E
o>
1000 - x +
RW09a, RW02a, _
RW02b Drilled
100
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100 ---
10 ---
Vineland Chemical
Location: RW09
RW09a, RW02a, _
RW02b Drilled
000-^000-^000-^000-^000-^000-^000-^000-^000-^000-^0
-t^^O-t^^O-t^^O-t^->JO-t«k-vlO-t«k-vlO-t«k-vlO-t«k-vlO-t«k-vlO-t«k-vlO-t
BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB
oooooooooooooooooooooooooooooooooooooooo^:
oooo-».-».-».-».i\ii\ii\ii\icocococo*».*».*».*».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: RW09A
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a
RW02b Drilled
100
000
000-^000
000-^000
000
000-^000
000-^000
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: RW10
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a, _
RW02b Drilled
100 --
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ----
100
Vineland Chemical
Location: RW11
,RW09a, RW02a, _
RW02b Drilled
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: RW12
100000
10000
Q.
Q.
O
'E
o>
1000 -,= -
,RW09a, RW02a, _
RW02b Drilled
100 ---
000
000-^000
000-^000
000
000-^000
000-^000
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
100000
10000 -
Q.
Q.
O
'E
o>
1000 --
100 ---
Vineland Chemical
Location: RW13
RW09a, RW02a, _
RW02b Drilled
ooo
ooo-*ooo
ooo-*ooo
ooo
ooo-*ooo
ooo-*ooo
ooooooooooooooooooooooooooooooooooooooooo
0000000000000000000000000000000000000000^
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
10 -
Vineland Chemical
Location: WW24M
"Area 2 and 3
'Area 1
Area 5
.RW09a, RW02a,
RW02b Drilled
OU3
S
1t
oooooooooooooooooooooooooooooooooooooooo:
oooo-».-».-».-».i\ii\ii\ii\icocococo*».*».*».*».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: WW24S
100000
10000
Q.
Q.
O
'E
o>
1000
RW09a, RW02a,
RW02b Drilled
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: WW25M
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a, _
RW02b Drilled
100
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: WW25S
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a
RW02b Drilled
100 --
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: WW26M
100000
10000
Q.
Q.
O
'E
o>
1000 ---
RW09a, RW02a,
RW02b Drilled
100
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
10 - .......
"-":r:r"a
"Area 2 and 3
Vineland Chemical
Location: WW26S
'Area 1
Area 5
.RW09a, RW02a,
RW02b Drilled
OU3
ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^ooo-^o
^^^O^^-^O-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vIO-^
BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB
oooooooooooooooooooooooooooooooooooooooo^:
oooo-».-».-».-».i\ii\ii\ii\icocococo*».*».*».*».aiaiaiaio>o>o>o>-^i-^i-^i-^ioooooooo<£><£><£><£>o
Time
o
Total Arsenic
-------�
Vineland Chemical
Location: WW27M
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
RW09a, RW02a,
RW02b Drilled
10 - r-u"u-
000-^000
000-^000
000
000
000
000-^000-^000-^0
ooooooooooooooooooooooooooooooooooooooooo
oooooooooooooooooooooooooooooooooooooooo^:
Time
o
Total Arsenic
-------�
100000
10000
Q.
Q.
O
'E
o>
1000 ---
100
10 --
Vineland Chemical
Location: WW27S
RW09a, RW02a,
RW02b Drilled
___. ___________ ._________.-
000-^000-^000-^000-^000-^000-^000-^000-^000-^000-^0
^^^O^^-^O-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vlO-^^-vIO-^
BBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBBB
oooooooooooooooooooooooooooooooooooooooo^:
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Time
o
Total Arsenic
-------�
ATTACHMENT C
-------�
Total As ppb Total As ppb
1350.0
j 300.0
J 250.0
H 200.0
J1500
j 100.0
I 50.0
'o.o
I
/
3100
7400
6700
6000
5300
4600
3900
3200
2500
1300
1100
400
Flooded Contours
Scatter Points
Figure 1
GW Contours - Shallow Zone - January 21 2003
Total Arsenic Plume > 350 ppb
Max 2002 - 2003
-------�
Figure 2
GW Contours-Shallow Zone-January 21 2003
Total Arsenic Plume > 350 ppb
Max 2008 - 2009
Scatter Points
-------�
Total As ppb Total As ppb
1350.0
Figure 3
GW Contours - Middle Zone - January 21 2003
Total Arsenic Plume > 350 ppb
Max 2002 - 2003
Flooded Contours
Scatter Points
-------�
Total AS ppb Total AS ppb
1350.0
Figure 4
GW Contours - Middle Zone -January 21 2003
Total Arsenic Plume > 350 ppb
Max 2008 - 2009
Scatter Points
100 p 10Q 200
SCALE IN FEET
r77~
* . .
-------�
ATTACHMENT D
-------�
RW02
10,000
5,000
1,000
500
100
36,000
36,600
37,200
37,800
38,400
39,000
Time(d)
39,600
200
40,800
41,400
42,000
log(y) = C(0) + C(l)*x + C(2)*x**2 -
(log)) = common logarithm)
Coefficients
C(00) 13.474690
C(01) -0.26891789E-03
ln(y) = D(0)+D(l)*x+D(2)*x*
(ln() = natural logarithm)
Coefficients
D(00) 31.026621
D(01) -0.61920633E-03
Time to reach 0.35 mg/l = 1 year
Time to reach 0.05 mg/l = 9 years
Time to reach 0.01 mg/l = 16 years
Correlation coefficient is 0.91655122
Correlation coefficient is 0.91655122
-------�
RW02a
5,000
0)
1,000
500
100
38,100
38,400
38,700
39,000
39,300
39,600
Time(d)
39,900
40,200
40,500
40,800
41,100
log(y) = C(0) + C(l)*x + C(2)*x**2 -
(log)) = common logarithm)
Coefficients
C(00) 30.385174
C(01) -0.68982716E-03
ln(y) = D(0) + D(l)*x + D(2)*x**2 -
(ln() = natural logarithm)
Coefficients
D(00) 69.964449
D(01) -0.15883857E-02
Time to reach 0.35 mg/l = < 1 year
Time to reach 0.05 mg/l = 3 years
Time to reach 0.01 mg/l = 6 years
Correlation coefficient is 0.93670640
Correlation coefficient is 0.93670640
-------�
RW02b
,000
100
37,000
37,500 38,000 38,500 39,000 39,500 40,000
Time (d)
40,500
41,000
41,500
42,000
log(y) = C(0) + C(l)*x + C(2)*x**2 -
(log)) = common logarithm)
Coefficients
C(00) 7.3380374
C(01) -0.10541420E-03
ln(y) = D(0) + D(l)*x + D(2)*x**2 -
(ln() = natural logarithm)
Coefficients
D(00) 16.896455
D(01) -0.24272516E-03
Time to reach 0.35 mg/l = 14 years
Time to reach 0.05 mg/l = 36 years
Time to reach 0.01 mg/l = 54 years
Correlation coefficient is 0.19858113
Correlation coefficient is 0.19858113
-------�
RW03
1,000
500
O)
1
100
36,000
36,600
37,200
37,800
38,400
39,000
Date (d)
39,600
40,200
40,800
41,400
42,000
log(y) = C(0) + C(l)*x + C(2)*x**2 + .
(log)) = common logarithm)
Coefficients
C(00) 6.844025
C(01) -0.10725365E-03
ln(y) = D(0) + D(l)*x + D(2)*x**2
(ln() = natural logarithm)
Coefficients
D(00) 15.759819
D(01) -0.24696067E-03
Time to reach 0.35 mg/l = < 1 year
Time to reach 0.05 mg/l = 21 years
Time to reach 0.01 mg/l = 39 years
Correlation coefficient is 0.37123800
Correlation coefficient is 0.37123800
-------�
RW04
,000
ot
36,800 37,200 37,600 38,000 38,400 38,800
Time(d)
39,200
39,600
40,000
40,400
log(y) = C(0) + C(l)*x + C(2)*x**2 -
(log)) = common logarithm)
Coefficients
C(00) 12.772188
C(01) -0.24690496E-03
ln(y) = D(0) + D(l)*x + D(2)*x**2 -
(ln() = natural logarithm)
Coefficients
D(00) 29.409050
D(01) -0.56851967E-03
Time to reach 0.35 mg/l = 3 years
Time to reach 0.05 mg/l = 12 years
Time to reach 0.01 mg/l = 20 years
Correlation coefficient is 0.73231222
Correlation coefficient is 0.73231222
-------�
RW05
2,000
1,000
I/I
<
1
500
200
37,200
37,500 37,800 38,100 38,400 38,700 39,000
Date(d)
39,300
39,600
39,900
40,200
40,500
log(y) = C(0) + C(l)*x + C(2)*x**2 -
(log)) = common logarithm)
Coefficients
C(00) 7.9582482
C(01) -0.13429409E-03
ln(y) = D(0) + D(l)*x + D(2)*x**2 -
(ln() = natural logarithm)
Coefficients
D(00) 18.324544
D(01) -0.30922357E-03
Time to reach 0.35 mg/l = N/A
Time to reach 0.05 mg/l = 17 years
Time to reach 0.01 mg/l = 31 years
Correlation coefficient is 0.63003592
Correlation coefficient is 0.73231222
-------�
RW06
10,000
5,000
1,000
500
200
37,200
1st Order Curve Fit
37,600
38,000
38,400
38,800
Date (d)
39,200
39,600
40,000
40,400
log(y) = C(0) + C(l)*x + C(2)*x**2
(log)) = common logarithm)
Coefficients
C(00) 5.7046108
C(01) -0.66480640E-03
ln(y) = D(0) + D(l)*x + D(2)*x**2 -
(ln() = natural logarithm)
Coefficients
D(00) 13.135352
D(01) -0.15307733E-03
Time to reach 0.35 mg/l = 20 years
Time to reach 0.05 mg/l = 54 years
Time to reach 0.01 mg/l = 83 years
Correlation coefficient is 0.26776477
Correlation coefficient is 0.26776477
-------�
RW07
10,000
5,000
O)
2
o
1,000
500
200
37,200
37,600
38,000
38,400
38,800
Date (d)
39,200
39,600
40,000
40,400
log(y) = C(0) + C(l)*x + C(2)*x**2
(log)) = common logarithm)
Coefficients
C(00) 6.1601763
C(01) -0.80358367E-04
ln(y) = D(0) + D(l)*x + D(2)*x**2 -
(ln() = natural logarithm)
Coefficients
D(00) 14.184330
D(01) -0.18503198E-03
Time to reach 0.35 mg/l = 13 years
Time to reach 0.05 mg/l = 41 years
Time to reach 0.01 mg/l = 65 years
Correlation coefficient is 0.40470106
Correlation coefficient is 0.40470106
-------�
RW08
5,000
= 1,000
ra
in
re
*r
500
100
37,200
37,500
37,800
38,100 38,400
38,700 39,000
Date (d)
39,300
39,600
39,900
40,200
40,500
log(y) = C(0) + C(l)*x + C(2)*x**2 -
(log)) = common logarithm)
Coefficients
C(00) 8.2402746
C(01) -0.13609750E-03
ln(y) = D(0) + D(l)*x + D(2)*x**2 -
(ln() = natural logarithm)
Coefficients
D(00) 18.973933
D(01) -0.31337607E-03
Time to reach 0.35 mg/l = 4 years
Time to reach 0.05 mg/l = 21 years
Time to reach 0.01 mg/l = 35 years
Correlation coefficient is 0.59266
Correlation coefficient is 0.59266
-------�
RW10
20,000
10,000
1,000
100
36,400
36,800 37,200 37,600 38,000 38,400 38,800
Date (d)
39,200
39,600
40,000
40,400
log(y) = C(0) + C(l)*x + C(2)*x**2 -
(log)) = common logarithm)
Coefficients
C(00) 8.8804672
C(01) -0.16243981-03
ln(y) = D(0) + D(l)*x + D(2)*x**2 -
(ln() = natural logarithm)
Coefficients
D(00) 20.448031
D(01) -0.37403148E-03
Time to reach 0.35 mg/l = N/A
Time to reach 0.05 mg/l = 11 years
Time to reach 0.01 mg/l = 22 years
Correlation coefficient is 0.48904069
Correlation coefficient is 0.48904069
-------�
RW12
1,000
500
1
39,150
39,300
39,450
39,600
39,750
Date (d)
39,900
40,050
40,200
40,350
log(y) = C(0) + C(l)*x + C(2)*x**2 + .
(log)) = common logarithm)
Coefficients
C(00) 3.2244755
C(01) -0.25393429-04
ln(y) = D(0) + D(l)*x + D(2)*x**2 -
(ln() = natural logarithm)
Coefficients
D(00) 7.4246291
D(01) -0.58470530E-04
Time to reach 0.35 mg/l = N/A
Time to reach 0.05 mg/l = 54 years
Time to reach 0.01 mg/l = 129 years
Correlation coefficient is 0.26809553E-01
Correlation coefficient is 0.26809553E-01
-------�
ATTACHMENT E
-------�
Total As vs Dissolved As (ppb)
T
0
t
a
1
P
A P
r b
s
e
n
i
c
80 -
70 -
60 -
50
40 -
30
20
^
^
10 J *
l*k
n &
U ^F i |
0 10 20 30 40 50
Dissolved As ppb
1000
s
o
i
iioo
10
1 -I
5000
10000 15000
Soil Iron Concentration mg?kg
20000
25000
-------�
ATTACHMENT F
-------�
Table 1
MAROS Statistical Trend Analysis Summary
Project: Vineland Superfund Shallow
Location: Vineland
User Name: Dave Becker
State: New Jersey
Time Period: 5/1/2000 to 9/15/2009
Consolidation Period: No Time Consolidation
Consolidation Type: Median
Duplicate Consolidation: Maximum
ND Values: 1/2 Detection Limit
J Flag Values : Actual Value
Well
Source/
Tail
Number Number
of of
Samples Detects
Average Median
Cone. Cone.
(mg/L) (mg/L)
All
Samples
"ND" ?
Mann-
Kendall
Trend
Linear
Regression
Trend
ARSENIC
EW04S
EW05S
EW06S
EW07S
EW08S
EW09S
EW10S
EW11S
EW12S
EW13S
EW14S
EW15S
EW16S
EW17S
EW18S
EW19S
EW20S
EW21S
EW22S
EW23S
MW28S
MW29S
MW30S
MW31S
MW32S
MW33S
MW34S
MW35S
MW36S
MW37S
MW38S
MW39S
MW40S
MW41S
MW42S
T
T
T
S
S
T
T
T
T
T
T
T
T
T
T
T
T
T
T
T
S
T
T
T
T
T
S
S
T
S
S
T
T
T
T
13
1
13
13
13
11
1
13
11
11
13
8
11
14
13
14
10
13
15
11
16
16
12
15
14
15
13
13
7
5
12
12
16
13
11
13
1
13
13
13
5
1
13
2
11
3
8
2
1
5
12
3
5
2
1
16
16
12
14
12
12
13
12
6
5
12
12
13
2
5
1.4E+00
2.8E-02
1.3E-01
1 .6E+00
3.2E+00
7.0E-03
4.0E-03
2.1E-01
4.2E-03
1 .5E+00
5.4E-03
7.4E-01
4.2E-03
3.9E-03
8.8E-03
6.5E-02
1.1E-02
9.5E-03
4.2E-03
3.7E-03
2.4E+00
4.5E-02
1 .8E+00
2.2E-01
1.8E-02
2.1E-02
1 .4E+00
1 .9E+00
1 .6E+00
1.7E+01
1.7E-01
2.7E+00
6.8E-02
5.4E-03
6.2E-03
1.3E+00
2.8E-02
9.9E-02
9.0E-01
2.6E+00
4.5E-03
4.0E-03
1.7E-01
4.5E-03
1.1E+00
4.5E-03
4.9E-01
4.5E-03
4.5E-03
4.5E-03
4.1E-02
4.5E-03
4.5E-03
4.5E-03
4.5E-03
1.4E+00
2.7E-02
1.8E+00
3.8E-02
1 .4E-02
1 .3E-02
1.3E+00
6.4E-01
1.4E+00
2.0E+01
1.3E-01
2.7E+00
2.2E-02
4.5E-03
4.5E-03
No
No
No
No
No
No
No
No
No
No
No
No
No
No
No
No
No
No
No
No
No
No
No
No
No
No
No
No
No
No
No
No
No
No
No
S
N/A
NT
I
I
NT
N/A
S
S
I
NT
NT
NT
S
D
NT
NT
PD
S
S
I
NT
NT
NT
NT
I
NT
I
NT
S
PI
S
I
PD
NT
NT
N/A
NT
I
I
NT
N/A
NT
NT
NT
NT
PD
NT
NT
D
NT
NT
NT
NT
NT
I
NT
NT
NT
S
I
I
I
NT
D
I
S
I
S
NT
MAROS Version 2.2, 2006, AFCEE
Friday, July 16, 2010
Page 1 of 2
-------�
MAROS Statistical Trend Analysis Summary
Well
Source/
Tail
Number
of
Samples
Number
of
Detects
Average
Cone.
(mg/L)
Median
Cone.
(mg/L)
All
Samples
"ND" ?
Mann-
Kendall
Trend
Linear
Regression
Trend
ARSENIC
MW43S
MW44S
MW45S
MW46S
MW47S
MW48S
MW49S
MW50S
MW51S
MW52S
MW53S
MW54S
WW24S
WW25S
WW26S
WW27S
T
T
T
T
T
T
T
S
T
T
T
T
T
T
T
T
10
10
12
11
13
4
4
4
5
4
4
5
12
13
17
14
1
1
12
8
g
4
4
4
2
4
2
5
12
13
1
2
4.3E-03
4.6E-03
7.8E-02
1.2E-02
1.6E-02
8.9E-01
2.3E+00
1.2E+01
4.3E-03
1.1E+00
1.0E-02
7.3E-01
4.3E-01
1.2E-01
4.2E-03
3.9E-03
4.5E-03
4.5E-03
3.7E-02
9.6E-03
1.0E-02
9.4E-01
2.5E+00
7.7E+00
4.5E-03
1.2E+00
8.8E-03
2.4E-01
3.2E-01
1.1E-01
4.5E-03
4.5E-03
No
No
No
No
No
No
No
No
No
No
No
No
No
No
No
No
NT
S
D
NT
D
S
S
D
S
S
NT
NT
NT
PD
NT
S
NT
S
PD
NT
D
S
S
D
D
S
I
I
NT
PD
NT
NT
Note: Increasing (I); Probably Increasing (PI); Stable (S); Probably Decreasing (PD); Decreasing (D); No Trend (NT); Not Applicable
(N/A); Not Applicable (N/A) - Due to insufficient Data (< 4 sampling events); No Detectable Concentration (NDC)
The Number of Samples and Number of Detects shown above are post-consolidation values.
MAROS Version 2.2, 2006, AFCEE
Friday, July 16, 2010
Page 2 of 2
-------�
Table 2
MAROS Spatial Moment Analysis Summary
Project: Vineland Superfund Shallow
Location: Vineland
Oth Moment
Effective Date
Estimated
Mass (Kg)
1st Moment (Center of Mass)
Xc (ft)
Yc(ft)
Source
Distance (ft)
User Name: Dave Becker
State: New Jersey
2nd Moment (Spread)
Sigma XX
(sqft)
Sigma YY
(sqft)
Number of
Wells
ARSENIC
5/1/2000
8/1/2000
11/1/2000
2/1/2001
5/1/2001
8/1/2001
11/1/2001
2/1/2002
5/1/2002
8/1/2002
11/1/2002
5/1/2003
11/1/2003
2/1/2004
5/1/2004
11/1/2004
5/1/2005
11/1/2005
2/1/2006
5/1/2006
8/1/2006
2/1/2007
8/1/2007
11/1/2007
2/1/2008
11/1/2008
2/1/2009
9/15/2009
1.2E+02
4.7E+01
6.0E+01
4.1E+01
2.9E+01
9.8E+01
1.1E+02
7.1E+01
2.4E+01
3.6E+01
O.OE+00
2.6E+01
1.6E+01
4.3E+01
O.OE+00
6.1E+01
4.6E+01
4.0E+01
1.0E+02
3.8E+01
1.6E+02
5.2E+01
O.OE+00
4.8E+01
8.0E+00
O.OE+00
4.7E+01
2.1E+00
335,183
334,955
334,911
335,066
334,750
335,054
335,055
335,049
334,810
334,915
334,672
335,051
334,754
334,806
334,678
334,572
334,988
334,522
334,833
334,636
334,847
334,539
334,993
334,550
246,993
246,930
247,221
246,751
247,312
247,148
247,190
247,077
247,074
247,012
247,338
246,779
247,029
247,193
247,204
247,169
247,035
247,156
247,124
247,341
247,192
247,071
247,032
247,102
233
277
148
437
329
40
2
111
271
225
412
409
341
249
377
483
168
534
231
446
208
529
168
513
74,721
182,545
79,801
51,521
77,603
174,688
1 1 1 ,462
131,403
193,267
177,226
84,758
75,807
37,255
78,192
91,272
82,781
66,244
72,217
51,907
130,124
105,058
17,578
128,670
323,269
93,195
109,326
64,264
65,893
129,762
109,940
108,277
112,969
234,988
135,646
75,267
41,361
106,387
104,458
104,112
122,411
76,673
66,523
66,181
118,596
84,157
47,858
104,756
151,051
42
27
22
16
15
43
44
43
38
22
5
14
6
22
2
23
10
18
17
9
19
13
5
23
7
5
32
12
MAROS Version 2.2, 2006, AFCEE
Friday, July 16, 2010
Page 1 of 2
-------�
Project: Vineland Superfund Shallow
Location: Vineland
User Name: Dave Becker
State: New Jersey
Moment Type Constituent
Zeroth Moment: Mass
ARSENIC
1st Moment: Distance to Source
ARSENIC
2nd Moment: Sigma XX
ARSENIC
2nd Moment: Sigma YY
ARSENIC
Coefficient
of Variation
0.85
0.51
0.60
0.39
Mann-Kendall
S Statistic
-80
68
-14
-14
Confidence
in Trend
94.0%
95.2%
62.5%
62.5%
Moment
Trend
PD
I
S
S
Note: The following assumptions were applied for the calculation of the Zeroth Moment:
Porosity: 0.25 Saturated Thickness: Uniform: 20 ft
Mann-Kendall Trend test performed on all sample events for each constituent. Increasing (I); Probably Increasing (PI); Stable (S);
Probably Decreasing (PD); Decreasing (D); No Trend (NT); Not Applicable (N/A)-Due to insufficient Data (< 4 sampling events).
Note: The Sigma XX and Sigma YY components are estimated using the given field coordinate system and then rotated to align with the
estimated groundwater flow direction. Moments are not calculated for sample events with less than 6 wells.
MAROS Version 2.2, 2006, AFCEE
Friday, July 16, 2010
Page 2 of 2
-------�
Table 3
MAROS First Moment Analysis
Project: Vineland Superfund Shallow
Location: Vineland
User Name: Dave Becker
State: |\|ew Jersey
COC: ARSENIC
Change in Location of Center of Mass Over Time
247200
247100
246900
<
»
<
05
>
«
02
1
oa
4
1/05
^
4
3D
5/C
e
«
0!
0
m
21
1
14
«
0
V*
c
J/O
8/
2
16
^
1
C
/O
e/
4
0
)2
C
a/i
OB
DO
20)
4
4
B
4>
c
0
1
IJ
8/
2/0
/O
o:
1
2
3
/O
>
u5
IX
Groundwater
Flow Direction:
\
Source
Coordinate:
X:
335,055
Y: | 247,188
334400 334500 334600 334700 334800 334900 335000 335100 335200 335300
Effective Date Constituent
5/1/2000
8/1/2000
11/1/2000
2/1/2001
5/1/2001
8/1/2001
11/1/2001
2/1/2002
5/1/2002
8/1/2002
11/1/2002
5/1/2003
11/1/2003
2/1/2004
5/1/2004
11/1/2004
5/1/2005
11/1/2005
2/1/2006
5/1/2006
8/1/2006
2/1/2007
8/1/2007
11/1/2007
2/1/2008
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
Xc (ft)
Xc (ft)
335,183
334,955
334,911
335,066
334,750
335,054
335,055
335,049
334,810
334,915
334,672
335,051
334,754
334,806
334,678
334,572
334,988
334,522
334,833
334,636
334,847
334,539
Yc (ft) Distance from Source (ft)
246,993
246,930
247,221
246,751
247,312
247,148
247,190
247,077
247,074
247,012
247,338
246,779
247,029
247,193
247,204
247,169
247,035
247,156
247,124
247,341
247,192
247,071
233
277
148
437
329
40
2
111
271
225
412
409
341
249
377
483
168
534
231
446
208
529
Number of Wells
42
27
22
16
15
43
44
43
38
22
5
14
6
22
2
23
10
18
17
9
19
13
5
23
7
MAROS Version 2.2, 2006, AFCEE
7/16/2010
Page 1 of 2
-------�
MAROS First Moment Analysis
Effective Date Constituent
11/1/2008
2/1/2009
9/15/2009
ARSENIC
ARSENIC
ARSENIC
Xc (ft)
334,993
334,550
Yc(ft) Distance from Source (ft) Number of Wells
247,032
247,102
168
513
5
32
12
Note: Increasing (I); Probably Increasing (PI); Stable (S); Probably Decreasing (PD); Decreasing (D); No Trend (NT); Not Applicable (N/A) -
Due to insufficient Data (< 4 sampling events). Moments are not calculated for sample events with less than 6 wells.
MAROS Version 2.2, 2006, AFCEE
7/16/2010
Page 2 of 2
-------�
Table 4. Heuristic Analysis Results
MAROS Site Results
Project: Vineland Superfund Shallow
Location: Vineland
User Name: Dave Becker
State: New Jersey
User Defined Site and Data Assumptions:
Hydrogeology and Plume Information:
Groundwater
Seepage Velocity: 100 ft/yr
Current Plume Length: 1500ft
Current Plume Width 1200 ft
Number of Tail Wells: 43
Number of Source Wells: 8
Source Information:
Source Treatment: Excavation
NAPL is not observed at this site.
Down-gradient Information:
Distance from Edge of Tail to Nearest:
Down-gradient receptor: 1 ft
Down-gradient property: 1 ft
Distance from Source to Nearest:
Down-gradient receptor: 1500ft
Down-gradient property: 1500ft
Data Consolidation Assumptions:
Time Period: 5/1/2000 to 9/15/2009
Consolidation Period: No Time Consolidation
Consolidation Type: Median
Duplicate Consolidation: Maximum
ND Values: 1/2 Detection Limit
J Flag Values : Actual Value
Plume Information Weighting Assumptions:
Consolidation Step 1. Weight Plume Information by Chemical
Summary Weighting: Weighting Applied to All Chemicals Equally
Consolidation Step 2. Weight Well Information by Chemical
Well Weighting: No Weighting of Wells was Applied.
Chemical Weighting: No Weighting of Chemicals was Applied.
Note: These assumptions were made when consolidating the historical montoring data and lumping the Wells and COCs.
1. Compliance Monitoring/Remediation Optimization Results:
Preliminary Monitoring System Optimization Results: Based on site classification, source treatment and Monitoring System
Category the following suggestions are made for site Sampling Frequency, Duration of Sampling before reassessment, and
Well Density. These criteria take into consideration: Plume Stability, Type of Plume, and Groundwater Velocity.
coc
Tail
Stability
Source
Stability
Level of
Effort
Sampling
Duration
Sampling
Frequency
Sampling
Density
ARSENIC
PI M Remove treatment system if
previously reducing
concentration or PRG met.
No Recommendation
30
Note:
Plume Status: (I) Increasing; (Pl)Probably Increasing; (S) Stable; (NT) No Trend; (PD) Probably Decreasing; (D) Decreasing
Design Categories: (E) Extensive; (M) Moderate; (L) Limited (N/A) Not Applicable, Insufficient Data Available
Level of Monitoring Effort Indicated by Analysi Moderate
2. Spatial Moment Analysis Results:
MAROS Version 2.2, 2006, AFCEE
Friday, July 16, 2010
Page 1 of 2
-------�
Moment Type Constituent
Zeroth Moment: Mass
ARSENIC
1st Moment: Distance to Source
ARSENIC
2nd Moment: Sigma XX
ARSENIC
2nd Moment: Sigma YY
ARSENIC
Coefficient
of Variation
0.85
0.51
0.60
0.39
Mann-Kendall
S Statistic
-80
68
-14
-14
Confidence
in Trend
94.0%
95.2%
62.5%
62.5%
Moment
Trend
PD
I
S
S
Note: The following assumptions were applied for the calculation of the Zeroth Moment:
Porosity: 0.25
Saturated Thickness: Uniform: 20 ft
Mann-Kendall Trend test performed on all sample events for each constituent. Increasing (I); Probably Increasing (PI); Stable (S);
Probably Decreasing (PD); Decreasing (D); No Trend (NT); Not Applicable (N/A)-Due to insufficient Data (< 4 sampling events).
MAROS Version 2.2, 2006, AFCEE
Friday, July 16, 2010
Page 2 of 2
-------�
Table 5.
MAROS Sampling Frequency Optimization Results
Project: Vineland Superfund Shallow
Location: Vineland
User Name: Dave Becker
State: New Jersey
"Recent Period" defined by events: From Winter 2007
2/1/2007
"Rate of Change" parameters used:
To Fall 2009
9/15/2009
Constituent Cleanup Goal Low Rate Medium Rate High Rate
ARSENIC 0.05
Units: Cleanup Goal is in mg/L; all rate parameters are
Recommended
Well Sampling Frequency
0.025 0.05 0.1
in mg/L/year.
Frequency Based Frequency Based
on Recent Data on Overall Data
ARSENIC
EW04S Quarterly
EW06S Quarterly
EW07S Quarterly
EW08S Quarterly
EW09S Annual
EW1 1 S Quarterly
EW12S Annual
EW1 3S Quarterly
EW14S Annual
EW16S Annual
EW17S Annual
EW18S Annual
EW1 9S Quarterly
EW20S Annual
EW21S Annual
EW22S Annual
EW23S Annual
MW28S Quarterly
MW29S Annual
MW30S Quarterly
MW31S Annual
MW32S Annual
MW33S SemiAnnual
MW34S Quarterly
Quarterly Quarterly
Quarterly Quarterly
Quarterly Quarterly
Quarterly Quarterly
Annual
Annual
Quarterly Quarterly
Annual
Annual
Quarterly Quarterly
Annual
Annual
Annual
Annual
Annual
Annual
Annual
Annual
Quarterly Quarterly
Annual
Annual
Annual
Annual
Annual
Annual
Annual
Annual
Quarterly Quarterly
Annual
Annual
Quarterly Quarterly
Annual
Annual
Annual
Annual
SemiAnnual SemiAnnual
Quarterly Quarterly
MAROS Version 2.2, 2006, AFCEE
Friday, July 16,2010
Page 1 of 2
-------�
Project: Vineland Superfund Shallow
Location: Vineland
User Name: Dave Becker
State: New Jersey
Well
MW35S
MW38S
MW39S
MW40S
MW41S
MW42S
MW43S
MW44S
MW45S
MW46S
MW47S
MW51S
MW52S
MW53S
MW54S
VWV24S
VWV25S
VWV26S
VWV27S
Recommended
Sampling Frequency
Quarterly
Quarterly
Quarterly
Quarterly
Annual
Annual
Annual
Annual
SemiAnnual
Annual
Annual
Annual
Quarterly
Annual
Quarterly
Quarterly
SemiAnnual
Biennial
Annual
Frequency Based
on Recent Data
Quarterly
Quarterly
Quarterly
Quarterly
Annual
Annual
Annual
Annual
SemiAnnual
Annual
Annual
Annual
Quarterly
Annual
Quarterly
Quarterly
SemiAnnual
Annual
Annual
Frequency Based
on Overall Data
Quarterly
Quarterly
Quarterly
Quarterly
Annual
Annual
Annual
Annual
SemiAnnual
Annual
Annual
Annual
Quarterly
Annual
Quarterly
Quarterly
SemiAnnual
Annual
Annual
Note: Sampling frequency is determined considering both recent and overall concentration trends. Sampling Frequency is the
final recommendation; Frequency Based on Recent Data is the frequency determined using recent (short) period of monitoring
data; Frequency Based on Overall Data is the frequency determined using overall (long) period of monitoring data. If the "recent
period" is defined using a different series of sampling events, the results could be different.
MAROS Version 2.2, 2006, AFCEE
Friday, July 16,2010
Page 2 of 2
-------�
Table 6
^^MAROS Sampling Location Optimization^^^H
Results by Considering All COCs
Project:
Location
Sampling
Well
EW04S
EW06S
EW07S
EW08S
EW09S
EW11S
EW12S
EW13S
EW14S
EW16S
EW17S
EW18S
EW19S
EW22S
EW23S
MW28S
MW29S
MW30S
MW31S
MW32S
MW33S
MW34S
MW35S
MW38S
MW39S
MW40S
MW41S
MW42S
MW45S
MW46S
MW47S
MW51S
Vineland Intermediate
: Vineland
Events Analyzed: From
X (feet)
334600.56
334829.06
335156.09
335285.13
335657.66
334937.78
335812.53
334238.03
334568.59
335731 .63
334815.03
334324.94
334038.03
333476.41
333139.78
33491 1 .81
334323.75
334797.63
334257.56
334293.53
334376.66
334685.03
334995.03
335054.69
334884.16
334401 .88
334165.06
334153.66
334123.13
334110.84
334373.19
333500.00
Winter 2008
2/1/2008
Y (feet)
247536.44
247129.22
247201 .20
247175.61
247321 .58
246843.97
246883.78
246659.00
246498.09
2461 1 1 .45
2461 61 .73
246179.55
246626.73
246738.47
246876.63
247283.53
247354.23
247493.91
247524.66
248085.34
246887.61
246664.27
246588.30
247188.13
247416.95
247454.22
247343.08
247147.42
246715.27
246517.73
2471 91 .78
247105.00
User Name:
State: New
Dave Becker
Jersey
to Fall 2009
9/15/2009
Number
of COCs
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
COC-Averaged
Slope Factor*
0.191
0.386
0.668
0.360
0.521
0.560
0.522
0.412
0.408
0.136
0.272
0.177
0.009
0.195
0.064
0.230
0.047
0.669
0.180
0.464
0.470
0.033
0.079
0.426
0.347
0.277
0.090
0.522
0.531
0.000
Abandoned?
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
0
MAROS Version 2.2, 2006, AFCEE
Thursday, July 22, 2010
Page 1 of2
-------�
Project: Vineland Intermediate
Location: Vineland
User Name: Dave Becker
State: New Jersey
Well
MW52S
MW53S
MW54S
WW25S
WW26S
WW27S
X (feet)
333963.00
334088.00
333930.00
334212.63
333851 .63
333425.31
Y (feet)
247258.00
247628.00
248210.00
247852.27
247788.92
247796.73
Number
of COCs
1
1
1
1
1
1
COC-Averaged
Slope Factor*
0.806
0.437
0.000
Abandoned?
D
D
D
D
D
0
Note: the COC-Averaged Slope Factor is the value calculated by averaging those "Average Slope Factor"
obtained earlier across COCs; to be conservative, a location is "abandoned" only when it is eliminated
from all COCs; "abandoned" doesn't necessarily mean the abandon of well, it can mean that NO samples
need to be collected for any COCs.
* When the report is generated after running the Excel module, SF values will NOT be shown above.
MAROS Version 2.2, 2006, AFCEE
Thursday, July 22, 2010
Page 2 of2
-------�
Table 7. Mid-Depth Well Trends
MAROS Statistical Trend Analysis Summary
Project: Vineland Intermediate
Location: Vineland
User Name: Dave Becker
State: New Jersey
Time Period: 5/1/2000 to 11/1/2009
Consolidation Period: No Time Consolidation
Consolidation Type: Median
Duplicate Consolidation: Maximum
ND Values: 1/2 Detection Limit
J Flag Values : Actual Value
Well
Source/
Tail
Number Number
of of
Samples Detects
Average Median
Cone. Cone.
(mg/L) (mg/L)
All
Samples
"ND" ?
Mann-
Kendall
Trend
Linear
Regression
Trend
ARSENIC
EW01M
EW04M
EW05M
EW06M
EW07M
EW08M
EW09M
EW10M
EW11M
EW12M
EW13M
EW14M
EW15M
EW16M
EW17M
EW18M
EW19M
EW20M
EW21M
EW22M
EW23M
MW28M
MW29M
MW31M
MW32M
MW33M
MW34M
MW35M
MW36M
MW37M
MW38M
MW39M
MW40M
MW41M
MW42M
T
T
T
T
S
S
T
T
T
T
T
T
T
T
T
T
T
T
T
T
T
S
T
T
T
T
S
S
T
S
S
T
T
T
T
13
13
13
12
14
12
10
15
13
10
12
12
14
10
13
13
14
13
16
14
13
16
14
16
11
15
11
12
8
9
12
12
13
15
11
0
13
13
12
14
12
0
11
13
0
12
0
1
0
0
3
14
13
16
0
0
16
7
16
1
10
2
4
5
8
10
11
5
14
7
4.5E-03
1.2E+01
5.4E-01
4.1E+00
3.6E+00
3.5E-02
4.1E-03
1.3E-01
3.7E-01
3.8E-03
5.4E-01
4.2E-03
4.7E-03
3.8E-03
4.0E-03
6.1E-03
8.1E-02
3.9E+00
1.1E+00
4.0E-03
4.0E-03
7.6E+00
5.0E-01
7.7E+00
4.2E-03
3.7E-02
5.5E-03
1.0E-01
1.5E-02
6.9E-02
1.8E-02
1 .9E+00
1.2E-02
2.6E-01
5.7E-02
4.5E-03
8.5E+00
5.1E-01
3.2E+00
3.4E+00
3.4E-02
4.5E-03
3.4E-02
2.5E-01
4.5E-03
3.6E-01
4.5E-03
4.5E-03
4.5E-03
4.5E-03
4.5E-03
2.7E-02
2.9E+00
5.2E-01
4.5E-03
4.5E-03
7.7E+00
4.5E-03
5.7E+00
4.5E-03
3.9E-02
4.5E-03
4.5E-03
1.1E-02
1 .4E-02
1 .3E-02
7.1E-02
4.5E-03
4.1E-02
2.7E-02
Yes
No
No
No
No
No
Yes
No
No
Yes
No
Yes
No
Yes
Yes
No
No
No
No
Yes
Yes
No
No
No
No
No
No
No
No
No
No
No
No
No
No
S
D
S
D
D
I
NT
PD
NT
NT
D
NT
NT
NT
NT
PI
NT
D
NT
NT
NT
S
D
D
NT
D
S
NT
NT
NT
D
D
NT
D
PD
S
D
NT
D
D
I
NT
PD
NT
NT
D
NT
NT
NT
NT
NT
NT
D
NT
NT
NT
D
D
S
NT
D
S
NT
NT
NT
D
D
NT
PD
NT
MAROS Version 2.2, 2006, AFCEE
Sunday, July 18, 2010
Page 1 of 2
-------�
MAROS Statistical Trend Analysis Summary
Well
Source/
Tail
Number Number
of of
Samples Detects
Average Median
Cone. Cone.
(mg/L) (mg/L)
All
Samples
"ND" ?
Mann-
Kendall
Trend
Linear
Regression
Trend
ARSENIC
MW43M
MW44M
MW45M
MW46M
MW47M
MW48M
MW49M
MW50M
MW51M
MW52M
MW53M
MW54M
RW01
RW02
RW02A
RW02B
RW03
RW04
RW05
RW06
RW07
RW08
RW09
RW09A
RW10
RW11
RW12
RW13
WW24M
WW25M
WW26M
WW27M
T
T
T
T
T
T
T
S
T
T
T
T
T
T
T
T
T
T
T
T
T
T
T
T
T
T
T
T
T
T
T
T
10
10
12
11
14
10
10
11
4
4
4
5
30
31
10
10
33
32
32
33
33
33
10
10
33
32
33
30
12
13
16
13
1
2
12
1
14
9
10
4
0
4
2
5
30
31
10
10
33
32
32
33
33
33
10
10
33
25
33
30
0
13
12
1
4.5E-03
7.2E-03
4.5E-01
6.2E-03
2.2E-01
2.6E-02
8.3E-02
6.3E-03
3.8E-03
6.1E-01
7.5E-02
3.1E-02
1.2E+00
2.9E+00
1 .5E+00
1 .9E+00
1.3E+00
5.1E+00
1.7E+00
5.7E+00
3.3E+00
3.8E+00
8.2E-01
1.6E-01
2.1E+00
2.4E+00
3.0E+00
1.4E+00
4.2E-03
2.0E+00
1.6E-02
4.4E-03
4.5E-03
4.5E-03
4.5E-01
4.5E-03
1.5E-01
1 JE-02
7.3E-02
4.5E-03
4.5E-03
5.0E-01
5.6E-02
2.5E-02
1.2E+00
2.5E+00
1.1E+00
1.7E+00
7.8E-01
2.3E+00
7.4E-01
1.9E+00
1.3E+00
1.3E+00
4.1E-01
1.4E-01
6.4E-01
8.1E-02
7.1E-01
6.1E-02
4.5E-03
1.7E+00
1 .4E-02
4.5E-03
No
No
No
No
No
No
No
No
Yes
No
No
No
No
No
No
No
No
No
No
No
No
No
No
No
No
No
No
No
Yes
No
No
No
NT
PD
S
NT
S
NT
S
D
S
S
NT
I
D
D
D
S
D
D
D
D
D
D
PI
S
D
D
D
D
NT
D
NT
NT
NT
PD
S
PI
S
NT
I
D
PD
S
NT
I
D
D
D
S
D
D
NT
D
D
D
I
PD
D
D
D
D
NT
D
S
NT
Note: Increasing (I); Probably Increasing (PI); Stable (S); Probably Decreasing (PD); Decreasing (D); No Trend (NT); Not Applicable
(N/A); Not Applicable (N/A) - Due to insufficient Data (< 4 sampling events); No Detectable Concentration (NDC)
The Number of Samples and Number of Detects shown above are post-consolidation values.
MAROS Version 2.2, 2006, AFCEE
Sunday, July 18, 2010
Page 2 of 2
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Table 8
MAROS Spatial Moment Analysis Summary
Project: Vineland Intermediate
Location: Vineland
Oth Moment
Estimated
Effective Date Mass (Kg)
1st Moment (Center of Mass)
Source
Xc (ft) Yc (ft) Distance (ft)
User Name: Dave Becker
State: New Jersey
2nd Moment (Spread)
Sigma XX Sigma YY
(sq ft) (sq ft)
Number of
Wells
ARSENIC
5/1/2000
8/1/2000
11/1/2000
2/1/2001
5/1/2001
8/1/2001
11/1/2001
2/1/2002
5/1/2002
8/1/2002
11/1/2002
2/1/2003
5/1/2003
11/1/2003
2/1/2004
5/1/2004
11/1/2004
5/1/2005
11/1/2005
2/1/2006
5/1/2006
8/1/2006
2/1/2007
5/1/2007
11/1/2007
2/1/2008
5/1/2008
8/1/2008
11/1/2008
2/1/2009
5/1/2009
8/1/2009
11/1/2009
6.1E+02
7.2E+02
1.1E+03
8.5E+02
6.2E+02
4.8E+02
2.5E+02
3.3E+02
5.3E+02
3.6E+02
2.0E+02
4.6E+02
4.6E+02
4.2E+02
2.5E+02
2.3E+02
4.8E+02
1.9E+02
3.6E+02
8.4E+01
2.7E+02
3.1E+02
3.1E+02
1.9E+02
2.2E+02
1.3E+02
1.2E+02
1.4E+02
1.8E+02
9.9E+01
1.4E+02
1.2E+02
9.4E+01
334,453
334,554
334,538
334,602
334,427
334,421
334,508
334,427
334,511
334,583
334,615
334,427
334,405
334,601
334,663
334,462
334,644
334,503
334,622
334,724
334,512
334,513
334,607
334,555
334,451
334,723
334,561
334,542
334,472
334,542
334,543
334,588
334,569
247,532
247,366
247,403
247,360
247,234
247,421
247,321
247,472
247,459
247,355
247,260
247,232
247,218
247,199
247,429
247,357
247,345
247,283
247,301
247,297
247,305
247,344
247,322
247,312
247,494
247,343
247,250
247,261
247,341
247,344
247,245
247,282
247,240
693
532
560
485
630
675
563
689
608
501
445
630
651
454
460
616
440
560
448
349
555
564
468
516
677
366
497
518
602
537
515
476
489
76,931
164,417
114,569
120,789
186,868
142,040
186,397
134,613
81,348
142,095
98,901
89,501
95,725
100,254
95,512
48,141
138,980
140,294
171,036
104,721
61,545
192,667
104,337
75,130
78,151
112,932
99,458
94,347
80,733
128,303
77,020
93,433
89,625
36,948
50,187
79,508
66,410
87,492
71,718
71,078
65,492
56,228
67,864
33,465
29,717
50,680
69,312
64,650
66,773
65,014
92,851
80,729
47,264
50,034
91,786
66,396
49,966
62,587
69,106
29,523
27,235
71,376
86,005
23,913
23,907
31,152
55
41
38
31
29
56
56
54
54
36
18
13
26
23
37
18
44
23
35
32
23
34
23
13
47
25
15
15
23
52
13
12
14
MAROS Version 2.2, 2006, AFCEE
Sunday, July 18, 2010
Page 1 of 2
-------�
Project: Vineland Intermediate
Location: Vineland
User Name: Dave Becker
State: New Jersey
Moment Type Constituent
Zeroth Moment: Mass
ARSENIC
1st Moment: Distance to Source
ARSENIC
2nd Moment: Sigma XX
ARSENIC
2nd Moment: Sigma YY
ARSENIC
Coefficient
of Variation
0.68
0.17
0.33
0.35
Mann-Kendall
S Statistic
-354
-124
-126
-102
Confidence
in Trend
100.0%
97.2%
97.4%
94.1%
Moment
Trend
D
D
D
PD
Note: The following assumptions were applied for the calculation of the Zeroth Moment:
Porosity: 0.25 Saturated Thickness: Uniform: 50 ft
Mann-Kendall Trend test performed on all sample events for each constituent. Increasing (I); Probably Increasing (PI); Stable (S);
Probably Decreasing (PD); Decreasing (D); No Trend (NT); Not Applicable (N/A)-Due to insufficient Data (< 4 sampling events).
Note: The Sigma XX and Sigma YY components are estimated using the given field coordinate system and then rotated to align with the
estimated groundwater flow direction. Moments are not calculated for sample events with less than 6 wells.
MAROS Version 2.2, 2006, AFCEE
Sunday, July 18, 2010
Page 2 of 2
-------�
Table 9.
MAROS First Moment Analysis
Project: Vineland Intermediate
Location: Vineland
User Name: Dave Becker
State: |\|ew Jersey
COC: ARSENIC
Change in Location of Center of Mass Over Time
oe
4
>
m
0
oa
a
2/0
01
3/0
»
>
2
t
oa
1/
»
00
J/
oa
»
04
11
08
,
»
»
» 1
k
»
05
D5/
08
1/C
OS
05
02
4
/oe
1
OR
i
t
»
*
UL
n
08/00
02/09 4
05/07
08
DE
08
^
4
ft
08l
t C
19
to
8/C
02(
0
9
01
2/0
1
7
/a
*
»
02
04
»
&
02/0!
Groundwater
Flow Direction:
\
Source
Coordinate:
X: || 335,055
Y: | 247,188
334350 334400 334450
Effective Date Constituent
5/1/2000
8/1/2000
11/1/2000
2/1/2001
5/1/2001
8/1/2001
11/1/2001
2/1/2002
5/1/2002
8/1/2002
11/1/2002
2/1/2003
5/1/2003
11/1/2003
2/1/2004
5/1/2004
11/1/2004
5/1/2005
11/1/2005
2/1/2006
5/1/2006
8/1/2006
2/1/2007
5/1/2007
11/1/2007
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
334500 334550 334600 334650 334700 334750
Xc (ft)
Xc (ft) Yc (ft) Distance from Source (ft)
334,453
334,554
334,538
334,602
334,427
334,421
334,508
334,427
334,511
334,583
334,615
334,427
334,405
334,601
334,663
334,462
334,644
334,503
334,622
334,724
334,512
334,513
334,607
334,555
334,451
247,532
247,366
247,403
247,360
247,234
247,421
247,321
247,472
247,459
247,355
247,260
247,232
247,218
247,199
247,429
247,357
247,345
247,283
247,301
247,297
247,305
247,344
247,322
247,312
247,494
693
532
560
485
630
675
563
689
608
501
445
630
651
454
460
616
440
560
448
349
555
564
468
516
677
Number of Wells
55
41
38
31
29
56
56
54
54
36
18
13
26
23
37
18
44
23
35
32
23
34
23
13
47
MAROS Version 2.2, 2006, AFCEE
7/18/2010
Page 1 of 2
-------�
MAROS First Moment Analysis
Effective Date
Constituent
Xc (ft)
Yc(ft) Distance from Source (ft) Number of Wells
2/1/2008
5/1/2008
8/1/2008
11/1/2008
2/1/2009
5/1/2009
8/1/2009
11/1/2009
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
334,723
334,561
334,542
334,472
334,542
334,543
334,588
334,569
247,343
247,250
247,261
247,341
247,344
247,245
247,282
247,240
366
497
518
602
537
515
476
489
25
15
15
23
52
13
12
14
Note: Increasing (I); Probably Increasing (PI); Stable (S); Probably Decreasing (PD); Decreasing (D); No Trend (NT); Not Applicable (N/A) -
Due to insufficient Data (< 4 sampling events). Moments are not calculated for sample events with less than 6 wells.
MAROS Version 2.2, 2006, AFCEE
7/18/2010
Page 2 of 2
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Table 10. Heuristic Analysis Results, Mid-Depth Wells
MAROS Site Results
Project: Vineland Intermediate
Location: Vineland
User Name: Dave Becker
State: New Jersey
User Defined Site and Data Assumptions:
Hydrogeology and Plume Information:
Groundwater
Seepage Velocity: 100 ft/yr
Current Plume Length: 1500ft
Current Plume Width 1200 ft
Number of Tail Wells: 59
Number of Source Wells: 8
Source Information:
Source Treatment: Excavation
NAPL is not observed at this site.
Down-gradient Information:
Distance from Edge of Tail to Nearest:
Down-gradient receptor: 1 ft
Down-gradient property: 1 ft
Distance from Source to Nearest:
Down-gradient receptor: 1500ft
Down-gradient property: 1500ft
Data Consolidation Assumptions:
Time Period: 5/1/2000 to 11/1/2009
Consolidation Period: No Time Consolidation
Consolidation Type: Median
Duplicate Consolidation: Maximum
ND Values: 1/2 Detection Limit
J Flag Values : Actual Value
Plume Information Weighting Assumptions:
Consolidation Step 1. Weight Plume Information by Chemical
Summary Weighting: Weighting Applied to All Chemicals Equally
Consolidation Step 2. Weight Well Information by Chemical
Well Weighting: No Weighting of Wells was Applied.
Chemical Weighting: No Weighting of Chemicals was Applied.
Note: These assumptions were made when consolidating the historical montoring data and lumping the Wells and COCs.
1. Compliance Monitoring/Remediation Optimization Results:
Preliminary Monitoring System Optimization Results: Based on site classification, source treatment and Monitoring System
Category the following suggestions are made for site Sampling Frequency, Duration of Sampling before reassessment, and
Well Density. These criteria take into consideration: Plume Stability, Type of Plume, and Groundwater Velocity.
coc
Tail
Stability
Source
Stability
Level of
Effort
Sampling
Duration
Sampling
Frequency
Sampling
Density
ARSENIC
M Remove treatment system if
previously reducing
concentration or PRG met.
No Recommendation
30
Note:
Plume Status: (I) Increasing; (Pl)Probably Increasing; (S) Stable; (NT) No Trend; (PD) Probably Decreasing; (D) Decreasing
Design Categories: (E) Extensive; (M) Moderate; (L) Limited (N/A) Not Applicable, Insufficient Data Available
Level of Monitoring Effort Indicated by Analysi Moderate
2. Spatial Moment Analysis Results:
MAROS Version 2.2, 2006, AFCEE
Sunday, July 18, 2010
Page 1 of 2
-------�
Moment Type Constituent
Zeroth Moment: Mass
ARSENIC
1st Moment: Distance to Source
ARSENIC
2nd Moment: Sigma XX
ARSENIC
2nd Moment: Sigma YY
ARSENIC
Coefficient
of Variation
0.68
0.17
0.33
0.35
Mann-Kendall
S Statistic
-354
-124
-126
-102
Confidence
in Trend
100.0%
97.2%
97.4%
94.1%
Moment
Trend
D
D
D
PD
Note: The following assumptions were applied for the calculation of the Zeroth Moment:
Porosity: 0.25
Saturated Thickness: Uniform: 50 ft
Mann-Kendall Trend test performed on all sample events for each constituent. Increasing (I); Probably Increasing (PI); Stable (S);
Probably Decreasing (PD); Decreasing (D); No Trend (NT); Not Applicable (N/A)-Due to insufficient Data (< 4 sampling events).
MAROS Version 2.2, 2006, AFCEE
Sunday, July 18, 2010
Page 2 of 2
-------�
Table 11.
MAROS Sampling Frequency Optimization Results
Project: Vineland Intermediate
Location: Vineland
User Name: Dave Becker
State: New Jersey
"Recent Period" defined by events: From Fall 2007
11/1/2007
"Rate of Change" parameters used:
To Fall 2009
11/1/2009
Constituent Cleanup Goal Low Rate Medium Rate High Rate
ARSENIC 0.05
Units: Cleanup Goal is in mg/L; all rate parameters are
Recommended
Well Sampling Frequency
0.025 0.05 0.1
in mg/L/year.
Frequency Based Frequency Based
on Recent Data on Overall Data
ARSENIC
EW01M Biennial
EW04M Quarterly
EW05M Quarterly
EW06M Quarterly
EW07M Quarterly
EW08M SemiAnnual
EW09M Annual
EW1 OM Quarterly
EW1 1 M Quarterly
EW12M Annual
EW1 3M Quarterly
EW14M Annual
EW15M Annual
EW16M Annual
EW17M Annual
EW18M Annual
EW19M SemiAnnual
EW20M Quarterly
EW21M Quarterly
EW22M Annual
EW23M Annual
MW28M Quarterly
MW29M Annual
MW31 M Quarterly
Annual
Annual
Quarterly Quarterly
Quarterly Quarterly
Quarterly Quarterly
Quarterly Quarterly
SemiAnnual SemiAnnual
Annual
Annual
Quarterly Quarterly
Quarterly Quarterly
Annual
Annual
Quarterly Quarterly
Annual
Annual
Annual
Annual
Annual
Annual
Annual
Annual
Annual
Annual
SemiAnnual SemiAnnual
Quarterly Quarterly
Quarterly Quarterly
Annual
Annual
Annual
Annual
Quarterly Quarterly
Annual
Annual
Quarterly Quarterly
MAROS Version 2.2, 2006, AFCEE
Sunday, July 18,2010
Page 1 of 3
-------�
Project: Vineland Intermediate
Location: Vineland
User Name: Dave Becker
State: New Jersey
Well
MW32M
MW33M
MW34M
MW35M
MW37M
MW38M
MW39M
MW40M
MW41M
MW42M
MW43M
MW44M
MW45M
MW46M
MW47M
MW48M
MW49M
MW50M
MW52M
MW53M
MW54M
RW01
RW02
RW02A
RW02B
RW03
RW04
RW05
RW06
RW07
RW08
RW09A
RW10
RW11
RW12
RW13
VWV24M
VWV25M
Recommended
Sampling Frequency
Annual
Annual
Annual
Annual
Annual
Annual
SemiAnnual
Annual
Annual
Annual
Annual
Annual
Quarterly
Annual
Quarterly
Annual
Quarterly
Annual
Quarterly
Quarterly
SemiAnnual
Annual
Annual
Annual
Annual
Quarterly
Annual
Annual
Annual
Annual
Annual
Annual
Annual
Annual
Annual
Annual
Annual
Quarterly
Frequency Based
on Recent Data
Annual
Annual
Annual
Annual
Annual
Annual
SemiAnnual
Annual
Annual
Annual
Annual
Annual
Quarterly
Annual
Quarterly
Annual
Quarterly
Annual
Quarterly
Quarterly
SemiAnnual
Annual
Annual
Annual
Annual
Quarterly
Annual
Annual
Annual
Annual
Annual
Annual
Annual
Annual
Annual
Annual
Annual
Quarterly
Frequency Based
on Overall Data
Annual
Annual
Annual
Annual
Annual
Annual
SemiAnnual
Annual
Annual
Annual
Annual
Annual
Quarterly
Annual
Quarterly
Annual
Quarterly
Annual
Quarterly
Quarterly
SemiAnnual
Annual
Annual
Annual
Annual
Annual
Annual
Annual
Annual
Annual
Annual
Annual
Annual
Annual
Annual
Annual
Annual
Quarterly
MAROS Version 2.2, 2006, AFCEE
Sunday, July 18,2010
Page 2 of 3
-------�
Project: Vineland Intermediate User Name: Dave Becker
Location: Vineland State: New Jersey
Recommended Frequency Based Frequency Based
Well Sampling Frequency on Recent Data on Overall Data
VWV26M Annual Annual Annual
VWV27M Annual Annual Annual
Note: Sampling frequency is determined considering both recent and overall concentration trends. Sampling Frequency is the
final recommendation; Frequency Based on Recent Data is the frequency determined using recent (short) period of monitoring
data; Frequency Based on Overall Data is the frequency determined using overall (long) period of monitoring data. If the "recent
period" is defined using a different series of sampling events, the results could be different.
MAROS Version 2.2, 2006, AFCEE Sunday, July 18, 2010 Page 3 of 3
-------�
Table 12 .
1 MAROS Sampling Location Optimization Results 1
Project:
Location
Sampling
Vineland Intermediate
: Vineland
Events Analyzed:
Parameters used:
Well
From Winter 2009
2/1/2009
User
State
Name: Dave Becker
New Jersey
to Fall 2009
11/1/2009
Constituent
ARSENIC
Inside SF
0.2
HullSF
0.1
Area Ratio Cone
Ratio
0.9 0.8
X (feet)
Average
Y (feet) Removable? Slope Factor*
Minimum
Slope Factor*
Maximum
Slope Factor*
Eliminated?
ARSENIC
EW01M
EW05M
EW06M
EW08M
EW09M
EW10M
EW11M
EW12M
EW13M
EW14M
EW15M
EW16M
EW17M
EW18M
EW19M
EW22M
EW23M
MW28M
MW29M
MW31M
MW32M
MW33M
MW34M
MW35M
MW37M
MW38M
MW39M
MW40M
334423.06
334584.69
334822.38
335282.69
335657.88
334273.47
334944.25
335812.53
334226.97
334576.69
335364.66
335726.00
334803.94
334329.84
334041 .59
333479.31
333147.25
334910.03
334332.16
334257.28
334293.22
334376.59
334679.88
334999.31
335530.72
335061 .56
334878.94
334407.75
248236.41
247105.13
247129.81
247183.30
247326.73
247058.27
246843.64
246873.55
246670.30
246496.89
246214.66
246119.73
246161.19
246187.56
246619.63
246750.97
246882.34
247268.52
247354.81
247518.86
248080.13
246887.63
246664.66
246589.69
247221 .02
247187.80
24741 8.59
247455.70
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
449
282
064
317
607
033
242
395
091
206
000
000
000
000
148
171
344
458
663
480
497
660
443
394
132
747
760
718
0.449
0.282
0.064
0.317
0.607
0.033
0.242
0.395
0.091
0.206
0.000
0.000
0.000
0.000
0.148
0.171
0.344
0.458
0.663
0.480
0.497
0.660
0.443
0.394
0.132
0.747
0.760
0.718
0.449
0.282
0.064
0.317
0.607
0.033
0.242
0.395
0.091
0.206
0.000
0.000
0.000
0.000
0.148
0.171
0.344
0.458
0.663
0.480
0.497
0.660
0.443
0.394
0.132
0.747
0.760
0.718
D
D
D
D
D
D
D
D
D
D
D
0
0
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
MAROS Version 2.2, 2006, AFCEE
Sunday, July 18,2010
Page 1 of 2
-------�
Project: Vineland Intermediate
Location: Vineland
User Name: Dave Becker
State: New Jersey
Well
MW41M
MW42M
MW45M
MW46M
MW47M
MW48M
MW49M
MW50M
MW54M
RW01
RW02
RW02A
RW02B
RW03
RW04
RW05
RW06
RW07
RW08
RW09A
RW10
RW11
RW12
RW13
VWV24M
VWV26M
VWV27M
X (feet)
334166.41
334153.66
334121.69
334111.19
334372.66
335156.84
335290.81
335379.91
333931 .00
335340.75
335201 .78
335312.00
335204.00
334905.63
334761 .88
334656.25
334653.50
334552.06
334169.94
333736.00
334142.91
333695.16
334127.94
334115.22
334054.22
333849.22
333414.06
Y (feet)
247338.44
2471 47.42
246709.91
246512.52
247187.59
247081 .69
247123.06
247196.06
248215.00
247239.47
247183.59
247227.00
2471 45.00
247198.69
247496.75
247391 .86
247624.25
247493.39
247445.88
247118.00
247048.30
246975.20
246826.36
246627.48
248099.25
247793.30
247798.97
Removable?
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Average
Slope Factor*
0.315
0.676
0.301
0.589
0.383
0.408
0.042
0.694
0.591
0.182
0.257
0.260
0.395
0.040
0.085
0.130
0.211
0.141
0.251
0.475
0.268
0.665
0.208
0.174
0.358
0.601
0.395
Minimum
Slope Factor*
0.315
0.676
0.301
0.589
0.383
0.408
0.042
0.694
0.591
0.182
0.186
0.055
0.163
0.002
0.001
0.022
0.037
0.033
0.087
0.447
0.029
0.631
0.011
0.174
0.358
0.601
0.395
Maximum
Slope Factor*
0.315
0.676
0.301
0.589
0.383
0.408
0.042
0.694
0.591
0.182
0.332
0.364
0.535
0.129
0.211
0.181
0.332
0.210
0.358
0.511
0.410
0.749
0.319
0.174
0.358
0.601
0.395
Eliminated?
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
D
Note: The Slope Factor indicates the relative importance of a well in the monitoring network at a given sampling event; the larger the SF
value of a well, the more important the well is and vice versa; the Average Slope Factor measures the overall well importance in the
selected time period; the state coordinates system (i.e., X and Y refer to Easting and Northing respectively) or local coordinates systems
may be used; wells that are NOT selected for analysis are not shown above.
* When the report is generated after running the Excel module, SF values will NOT be shown above.
MAROS Version 2.2, 2006, AFCEE
Sunday, July 18, 2010
Page 2 of 2
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Table 13. Deep Well Trends.
MAROS Statistical Trend Analysis Summary
Project: Vineland Deep
Location: Vineland
User Name: Dave Becker
State: New Jersey
Time Period: 5/1/2000 to 2/1/2009
Consolidation Period: No Time Consolidation
Consolidation Type: Median
Duplicate Consolidation: Maximum
ND Values: 1/2 Detection Limit
J Flag Values : Actual Value
Well
Source/
Tail
Number Number
of of
Samples Detects
Average Median
Cone. Cone.
(mg/L) (mg/L)
All
Samples
"ND" ?
Mann-
Kendall
Trend
Linear
Regression
Trend
ARSENIC
EW01D
EW04D
EW05D
EW07D
EW09D
EW10D
EW15D
MW51D
MW54D
T
T
T
S
S
T
T
T
T
12
16
8
16
9
9
10
4
5
0
8
1
4
0
1
1
0
1
4.3E-03
1.0E-02
4.7E-03
6.4E-03
4.1E-03
4.1E-03
3.9E-03
3.8E-03
1.2E-02
4.5E-03
4.5E-03
4.5E-03
4.5E-03
4.5E-03
4.5E-03
4.5E-03
4.5E-03
4.5E-03
Yes
No
No
No
Yes
No
No
Yes
No
S
PD
NT
S
NT
NT
NT
S
NT
S
NT
NT
I
NT
NT
NT
PD
NT
Note: Increasing (I); Probably Increasing (PI); Stable (S); Probably Decreasing (PD); Decreasing (D); No Trend (NT); Not Applicable
(N/A); Not Applicable (N/A) - Due to insufficient Data (< 4 sampling events); No Detectable Concentration (NDC)
The Number of Samples and Number of Detects shown above are post-consolidation values.
MAROS Version 2.2, 2006, AFCEE
Monday, July 19, 2010
Page 1 of 1
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Table 14.
MAROS Spatial Moment Analysis Summary
Project: Vineland Deep User Name: Dave Becker
Location: Vineland
Effective Date
State: New Jersey
Oth Moment 1st Moment (Center of Mass) 2nd Moment (Spread)
Estimated Source Sigma XX Sigma YY
Mass (Kg) Xc (ft) Yc (ft) Distance (ft) (sq ft) (sq ft)
Number of
Wells
ARSENIC
5/1/2000
8/1/2000
11/1/2000
2/1/2001
5/1/2001
11/1/2001
5/1/2002
5/1/2003
9/1/2003
3/1/2004
6/1/2004
11/1/2004
5/1/2005
11/1/2005
5/1/2006
10/1/2006
3/1/2007
6/1/2007
9/1/2007
2/1/2008
9/21/2008
2/1/2009
3.3E-01 335,045 246,995 193 71,819 43,517
O.OE+00
O.OE+00
O.OE+00
2.4E+00 334,995 246,995 202 73,135 45,004
2.1E+00 335,014 247,014 179 76,536 47,242
2.0E+00 335,027 246,991 199 75,374 43,632
O.OE+00
O.OE+00
O.OE+00
O.OE+00
O.OE+00
O.OE+00
3.3E+00 334,433 247,193 622 147,502 110,622
2.8E+00 334,439 247,600 741 153,616 46,894
O.OE+00
2.0E+00 334,451 247,298 614 74,241 157,862
O.OE+00
O.OE+00
O.OE+00
O.OE+00
3.5E+00 334,819 247,318 269 123,581 149,097
6
2
3
1
6
6
6
2
2
5
2
3
4
6
6
3
6
3
3
5
3
6
MAROS Version 2.2, 2006, AFCEE
Monday, July 19, 2010
Page 1 of 2
-------�
Project: Vineland Deep
Location: Vineland
User Name: Dave Becker
State: New Jersey
Moment Type Constituent
Zeroth Moment: Mass
ARSENIC
1st Moment: Distance to Source
ARSENIC
2nd Moment: Sigma XX
ARSENIC
2nd Moment: Sigma YY
ARSENIC
Coefficient
of Variation
1.51
0.63
0.36
0.63
Mann-Kendall
S Statistic
2
12
14
18
Confidence
in Trend
51.1%
91.1%
94.6%
98.4%
Moment
Trend
NT
PI
PI
I
Note: The following assumptions were applied for the calculation of the Zeroth Moment:
Porosity: 0.25 Saturated Thickness: Uniform: 60 ft
Mann-Kendall Trend test performed on all sample events for each constituent. Increasing (I); Probably Increasing (PI); Stable (S);
Probably Decreasing (PD); Decreasing (D); No Trend (NT); Not Applicable (N/A)-Due to insufficient Data (< 4 sampling events).
Note: The Sigma XX and Sigma YY components are estimated using the given field coordinate system and then rotated to align with the
estimated groundwater flow direction. Moments are not calculated for sample events with less than 6 wells.
MAROS Version 2.2, 2006, AFCEE
Monday, July 19, 2010
Page 2 of 2
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Table 15.
MAROS First Moment Analysis
Project: Vineland Deep
Location: Vineland
User Name: Dave Becker
State: |\|ew Jersey
COC: ARSENIC
Change in Location of Center of Mass Over Time
k n
4
» Q
2/0
9
«
4
«
3V
)0
334400 334500 334600 334700 334800 334900 335000 335100
Xc (ft)
Groundwater
Flow Direction:
\
Source
Coordinate:
X: || 335,055
Y: | 247,188
Effective Date
Constituent
Xc (ft)
Yc(ft) Distance from Source (ft) Number of Wells
5/1/2000
8/1/2000
11/1/2000
2/1/2001
5/1/2001
11/1/2001
5/1/2002
5/1/2003
9/1/2003
3/1/2004
6/1/2004
11/1/2004
5/1/2005
11/1/2005
5/1/2006
10/1/2006
3/1/2007
6/1/2007
9/1/2007
2/1/2008
9/21/2008
2/1/2009
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
ARSENIC
335,045
334,995
335,014
335,027
334,433
334,439
334,451
334,819
246,995 193
246,995 202
247,014 179
246,991 199
247,193 622
247,600 741
247,298 614
247,318 269
6
2
3
1
6
6
6
2
2
5
2
3
4
6
6
3
6
3
3
5
3
6
Note: Increasing (I); Probably Increasing (PI); Stable (S); Probably Decreasing (PD); Decreasing (D); No Trend (NT); Not Applicable (N/A) -
Due to insufficient Data (< 4 sampling events). Moments are not calculated for sample events with less than 6 wells.
MAROS Version 2.2, 2006, AFCEE
7/19/2010
Page 1 of 1
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Table 16. Heuristic Analysis Results, Deep Wells.
MAROS Site Results
Project: Vineland Deep
Location: Vineland
User Name: Dave Becker
State: New Jersey
User Defined Site and Data Assumptions:
Hydrogeology and Plume Information:
Groundwater
Seepage Velocity: 100 ft/yr
Current Plume Length: 1500ft
Current Plume Width 1200 ft
Number of Tail Wells: 7
Number of Source Wells: 2
Source Information:
Source Treatment: Excavation
NAPL is not observed at this site.
Down-gradient Information:
Distance from Edge of Tail to Nearest:
Down-gradient receptor: 1 ft
Down-gradient property: 1 ft
Distance from Source to Nearest:
Down-gradient receptor: 1500ft
Down-gradient property: 1500ft
Data Consolidation Assumptions:
Time Period: 5/1/2000 to 2/1/2009
Consolidation Period: No Time Consolidation
Consolidation Type: Median
Duplicate Consolidation: Maximum
ND Values: 1/2 Detection Limit
J Flag Values : Actual Value
Plume Information Weighting Assumptions:
Consolidation Step 1. Weight Plume Information by Chemical
Summary Weighting: Weighting Applied to All Chemicals Equally
Consolidation Step 2. Weight Well Information by Chemical
Well Weighting: No Weighting of Wells was Applied.
Chemical Weighting: No Weighting of Chemicals was Applied.
Note: These assumptions were made when consolidating the historical montoring data and lumping the Wells and COCs.
1. Compliance Monitoring/Remediation Optimization Results:
Preliminary Monitoring System Optimization Results: Based on site classification, source treatment and Monitoring System
Category the following suggestions are made for site Sampling Frequency, Duration of Sampling before reassessment, and
Well Density. These criteria take into consideration: Plume Stability, Type of Plume, and Groundwater Velocity.
coc
Tail
Stability
Source
Stability
Level of
Effort
Sampling
Duration
Sampling
Frequency
Sampling
Density
ARSENIC
NT
PI
Remove treatment system if
previously reducing
concentration or PRG met.
No Recommendation
30
Note:
Plume Status: (I) Increasing; (Pl)Probably Increasing; (S) Stable; (NT) No Trend; (PD) Probably Decreasing; (D) Decreasing
Design Categories: (E) Extensive; (M) Moderate; (L) Limited (N/A) Not Applicable, Insufficient Data Available
Level of Monitoring Effort Indicated by Analysi Extensive
2. Spatial Moment Analysis Results:
MAROS Version 2.2, 2006, AFCEE
Monday, July 19, 2010
Page 1 of 2
-------�
Moment Type Constituent
Zeroth Moment: Mass
ARSENIC
1st Moment: Distance to Source
ARSENIC
2nd Moment: Sigma XX
ARSENIC
2nd Moment: Sigma YY
ARSENIC
Coefficient
of Variation
1.51
0.63
0.36
0.63
Mann-Kendall
S Statistic
2
12
14
18
Confidence
in Trend
51.1%
91.1%
94.6%
98.4%
Moment
Trend
NT
PI
PI
I
Note: The following assumptions were applied for the calculation of the Zeroth Moment:
Porosity: 0.25
Saturated Thickness: Uniform: 60 ft
Mann-Kendall Trend test performed on all sample events for each constituent. Increasing (I); Probably Increasing (PI); Stable (S);
Probably Decreasing (PD); Decreasing (D); No Trend (NT); Not Applicable (N/A)-Due to insufficient Data (< 4 sampling events).
MAROS Version 2.2, 2006, AFCEE
Monday, July 19, 2010
Page 2 of 2
-------�
Diverted
Blackwater Branch
Natural channel is dry.
.3
Shallow Water Elevations (ft)1
April 19, 2010
68,0
1 Issue with site datum:
Values without an asterisk = 2003 survey
Values with an asterisk = 2010 survey
-------�
O
'"-, >..
//"Blackwater Branch
Diverted
Blackwater Branch
Natural channel is dry.
Mid-Depth Water Elevation (ft)1
April 19, 2010
68.0
Groundwater
Treatment
Plant
jsso x Issue with site datum:
Values without an asterisk = 2003 survey
' 56.0 Values with an asterisk = 2010 survey
-------�
ATTACHMENT G
Input Information and Results Only
(References for footprint conversion factors provided upon request)
-------�
Vineland Footprint Analysis
Green Remediation - Inventory of Energy, Material, Waste, and Other Remedy Aspects
Remedy Conceptual Design and Assumptions:
Existing Pump and Treat System
Overview
The remedy is a pump and treate system for OU2 of the Vineland Chemical Superfund Site. The system currently extracts
approximately 750 gpmfrom 12 extraction wells. The water is pumped to an equalization tank and then to the following process
components:
- chemical oxidation where hydrogen peroxide is added
- coagulation where ferric chloride and sodium hydroxide are added
-flocculation where polymer is added andflox is formed
- dissolved air flotation to separate solids from the process water
-filtration with continuous backwashing sand filters
- discharge to surface water
The removed solids are dewatered with a centrifuge and disposed of as hazardous waste. Groundwater sampling is conducted
on an annual basis.
White cells are for manual data input
Yellow cells are for manual data input from a drop-down list of selections and are protected
Blue cells are calculated cells that are protected
Instructions
1. Enter site or project name on row three of this tab.
2. Enter remedy name on row six of this tab.
3. Enter site and remedy description on row nine of this tab.
4. Copy the template tab and rename as a specific activity (e.g., O&M) on tab label and on row six of the tab.
5. Enter activity-specific information into the white and yellow cells on the copied/renamed tab.
6. Repeat steps 4 through 5 as needed for up to a total of 15 activities/tabs.
7. In cells E6 to S6 of the Summary tab, enter the names of the activity tabs from steps 4 through 6 (one name per cell).
8. In cells E4to S4 of the Summary tab, enter the number (1 to 6) corresponding to the Level of the activity named in the
corresponding cell in Row 6. For example, if the analysis defines Level 1 as construction, and the activities named in E6, F6, and
G6 are all related to construction, then enter the number 1 in E4, F4, and G4.
Information from the activity tabs is compiled and summarized in the Summary tab. Some of the blue (calculated) cells of the
activity tabs refer to the Lookup tab for conversion factors and default values. Each section of the activity tabs include white cells
only if user override values are preferred instead of the default values from the Lookup tab.
All of the activities fora particular remedy to be included n the footprint analysis should be included in a single inventory
spreadsheet. The spreadsheets are organized so that each remedy or remedy alternative has its own inventory spreadsheet.
This workbook is designed to assist EPA with conducting footprint analyses and to help EPA better understand the process of footprint
quantification for environmental remedies. The workbook does not represent EPA guidance, requirements, or suggestions with respect to
footprint quantification. The workbook is in draft status as of March 2011, and is intended for testing purposes. For more information about
this draft template and footprint analyses at clean-up sites, contact:
Karen Scheuermann (EPA Region 9) atscheuermann.karen@epa.gov or Carlos Pachon (EPA OSRTI) atpachon.carlos@epa.gov.
-------�
Vineland Footprint Analysis
General Scope
Input for Groundwater Extraction
Typical Scope Items
Green Remediation - Inventory of Energy, Material, Waste, and Other Remedy Aspects
Existing Pump and Treat System
Useful Information
Groundwater extraction network
- electricity for pumps
-well maintenance
Labor, Mobilizations, Mileage, and Fuel
Participant
Well jetting contractor
Well jetting oversight
Crew Size
2
1
Number of
Days
2
2
Hours
Worked Per
Day
8
8
Total Hours
Worked
32
16
Trips to Site
2
2
Roundtrip
Miles to Site
80
80
Mode of Transport.
Heavy-Duty Truck
Light-Duty Truck
Fuel Type
Gasoline
Gasoline
Total Miles
Traveled
160
160
Miles Per
Gallon
10
15
Total Fuel
Used
16
10.7
Activity or Notes
Equipment Use, Mobilization, and Fuel Usage
Equipment Type
Other
HP
50
Load
Factor
0.5
Equip. Fuel
Type
diesel
Gallons
Fuel Used
per Hour
1.275
Total Hours
Operated
8
Gallons Fuel
Used
On-Site
10.2
Trips to Site
Roundtrip
Miles to Site
Total Miles
Transported
Transport Fuel
Type
Miles per
Gallon
Gallons Fuel
Used for
Transport.
Activity or Notes
pressure washer and pump towed behind truck
assumes 8 wells per year
1 hour per well at 1200 psi and 40 gpm
Electricity Usage
Equipment Type
Equip, with kW rating
Equip, with kW rating
Direct kWh info.
HP
% Full
Load
Efficiency
Totals
Electrical
Rating (kW)
0
Hours Used
Energy Used
(kWh)
441600
441600
Notes
Extraction pumps
see equipment list
Natural Gas Usage
Cells shaded in dark gray are not relevant to the equipment types noted
"Direct kWh info" refers to total electricity usage calculated or provided elsewhere (e.g., an electric meter).
Equipment Type
Power Rating
(btu/hr)
Efficiency
Totals
Total Hours
Used
Btus
Required
0
Total
Therms
Used
0
Notes
If heat load is known instead of unit power rating, then enter power rating as 125% of heat load and choose 80% for efficiency.
This workbook is for testing and research purposes only. It does not represent EPA guidance or a requirement.
For more information contact: scheuermann.karen@epa.gov or pachon.carlos@epa.gov.
-------�
Vineland Footprint Analysis
Materials Usage
Input for Groundwater Extraction
Material Type
Other3 -acetic acid
Other3 -acetic acid
Unit
Ibs
Ibs
Quantity
1927.7076
3000
Site-Spec.
One- Way
Distance
(miles)*
40
500
Empty Return Trips
Number of
Trips
1
1
2
Total One-
Way Miles
40
500
540
Mode of Transport.
Truck A (< 5 tons)
Truck A (< 5 tons)
Truck A (< 5 tons)
Fuel Type
Diesel
Diesel
Diesel
Fuel Use Rate
(mpgorgptm)
8.5
8.5
8.5
Total Fuel Use
4.7
58.8
63.5
Notes
acetic acid as surrogate for glycolic acid
acetic acid as surrogate for Redux
Green Remediation - Inventory of Energy, Material, Waste, and Other Remedy Aspects
Existing Pump and Treat System
Laboratory Analysis
Parameter and Notes
VOCs
SVOCs
PCBs/Pesticides
Metals
Other
Other
Other
Other
Other
Other
Unit Cost
Totals
Number of
Samples
0
Total Cost
0
0
0
0
0
0
0
0
0
0
0
* Leave site-specific one-way miles blank if value is not known and a default will be used for
Waste Generation
Fuel Use Rate reported in miles per gallon (mpg) and gallons per ton-mile (gptm)
Waste Type
Unit
tons
tons
tons
tons
tons
Quantity
Site-Spec.
One-Way
Distance
(miles)
Empty Return Trips
Number of
Trips
Total One-
Way Miles
Mode of Transport.
Truck A (< 5 tons)
Fuel Type
Fuel Use Rate
Total Fuel Use
Notes
* Leave site-specific one-way miles blank if value is not known and a default will be used for
calculating total-one way miles
On-Site Water Usage (1000 x gallons)
gptm = gallons per ton-mile
Fate of On-Site Water Usage (1000 x gallons)
Resource Type
Potable water
Water table drawdown (ft)
Quantity
99
Use of Resource
water for diluting glycolic acid
Discharge Location
Reinjected to aquifer
Notes
If potable water is trucked to site, use "potable water" in materials section to calculate fuel use. Only the potable water use from the On-Site Water Use Section will be input into the Summary tab. It is assumed that the quantity of potable water in the Materials section is
accounted for in in the On-Site Water Use Section.
Miscellaneous Emissions and Reductions
Item
Other HAP emissions
Other GHG emissions
Other GHG reductions
Other NOx reductions
Other SOx reductions
Other PM reductions
Quantity
Activity or Notes
On-Site Renewable Energy Generation
Item
Photovoltaic (kWh)
Renewable Energy #1 (kWh)
Renewable Energy #2 (kWh)
Quantity
Activity or Notes
Purchased Renewable Energy (including Renewable Energy Certificates "RECs")
This workbook is for testing and research purposes only. It does not represent EPA guidance or a requirement.
For more information contact: scheuermann.karen@epa.gov or pachon.carlos@epa.gov.
Item
Purchased from Utility (kWh)
RECs (kWh)
Quantity
441600
Activity or Notes
RECs, New Jersey area (eGRID non-base load)
-------�
Vine/and Footprint Analysis
General Scope
Input for O&M
Typical Scope Items
Green Remediation - Inventory of Energy, Material, Waste, and Other Remedy Aspects
Existing Pump and Treat System
Useful Information
P&T System O&M
Labor, Mobilizations, Mileage, and Fuel
Participant
Full-time operators
part-time operator
Crew Size
3
1
Number of
Days
260
130
Hours
Worked Per
Day
8
8
Total
Hours
Worked
6240
1040
Trips to Site
780
130
Roundtrip
Miles to Site
20
20
Mode of Transport.
Light-Duty Truck
Light-Duty Truck
Fuel Type
Gasoline
Gasoline
Total Miles
Traveled
15600
2600
Miles Per
Gallon
15
15
Total Fuel
Used
1040
173.3
Activity or Notes
Equipment Use, Mobilization, and Fuel Usage
Equipment Type
HP
Load
Factor
Equip. Fuel
Type
Gallons
Fuel Used
per Hour
Total Hours
Operated
Gallons Fuel
Used
On-Site
Trips to Site
Roundtrip
Miles to Site
Total Miles
Transported
Transport Fuel
Type
Miles per
Gallon
Gallons Fuel
Used for
Transport.
Activity or Notes
Electricity Usage
Equipment Type
Equip, with kW rating
Equip, with kW rating
HP
% Full
Load
Efficiency
Totals
Electrical
Rating (kW)
0
Hours
Used
Energy Used
(kWh)
875900
875900
Notes
Usage for treatment plant
see equipment list
Natural Gas Usage
Equipment Type
Power Rating
(btu/hr)
Efficiency
Totals
Total Hours
Used
Btus
Required
0
Total
Therms
Used
23657
23657
Notes
from gas bills
// heat load is known instead of unit power rating, then enter power rating as 125% of heat load and choose 80% for efficiency.
Cells shaded in dark gray are not relevant to the equipment types noted
"Direct kWh info" refers to total electricity usage calculated or provided elsewhere (e.g., an electric meter).
This workbook is for testing and research purposes only. It does not represent EPA guidance or a requirement.
For more information contact: scheuermann.karen@epa.gov or pachon.carlos@epa.gov.
-------�
Vine/and Footprint Analysis
Materials Usage
Input for O&M
Material Type
Hydrogen peroxide (50%, SG=1.19)
Other 1 - Ferric chloride
Potable water
Sodium hydroxide (dry bulk)
Potable water
Polymer
Unit
Ibs
Ibs
gals
Ibs
gals
Ibs
Quantity
98000
197000
63840.819
256000
122781.77
33485.1
Site-Spec.
One-Way
Distance
(miles)*
40
40
40
40.0
40
40.000
Empty Return Trips
Number of
Trips
2
12
12
25
25
8
84
Total One-
Way Miles
80
480
480
1000
1000
320
3360
Mode of Transport.
Truck Heavy Load (gptm)
Truck Heavy Load (gptm)
Truck Heavy Load (gptm)
Truck Heavy Load (gptm)
Truck Heavy Load (gptm)
Truck Light Load (gptm)
Truck A (< 5 tons)
Fuel Type
Diesel
Diesel
Diesel
Diesel
Diesel
Diesel
Diesel
Fuel Use Rate
(mpgorgptm)
0.011
0.011
0.011
0.011
0.011
0.024
8.5
Total Fuel Use
21.6
43.3
117.1
56.3
225.3
16.1
395.3
Notes
water blended with FeCI3 by vendor
water blended with NaOH by vendor
assumes SG=1
Green Remediation - Inventory of Energy, Material, Waste, and Other Remedy Aspects
Existing Pump and Treat System
Laboratory Analysis
Parameter and Notes
Arsenic
SVOCs
PCBs/Pesticides
Metals
Other
Other
Other
Other
Other
Other
Unit Cost
15
Totals
Number of
Samples
1300
1300
Total Cost
19500
0
0
0
0
0
0
0
0
0
19500
* Leave site-specific one-way miles blank if value is not known and a default will be used for
Waste Generation
Fuel Use Rate reported in miles per gallon (mpg) and gallons per ton-mile (gptm)
Waste Type
Hazardous landfill
Unit
tons
tons
tons
tons
tons
Quantity
260
Site-Spec.
One-Way
Distance
(miles)
700
Empty Return Trips
Number of
Trips
20
20
Total One-
Way Miles
14000
14000
Mode of Transport.
Truck Heavy Load (gptm)
Truck A (< 5 tons)
Fuel Type
Diesel
Diesel
Fuel Use Rate
0.011
8.5
Total Fuel Use
2002
1647.058824
Notes
* Leave site-specific one-way miles blank if value is not known and a default will be used for
calculating total-one way miles
On-Site Water Usage (1000 x gallons)
gptm = gallons per ton-mile
Fate of On-Site Water Usage (1000 x gallons)
Resource Type
Potable water
Potable water
Water table drawdown (ft)
Quantity
186.6226
12250
Use of Resource
associated with chemical blending
potable water use on-site from utility bills
Discharge Location
Discharge to surface water
Discharge to surface water
Notes
If potable water is trucked to site, use "potable water" in materials section to calculate fuel use. Only the potable water use from the On-Site Water Use Section will be input into the Summary tab. It is assumed that the quantity of potable water in the Materials section is
accounted for in in the On-Site Water Use Section.
Miscellaneous Emissions and Reductions
Item
Other HAP emissions
Other GHG emissions
Other GHG reductions
Other NOx reductions
Other SOx reductions
Other PM reductions
Quantity
Activity or Notes
On-Site Renewable Energy Generation
This workbook is for testing and research purposes only. It does not represent EPA guidance or a requirement.
For more information contact: scheuermann.karen@epa.gov orpachon.carlos@epa.gov.
Item
Photovoltaic (kWh)
Renewable Energy #1 (kWh)
Renewable Energy #2 (kWh)
Quantity
Activity or Notes
Purchased Renewable Energy (including Renewable Energy Certificates "RECs")
Item
Purchased from Utility (kWh)
RECs (kWh)
Quantity Activity or Notes
875900 RECs, New Jersey area (eGRID non-base load)
-------�
Vineland Footprint Analysis
General Scope
Input for Long-Term Groundwater Monitoring
Typical Scope Items
Green Remediation - Inventory of Energy, Material, Waste, and Other Remedy Aspects
Existing Pump and Treat System
Useful Information
Long-term groundwater monitoring
Labor, Mobilizations, Mileage, and Fuel
Participant
sampling technicians
Crew Size
2
Number of
Days
50
Hours
Worked Per
Day
8
Total Hours
Worked
800
Trips to Site
50
Roundtrip
Miles to Site
40
Mode of Transport.
Light-Duty Truck
Fuel Type
Gasoline
Total Miles
Traveled
2000
Miles Per
Gallon
15
Total Fuel
Used
133.3
Activity or Notes
Equipment Use, Mobilization, and Fuel Usage
Equipment Type
Generator
HP
4
Load
Factor
0.51
Equip. Fuel
Type
Gasoline
Gallons
Fuel Used
per Hour
0.11628
Total Hours
Operated
50
Gallons Fuel
Used
On-Site
5.814
Trips to Site
Roundtrip
Miles to Site
Total Miles
Transported
Transport Fuel
Type
Miles per
Gallon
Gallons Fuel
Used for
Transport.
Activity or Notes
two 2HP gas power generators operated 8 hours per day
Electricity Usage
Equipment Type
Equip, with kW rating
Equip, with kW rating
Direct kWh info.
HP
% Full
Load
Efficiency
Totals
Electrical
Rating (kW)
0
Hours Used
Energy Used
(kWh)
0
Notes
Natural Gas Usage
Equipment Type
Power Rating
(btu/hr)
Efficiency
Totals
Total Hours
Used
Btus
Required
0
Total
Therms
Used
0
Notes
If heat load is known instead of unit power rating, then enter power rating as 125% of heat load and choose 80% for efficiency.
Cells shaded in dark gray are not relevant to the equipment types noted
"Direct kWh info" refers to total electricity usage calculated or provided elsewhere (e.g., an electric meter).
This workbook is for testing and research purposes only. It does not represent EPA guidance or a requirement.
For more information contact: scheuermann.karen@epa.gov or pachon.carlos@epa.gov.
-------�
Vineland Footprint Analysis
Materials Usage
Input for Long-Term Groundwater Monitoring
Material Type
Unit
Quantity
Site-Spec.
One- Way
Distance
(miles)*
Empty Return Trips
Number of
Trips
Total One-
Way Miles
Mode of Transport.
Truck A (< 5 tons)
Fuel Type
Fuel Use Rate
(mpgorgptm)
Total Fuel Use
Notes
Green Remediation - Inventory of Energy, Material, Waste, and Other Remedy Aspects
Existing Pump and Treat System
Laboratory Analysis
Parameter and Notes
Arsenic
SVOCs
RGBs/Pesticides
Metals
Other
Other
Other
Other
Other
Other
Unit Cost
15
Totals
Number of
Samples
120
120
Total Cost
1800
0
0
0
0
0
0
0
0
0
1800
* Leave site-specific one-way miles blank if value is not known and a default will be used for
Waste Generation
Fuel Use Rate reported in miles per gallon (mpg) and gallons per ton-mile (gptm)
Waste Type
Unit
tons
tons
tons
tons
tons
Quantity
Site-Spec.
One-Way
Distance
(miles)
Empty Return Trips
Number of
Trips
Total One-
Way Miles
Mode of Transport.
Truck A (< 5 tons)
Fuel Type
Fuel Use Rate
Total Fuel Use
Notes
* Leave site-specific one-way miles blank if value is not known and a default will be used for
calculating total-one way miles
On-Site Water Usage (1000 x gallons)
gptm = gallons per ton-mile
Fate of On-Site Water Usage (1000 x gallons)
Resource Type
Water table drawdown (ft)
Quantity
Use of Resource
Discharge Location
Notes
If potable water is trucked to site, use "potable water" in materials section to calculate fuel use. Only the potable water use from the On-Site Water Use Section will be input into the Summary tab. It is assumed that the quantity of potable water in the Materials section is
accounted for in in the On-Site Water Use Section.
Miscellaneous Emissions and Reductions
Item
Other HAP emissions
Other GHG emissions
Other GHG reductions
Other NOx reductions
Other SOx reductions
Other PM reductions
Quantity
Activity or Notes
On-Site Renewable Energy Generation
Item
Photovoltaic (kWh)
Renewable Energy #1 (kWh)
Renewable Energy #2 (kWh)
Quantity
Activity or Notes
Purchased Renewable Energy (including Renewable Energy Certificates "RECs")
This workbook is for testing and research purposes only. It does not represent EPA guidance or a requirement.
For more information contact: scheuermann.karen@epa.gov or pachon.carlos@epa.gov.
Item
Purchased from Utility (kWh)
RECs (kWh)
Quantity
Activity or Notes
-------�
Vineland Footprint Analysis
Green Remediation - Inventory of Energy, Material, Waste, and Other Remedy Aspects
Existing Pump and Treat System
Summary
Level
Item
Labor and Travel
Hours worked (hrs)
Heavy equip, operating hours (hrs)
Passenger trips to site (trips)
Passenger vehicle miles (miles)
Heavy equip, trips to site (trips)
Heavy equip, transport miles (miles)
Materials transport trips (trips)
Materials transport miles (miles)
Waste transport trips (trips)
Waste transport miles (miles)
Energy
On-site
Gasoline (gallons)
£85 (gallons)
Diesel (gallons)
B20 (gallons)
Photovoltaic (MWh)
Other Renewable Energy #1
Other Renewable Energy #2
Off-site
Gasoline (gallons)
£85 (gallons)
Diesel (gallons)
B20 (gallons)
Total Fuel
Gasoline (gallons)
£85 (gallons)
Diesel (gallons)
B20 (gallons)
Electricity Demand (kW)
Electricity Usage (MWh)
Purchased Renewable Electricity (MWh)
Natural gas usage (therms)
1
2
3
0
0
0
0
0
0
0
0
0
0
0
0
extraction
48
8
4
320
0
0
4
1080
0
0
0
0
10.2
0
0
0
0
26.7
0
127
0
26.7
0
137.2
0
0
441.6
441.6
0
O&M
7280
0
910
18200
0
0
168
6720
40
28000
0
0
0
0
0
0
0
1213.3
0
4524.058824
0
1213.3
0
4524.058824
0
0
875.9
875.9
23657
LTM
800
50
50
2000
0
0
0
0
0
0
5.814
0
0
0
0
0
0
133.3
0
0
0
139.114
0
0
0
0
0
0
0
Total
8128
58
964
20520
0
0
172
7800
40
28000
5.814
0
10.2
0
0
0
0
1373.3
0
4651.058824
0
1379.114
0
4661.258824
0
0
1317.5
1317.5
23657
This workbook is for testing and research purposes only. It does not represent EPA guidance or a requirement.
For more information contact: scheuermann.karen@epa.gov or pachon.carlos@epa.gov.
-------�
Vineland Footprint Analysis
Green Remediation - Inventory of Energy, Material, Waste, and Other Remedy Aspects
Existing Pump and Treat System
Summary
Level
Item
Materials
Asphalt (tons)
Bentonite (tons)
Borrow (tons)
Cement (tons)
Cheese whey (Ibs)
Concrete (tons)
Emulsified vegetable oil (Ibs)
GAC: regenerated (Ibs)
GAC: virgin coal-based (Ibs)
GAC: virgin coconut-based (Ibs)
Gravel/sand/clay (tons)
HOPE (Ibs)
Hydrochloric acid (30%, SG = 1.18) (Ibs)
Hydrogen peroxide (50%, SG=1.19) (Ibs)
Hydroseed (Ibs)
Lime (Ibs)
Molasses (Ibs)
Nitrogen fertilizer (Ibs)
Other 1 - Ferric chloride (Ibs)
Other 2 ()
Other 3 -acetic acid (Ibs)
Other 4 ()
Others ()
Phosphorus fertilizer (Ibs)
Polymer (Ibs)
Potable water (gals)
Potassium permanganate (Ibs)
PVC (Ibs)
Sequestering agent (Ibs)
Sodium hydroxide (dry bulk) (Ibs)
Stainless steel (Ibs)
Steel (Ibs)
Trees: root balls (each)
Trees: whips (each)
Waste
Non-hazardous landfill (tons)
Hazardous landfill (tons)
Recycling facility (tons)
Hauled to POTW (gals x 1000)
Incineration (tons)
Location for reuse (tons)
Water Use
Potable water (gals x 1000)
Extracted GW #1 (gals x 1000)
Extracted GW #2 (gals x 1000)
Surface water (gals x 1000)
Reclaimed water (gals x 1000)
Storm water (gals x 1000)
1
2
3
0
0
0
0
0
0
0
0
0
0
0
0
extraction
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
4927.7076
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
99
0
0
0
0
0
O&M
0
0
0
0
0
0
0
0
0
0
0
0
0
98000
0
0
0
0
197000
0
0
0
0
0
33485.1
186622.5938
0
0
0
256000
0
0
0
0
0
260
0
0
0
12436.62259
0
0
0
0
0
LTM
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Total
0
0
0
0
0
0
0
0
0
0
0
0
0
98000
0
0
0
0
197000
0
4927.7076
0
0
0
33485.1
186622.5938
0
0
0
256000
0
0
0
0
0
260
0
0
0
12535.62259
0
0
0
0
0
This workbook is for testing and research purposes only. It does not represent EPA guidance or a requirement.
For more information contact: scheuermann.karen@epa.gov or pachon.carlos@epa.gov.
-------�
Vineland Footprint Analysis
Green Remediation - Inventory of Energy, Material, Waste, and Other Remedy Aspects
Existing Pump and Treat System
Summary
Level
Item
Water Discharge
Discharge to surface water (gals x 1000)
Reinjected to aquifer (gals x 1000)
Discharge to POTW (gals x 1000)
Discharge to atmosphere (gals x 1000)
Public Use (gals x 1000)
Irrigation (gals x 1000)
Industrial process water (gals x 1000)
Other beneficial use (gals x 1000)
Laboratory Analysis
Total samples (samples)
Total cost ($)
Other
Other HAP emissions (Ibs)
Other GHG emissions (Ibs)
Other GHG reductions (Ibs)
Other NOx reductions (Ibs)
Other SOx reductions (Ibs)
Other PM reductions (Ibs)
1
2
3
0
0
0
0
0
0
0
0
0
0
0
0
extraction
0
99
0
0
0
0
0
0
0
0
0
0
0
0
0
0
O&M
12436.62259
0
0
0
0
0
0
0
1300
19500
0
0
0
0
0
0
LTM
0
0
0
0
0
0
0
0
120
1800
0
0
0
0
0
0
Total
12436.62259
99
0
0
0
0
0
0
1420
21300
0
0
0
0
0
0
This workbook is for testing and research purposes only. It does not represent EPA guidance or a requirement.
For more information contact: scheuermann.karen@epa.gov or pachon.carlos@epa.gov.
-------�
Lookup Table
Mode of Transport. For
Personnel
Airplane
Bus
Car
Heavy-Duty Truck
Light-Duty Truck
Train
Vehicle (other)
Gasoline
mpg
ERROR
ERROR
20
10
15
ERROR
NO DATA
E85
mpg
ERROR
ERROR
14.6
7.3
10.95
ERROR
NO DATA
Diesel
mpgorpmpg
44.7
95.6
22.3
11.2
16.7
59.1
NO DATA
B20
mpg
ERROR
ERROR
20.6
10.3
15.4
ERROR
NO DATA
- Fuel usage for buses, airplanes, and trains are for passenger miles per gallon (pmpg)
-Airplane/jet fuel calculated as diesel for simplicity and due to similarities between kerosene and diesel
- Typical gasoline fuel efficiencies from from www.fueleconomy.gov
- E85 efficiences based on higher heating values (mmBtu per barrel) of 5.218 mmBtu (gasoline) and 3.539 for (ethanol),
Climate Leaders Direct Emissions from Mobile Sources
- Diesel car and truck efficiences based on higher heating values (mmBtu per barrel) of 5.218 mmBtu (gasoline) and 5.825 for
(diesel), Climate Leaders Direct Emissions from Mobile Sources
- B20 car and truck efficiences based on higher heating values of 5.825 mmBtu per barrel (diesel, Climate Leaders) and 127,960
btu per gallon (biodiesel, Alternative Fuels & Advanced Vehicles Data Center, www.afdc.energy.gov)
- Diesel airplane, bus, and train efficiences from converting average CO2 emissions Climate Leaders from Commuting, Business
Travel and Product Transport to diesel usage assuming 22.5 Ibs ofCO2 per gallon of diesel.
Fuel Type for Equipment
Transport
B20
Diesel
mpg
7.09
7.2
B20 efficiency based on higher heating value of
127,960 btu per gallon for biodiesel (Alternative
Fuels & Advanced Vehicles Data Center,
www.afdc.energy.gov.
Fuel Type for
Equip. Use
B20
Diesel
E85
Gasoline
Gals, per HP-hr
0.052
0.051
0.078
0.057
Fuel consumption based on thermal
efficiency of 36% for diesel and 38%
for gasoline.
Mode of Transport. For
Materials
Train (gptm)
Truck A (< 5 tons)
Trucks (5-15 tons)
Truck C (15+ tons)
Truck Heavy Load (gptm)
Truck Light Load (gptm)
rate
(mpg or gptm)
0.0024
8.5
7.2
5.92
0.011
0.024
Equipment Type
Asphalt paver
Backhoe
Concrete paving machine
Dozer (large)
Dozer (small)
Drilling- direct push
Drilling - large rig (e.g., CME-75)
Drilling - medium rig (e.g., CME-55)
Dump truck
Excavator (large)
Excavator (medium)
Excavator/hoe (small)
Generator
Grader
Grout pump
Hydroseeder
Integrated tool carrier
Loader
Loader (small)
Mobile laboratory
Mowers
Other
Riding trencher
Roller
Rotary-screw air compressor (250 cfm)
Skid-steer (small)
Telescopic handler
Tractor mower
Water truck
Default Load
0.62
0.57
0.53
0.55
0.55
0.75
0.75
0.75
0.57
0.57
0.57
0.57
0.51
0.61
0.51
0.62
0.43
0.55
0.55
0.5
0.6
0.5
0.75
0.56
0.48
0.55
0.43
0.6
0.57
Typical HP
Default eguipment loads obtained from Road Construction Emissions Model Version 6.3.2,
Sacramento Air Quality Management District. Generators and grout pumps considerd "other general
industrial eguipment".
mpg = miles per gallon, gptm = gallons per ton-mile
Rail fuel usage from Climate Leaders, Direct Emissions from Mobile Sources
Truck usages from Climate Leaders, Direct Emissions from Mobil Sources and Effects of
Payload on the Fuel Consumption of Trucks, Dept. for Transportation (Great Britain),
December 2007. Truck heavy load based on Truck C carrying 15 tons. Truck light load
based on Truck A carrying 5 tons.
This workbook is for testing and research purposes only. It does not
represent EPA guidance or a requirement.
For more information contact:
scheuermann.karen@epa.gov or pachon.carlos@epa.gov.
-------�
Lookup Table (continued)
Materials
Asphalt
Bentonite
Borrow
Cement
Cheese whey
Concrete
Emulsified vegetable oil
GAC: regenerated
GAC: virgin coal-based
GAC: virgin coconut-based
Gravel/sand/clay
HOPE
Hydrochloric acid (30% SG = 1.18)
Hydrogen peroxide (50%, SG=1.19)
Hydroseed
Lime
Molasses
Nitrogen fertilizer
Other 1 - Ferric chloride
Other 2
Other 3 - acetic acid
Other 4
Other 5
Phosphorus fertilizer
Polymer
Potable water
Potassium permanganate
PVC
Sequestering agent
Sodium hydroxide (dry bulk)
Stainless steel
Steel
Trees: root balls
Trees: whips
Units
tons
tons
tons
tons
Ibs
tons
Ibs
Ibs
Ibs
Ibs
tons
Ibs
Ibs
Ibs
Ibs
Ibs
Ibs
Ibs
Ibs
Ibs
Ibs
Ibs
gals
Ibs
Ibs
Ibs
Ibs
Ibs
Ibs
each
each
Conv. to tons
1
1
1
1
0.0005
1
0.0005
0.0005
0.0005
0.0005
1
0.0005
0.0005
0.0005
0.0005
0.0005
0.0005
0.0005
0.0005
0.0005
0.0005
0.0005
0.00417
0.0005
0.0005
0.0005
0.0005
0.0005
0.0005
NA
NA
Default
One-Way
Distance from
Source to Site
(miles)
30
1000
30
30
1000
30
1000
1000
1000
1000
30
1,000
500
500
500
500
500
500
500
0
500
0
0
500
1000
25
1000
1000
1000
500
500
500
500
1000
Miles are one-way miles. In most cases a empty initial or return trip needs to be added.
Miles should be from manufacturer to supplier to site.
This workbook is for testing and research purposes only. It does not
represent EPA guidance or a requirement.
For more information contact:
scheuermann.karen@epa.gov or pachon.carlos@epa.gov.
Waste Disposal Facility
Non-hazardous landfill
Hazardous landfill
Recycling facility
Hauled to POTW
Incineration facility
Location for reuse
Default One-Way Distance
(Miles)
25
500
100
50
50
50
Notes
-------�
TABLE G-l. SUMMARY OF ELECTRICITY USAGE
EQUIPMENT
Extraction System
RW-1
RW-2
RW-2a
RW-2b
RW-3
RW-4
RW-5
RW-6
RW-7
RW-8
RW-9
RW-9a
RW-10
RW-11
RW-12
RW-13
Treatment System
Chem. Feed pumps*
EQtank pump
Oxidation tank mixer
Coag. Tank mixer
DAF #3 Floe. Mixer 1
DAF #3 Floe. Mixer 2
DAF #4 Floe. Mixer 1
DAF #4 Floe. Mixer 2
DAF recirc. Pump
Residuals sump mixer
Filter feed mixer
Filter feed pump
Effluent pump
Air compressor 1
Air compressor 2
Thickener skimmer
Thickener overflow
Centrifuge**
Building lighting***
Building HVAC****
Controls****
Plug loads****
SOF
UNITS
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
1
POWER
RATING
(HP)
PER UNIT
7.5
7.5
5
5
5
2
2
5
2
5
0
7.5
7.5
7.5
7.5
7.5
6.67
40
3
3
5
0.5
5
0.5
7.5
1
3
28
20
10
10
0.75
17.5
12
30
3
POWER
RATING
(KW)
PER UNIT
5.6
5.6
3.7
3.7
3.7
1.5
1.5
3.7
1.5
3.7
0.0
5.6
5.6
5.6
5.6
5.6
5.0
29.8
2.2
2.2
3.7
0.4
3.7
0.4
5.6
0.7
2.2
20.9
14.9
7.5
7.5
0.6
13.1
9.0
22.4
2.2
10.0
VFD
SETTING
%LOAD
28%
83%
95%
100%
100%
85%
100%
100%
95%
98%
0%
100%
90%
46%
92%
21%
N/A
20%
N/A
N/A
50%
50%
50%
50%
N/A
N/A
N/A
75%
100%
N/A
N/A
N/A
N/A
N/A
N/A
N/A
N/A
LOAD
FACTOR
7%
67%
92%
108%
108%
72%
108%
108%
95%
101%
0%
108%
81%
13%
84%
3%
80%
3%
80%
80%
17%
17%
17%
17%
80%
80%
80%
50%
108%
80%
80%
80%
80%
80%
80%
100%
100%
EFFICIENCY
75%
75%
75%
75%
75%
70%
70%
75%
70%
75%
75%
75%
75%
75%
75%
75%
HOURS OF
OPERATION
PER YEAR
1752
7884
7884
7884
7008
5256
4380
8322
7008
8322
0
7884
8322
876
8322
876
EXTRACTION SYSTEM
65%
80%
75%
75%
75%
75%
75%
75%
75%
75%
75%
80%
75%
75%
75%
65%
75%
75%
75%
100%
100%
8760
8760
8760
8760
8760
8760
8760
8760
8760
8760
8760
8760
8760
6300
6300
8760
876
2600
4368
8760
876
Treatment System Subtotal
Total
KWH PER
YEAR
956
39,564
36,148
42,161
37,476
8,094
10,038
44,503
14,230
41,886
0
63,242
50,287
848
51,981
202
441,616
53,647
8,713
20,912
20,912
7,261
726
7,261
726
52,280
6,971
20,912
113,521
187,382
50,131
50,131
6,032
12,199
24,827
98,715
104,273
19,605
8,760
875,896
1,317,513
%OF
TOTAL
ELEC. USE
0.1%
3.0%
2.7%
3.2%
2.8%
0.6%
0.8%
3.4%
1.1%
3.2%
0.0%
4.8%
3.8%
0.1%
3.9%
0.0%
33.5%
4.1%
0.7%
1.6%
1.6%
0.6%
0.1%
0.6%
0.1%
4.0%
0.5%
1.6%
8.6%
14.2%
3.8%
3.8%
0.5%
0.9%
1.9%
7.5%
7.9%
1.5%
0.7%
66.5%
100.0%
-------�
Green Remediation Footprint Analysis Spreadsheets
VinelondChemicalSuperfundSite, Vinelond, NJ, P&T-P&T
Level 1- Extraction
On-Site
Electricity Generation
Transportation
OtherOff-Site
Extraction Total
Level2-O&M
On-Site
Electricity Generation
Transportation
OtherOff-Site
O&M Total
Level3-LTM
On-Site
Electricity Generation
Transportation
OtherOff-Site
LTM Total
Level 4 - Not Used
On-Site
Electricity Generation
Transportation
OtherOff-Site
Wot Used Total
Level 5 - Not Used
On-Site
Electricity Generation
Transportation
OtherOff-Site
Wot Used Total
Level 6- Not Used
On-Site
Electricity Generation
Transportation
OtherOff-Site
Wot Used Total
Total
Totals For Parameters Used, Extracted, Emitted, or Generated - P&T
Energy
Used
Mbtu
1,508,599.
3,444,480.
20,964.
211,423.
5,185,466.
5,426,118.
6,832,020.
779,293.
4,115,178.
17,152,609.
721.
0
16,529.
14,603.
31,853.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
22,369,928.
Grid Electricity
Used
MWh
442.
26.
0
53.
521.
876.
53.
0
420.
1,349.
0
0
0
1.
1.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1,871.
All Water
Used
gal x 1000
99.
396,557.
0
108.
396,764.
12,437.
786,558.
0
2,818.
801,813.
0
0
0
1.
1.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1,198,578.
Potable Water
Used
gal x 1000
99.
0
0
0
99.
12,436.6
0
0
0
12,436.6
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
12,535.6
Groundwater
Extracted
gal x 1000
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
CO2e
Emitted
Ibs
230.
185,994.
3,381.
85,990.
275,595.
288,615.
368,913.
125,572.
987,539.
1,770,639.
114.
0
2,613.
2,412.
5,139.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
2,051,373.
NOx
Emitted
Ibs
2.
1,614.
25.
212.
1,853.
237.
3,202.
902.
3,261.
7,602.
1.
0
15.
10.
26.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
9,481.
SOx
Emitted
Ibs
0
1,509.
1.
634.
2,144.
0
2,993.
29.
3,986.
7,008.
0
0
1.
9.
10.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
9,162.
PM
Emitted
Ibs
0
336.
0
52.
388.
18.
666.
16.
879.
1,579.
0
0
0
1.
1.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1,968.
Solid Waste
Generated
tons
0
0
0
0
0
0
0
0
6.3
6.3
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
6.3
Haz. Waste
Generated
tons
0
0
0
0
0
260.
0
0
0.167
260.167
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
260.167
Air Toxics
Emitted
Ibs
0.0001
132.48
0.0017
22.6737
155.1555
0.1987
262.77
0.0708
110.3646
373.4041
0.0002
0
0.0052
0.2563
0.2617
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
528.8213
Mercury
Released
Ibs
0
0.0958272
0
0.001238332
0.097065532
0.000615082
0.1900703
0
0.061643706
0.252329088
0
0
0
0.000026945
0.000026945
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.349421565
Lead
Released
Ibs
0
-0.0565248
0
0.009339962
-0.047184838
0.00118285
-0.1121152
0
0.075675199
-0.035257151
0
0
0
0.000459051
0.000459051
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
-0.081982938
Dioxins
Released
Ibs
0
0.000000052992
0
0.000000012763
0.000000065755
0
0.000000105108
0
0.000000054352
0.00000015946
0
0
0
0.000000000146
0.000000000146
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.000000225361
This workbook is for testing and research purposes only. It does not represent EPA guidance or a requirement.
For more information contact: scheuermann. karen @epa. gov or pachon. carlos(5>epa. gov.
-------�
Green Remediation Footprint Analysis Spreadsheets
Vineland Chemical SuperfundSite, Vineland, NJ, P&T-P&T
Totals
ON-SITE
Energy
Diesel (on-site use)
Gasoline (on-site use)
Natural gas (on-site use)
Electricity (on-site use)
Photovoltaic (on-site system)
Other Energy 2
Other Energy 3
Water
Groundwater Extracted On-site
Potable Water Used On-site
Other On-Site Water 1
Other On-Site Water 2
Other On-Site Water 3
Waste Generation
On-Site Solid Waste Generation
On-Site Solid Waste Disposal
On-Site Hazardous Waste Generation
On-Site Hazardous Waste Disposal
Other
On-site process emissions (HAPs)
On-site process emissions (GHGs)
On-site GHG storage
On-site NOx reduction
On-site SOx reduction
On-site PM reduction
Other 1
Other 2
ON-SITE TOTAL
ELECTRICITY GENERATION
Electricity production
Purchased Renewa ble Electricity
TRANSPORTATION
Diesel (off-site use)
Gasoline (off-site use)
Natural gas (off -site use)
Other Transportation 1
Other Transportation 2
Other Transportation 3
Other Transportation 4
Other Transportation 5
TRANSPORTATION TOTAL
gal
gal
ccf
MWh
MWh
TBD
TBD
gal x 1000
gal x 1000
gal x 1000
gal x 1000
gal x 1000
ton
ton
Ibs
Ibs C02e
Ibs C02e
Ibs
Ibs
Ibs
TBD
TBD
MWh
MWh
gal
gal
ccf
TBD
TBD
TBD
0
0
Quantity
Used
10.2
5.814
23657
1317.5
0
0
0
0
12535.623
0
0
0
0
0
260
0
0
0
0
0
0
0
0
0
1317.5
1317.5
4651.0588
1373.3
0
0
0
0
0
0
All Levels - Parameters Used, Extracted, Emitted, or Generated - P&T
Energy
Conv.
Factor
139
124
103
3413
37922
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
7800
0
139
124
103
0
0
0
0
0
0
Used
Mbtu
22,369,928.
1,418.
721.
2,436,671.
4,496,628.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
6,935,438.
10,276,500.
0
646,497.
170,289.
0
0
0
0
0
0
816,786.
Grid Electricity
Conv.
Factor
0
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.06
0
0
0
0
0
0
0
0
0
0
Used
MWh
1,871.
0
0
0
1,318.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1,318.
79.
0
0
0
0
0
0
0
0
0
0
All Water
Conv.
Factor
0
0
0
0
0
0
0
1
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0
900
-2
0
0
0
0
0
0
0
0
0
Used
gal x 1000
1,198,579.
0
0
0
0
0
0
0
0
12,536.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
12,536.
1,185,750.
-2,635.
0
0
0
0
0
0
0
0
0
Potable Water
Conv.
Factor
0
0
0
0
0
0
0
0
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Used
gal x 1000
12,535.6
0
0
0
0
0
0
0
0
12,535.6
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
12,535.6
0
0
0
0
0
0
0
0
0
0
0
Groundwater
Conv.
Factor
0
0
0
0
0
0
0
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Extracted
gal x 1000
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
C02e
Conv.
Factor
22.5
19.6
12.2
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
-1
0
0
0
0
0
0
2400
-1979
22.5
19.6
12.2
0
0
0
0
0
0
Emitted
Ibs
2,051,374.
230.
114.
288,615.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
288,959.
3,162,000.
-2,607,093.
104,649.
26,917.
0
0
0
0
0
0
131,566.
NOx
Conv.
Factor
0.17
0.11
0.01
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
-1
0
0
0
0
0
6.7
-3.045
0.17
0.11
0.01
0
0
0
0
0
0
Emitted
Ibs
9,480.
2.
1.
237.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
240.
8,827.
-4,012.
791.
151.
0
0
0
0
0
0
942.
SOx
Conv.
Factor
0.0054
0.0045
6E-06
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
-1
0
0
0
0
15
-11.58
0.0054
0.0045
6E-06
0
0
0
0
0
0
Emitted
Ibs
9,162.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
19,763.
-15,261.
25.
6.
0
0
0
0
0
0
31.
PM
Conv.
Factor
0.0034
0.0005
0.0008
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
-1
0
0
0
1.7
-0.94
0.0034
0.0005
0.0008
0
0
0
0
0
0
Emitted
Ibs
1,969.
0
0
18.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
18.
2,240.
-1,238.
16.
1.
0
0
0
0
0
0
17.
Solid Waste
Conv.
Factor
0
0
0
0
0
0
0
0
0
0
0
0
1
0
0
0
0
0
0
0
0
0
0
0
0
0.0009
-9E-04
0
0
0
0
0
0
0
0
0
Generated
tons
6.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1.
-1.
0
0
0
0
0
0
0
0
0
Haz. Waste
Conv.
Factor
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Generated
tons
260.167
0
0
0
0
0
0
0
0
0
0
0
0
0
0
260.
0
0
0
0
0
0
0
0
0
260.
0
0
0
0
0
0
0
0
0
0
0
Air Toxics
Conv.
Factor
5E-06
4E-05
8E-06
0
0
0
0
0
0
0
0
0
0
0
0
0
1
0
0
0
0
0
0
0
0
0.7
-0.4
5E-06
4E-05
8E-06
0
0
0
0
0
0
Emitted
Ibs
528.8214
0.0001
0.0002
0.1987
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.199
922.25
-527.
0.0242
0.0536
0
0
0
0
0
0
0.0778
Mercury
Conv.
Factor
0
0
3E-08
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.0002
-2E-05
0
0
3E-08
0
0
0
0
0
0
Released
Ibs
0.349421563
0
0
0.000615082
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.000615082
0.3162
-0.0303025
0
0
0
0
0
0
0
0
0
Lead
Conv.
Factor
0
0
5E-08
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
4E-05
-2E-04
0
0
5E-08
0
0
0
0
0
0
Released
Ibs
-0.081982938
0
0
0.00118285
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.00118285
0.055335
-0.223975
0
0
0
0
0
0
0
0
0
Dioxins
Conv.
Factor
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
4E-10
-2E-10
0
0
0
0
0
0
0
0
0
Released
Ibs
0.000000225362
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.0000004743
-0.0000003162
0
0
0
0
0
0
0
0
0
-------�
Green Remediation Footprint Analysis Spreadsheets
Vineland Chemical SuperfundSite, Vineland, NJ, P&T-P&T
OFF-SITE OTHER
Materials
Asphalt
Bentonite
Borrow (clean soil)
Cement
Cheese Whey
Concrete
Diesel Produced
Emulsified vegetable oil
GAC: regenerated
GAC: virgin coal-based
GAC: virgin coconut-based
Gasoline Produced
Gravel/sand/clay
HOPE
Hydrochloric acid (30%, SG = 1.18)
Hydrogen peroxide (50%, SG=1.19)
Hydroseed
Lime
Molasses
Natural Gas Produced
Nitrogen fertilizer
Other Material #1 - Ferric Chloride
(salt)
Other Material #2 - Mulch
Other Material #3 - acetic acid
Other Material #4 - guar gum
Other Material #5
Phosphorus fertilizer
Polymer
Potable Water
Potassium permanganate
PVC
Sequestering agent
Sodium hydroxide (dry bulk)
Stainless Steel
Steel
Tree: root ball
Tree: whip
Off-Site Services
Off-site waste water treatment
Off-site Solid Waste Disposal
Off-site Haz. Waste Disposal
Off-site Laboratory Analysis
Other 1
Other 2
Other3
Other 4
Other 5
Other
Potable Water Transported
Electricity transmission
Other 1
Other 2
Other3
OFF-SITE OTHER TOTAL
tons
tons
tons
dry-ton
Ibs
tons
gal
Ibs
Ibs
Ibs
Ibs
gal
ton
Ib
Ibs
Ibs
Ibs
Ibs
Ibs
ccf
Ibs
Ibs
cy
Ib
Ib
TBD
Ibs
Ibs
gal x 1000
Ibs
Ibs
Ibs
Ibs
Ib
Ib
trees
trees
gal x 1000
ton
ton
$
TBD
TBD
TBD
TBD
TBD
gal x 1000
MWh
TBD
TBD
TBD
Quantity
Used
0
0
0
0
0
0
4661.2588
0
0
0
0
1379.114
0
0
0
98000
0
0
0
23657
0
197000
0
4927.7076
0
0
0
33485.1
12535.623
0
0
0
256000
0
0
0
0
0
0
260
21300
0
0
0
0
0
12535.623
1317.5
0
0
0
All Levels - Parameters Used, Extracted, Emitted, or Generated - P&T
Energy
Conv.
Factor
0
55
15.75
4100
1.87
3019
18.5
3.6
9.6
10.8
0
21
55
31
0
4.95
0.049
0
1.31
5.2
16.2
2.31
0
5.2
0.91
0
3.39
15.39
9.2
29.22
22
0
6.6
11.6
4.4
3.7
0
15
160
176
6.49
0
0
0
0
0
7.4
410
0
0
0
0
Used
Mbtu
0
0
0
0
0
0
86,233.
0
0
0
0
28,961.
0
0
0
485,100.
0
0
0
123,016.
0
455,070.
0
25,624.
0
0
0
515,336.
115,328.
0
0
0
1,689,600.
0
0
0
0
0
0
45,760.
138,237.
0
0
0
0
0
92,764.
540,175.
0
0
0
4,341,204.
Grid Electricity
Conv.
Factor
0
0.0027
6E-05
0.13
0
0.096
0.0006
6E-05
0.0004
5E-05
0
0.0006
0.0027
0.0003
0
0.0006
1E-07
0
5E-06
0.0003
2E-05
0.0003
0
2E-05
5E-05
0
7E-05
0.0023
0.0004
0.0016
0.0006
0
0.0003
0.0006
0.0002
2E-06
0
0.0007
0.0077
0.0085
0.0004
0
0
0
0
0
0.0006
0.12
0
0
0
0
Used
MWh
0
0
0
0
0
0
3.
0
0
0
0
1.
0
0
0
59.
0
0
0
6.
0
67.
0
0
0
0
0
75.
6.
0
0
0
82.
0
0
0
0
0
0
2.
7.
0
0
0
0
0
8.
158.
0
0
0
474.
All Water
Conv.
Factor
0
0.13
8E-05
0.41
0
0.34
0.0008
2E-05
0.0064
0
0
0.0008
0.13
0.0023
0
0.019
0.0001
0
9E-05
8E-05
0
0.0003
0
0
0.0001
0
0
0.0018
0.021
0.003
0.0069
0
0.0012
0.0023
0.0006
0.004
0
0.0029
0.15
0.165
0.0007
0
0
0
0
0
0.0013
0.24
0
0
0
0
Used
gal x 1000
0
0
0
0
0
0
4.
0
0
0
0
1.
0
0
0
1,862.
0
0
0
2.
0
53.
0
0
0
0
0
60.
263.
0
0
0
294.
0
0
0
0
0
0
43.
14.
0
0
0
0
0
16.
316.
0
0
0
2,928.
Potable Water
Conv.
Factor
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Used
gal x 1000
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Groundwater
Conv.
Factor
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Extracted
gal x 1000
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
C02e
Conv.
Factor
0
6.7
2.52
1800
1.1
1322
2.7
3.51
2
4.5
0
4.4
6.7
1.9
0
1.35
0.0046
0
0.4
2.2
1.5
0.41
0
0.67
1
0
0.35
2.72
5
4.5
2.6
0
1.37
3.4
1.1
0.6
0
4.4
25
27.5
1
0
0
0
0
0
0.9948
184.8
0
0
0
0
Emitted
Ibs
0
0
0
0
0
0
12,585.
0
0
0
0
6,068.
0
0
0
132,300.
0
0
0
52,045.
0
80,770.
0
3,302.
0
0
0
91,079.
62,678.
0
0
0
350,720.
0
0
0
0
0
0
7,150.
21,300.
0
0
0
0
0
12,471.
243,474.
0
0
0
1,075,942.
NOx
Conv.
Factor
0
0.033
0.0176
3.6
0.0083
2.6
0.0064
0.0265
0.025
0.12
0
0.008
0.033
0.0032
0
0.0087
3E-06
0
0.003
0.0037
0.0008
0.0019
0
0.0006
0.073
0
0.0017
0.013
0.0097
0.021
0.0048
0
0.003
0.0075
0.0014
0.003
0
0.016
0.14
0.154
0.0048
0
0
0
0
0
0.0025
0.468
0
0
0
0
Emitted
Ibs
0
0
0
0
0
0
30.
0
0
0
0
11.
0
0
0
853.
0
0
0
88.
0
382.
0
3.
0
0
0
435.
122.
0
0
0
768.
0
0
0
0
0
0
40.
102.
0
0
0
0
0
32.
617.
0
0
0
3,483.
SOx
Conv.
Factor
0
0.03
0.0018
2.1
0.0099
1.5
0.013
0.031
0.015
0.074
0
0.019
0.03
0.0041
0
0.0066
5E-05
0
0.0026
0.0046
0.0174
0.0015
0
0.02
0.0068
0
0.017
0.0098
0.0059
0.016
0.0076
0
0.0048
0.012
0.0017
0.0006
0
0.015
0.075
0.0825
0.0036
0
0
0
0
0
0.0065
1.2
0
0
0
0
Emitted
Ibs
0
0
0
0
0
0
61.
0
0
0
0
26.
0
0
0
647.
0
0
0
109.
0
296.
0
99.
0
0
0
328.
74.
0
0
0
1,229.
0
0
0
0
0
0
21.
77.
0
0
0
0
0
81.
1,581.
0
0
0
4,629.
PM
Conv.
Factor
0
0.004
0.0004
0.0063
0.0002
0.0054
0.0003
0.0017
0
0
0
0.0005
0.004
0.0006
0
0.0025
3E-07
0
6E-05
7E-05
7E-05
0.0002
0
6E-05
0.0001
0
0.0001
0.001
0.016
0.0017
0.0012
0
0.0005
0.0044
0.0006
3E-05
0
0.0017
0.4
0.44
0.0004
0
0
0
0
0
0.0006
0.1128
0
0
0
0
Emitted
Ibs
0
0
0
0
0
0
2.
0
0
0
0
1.
0
0
0
245.
0
0
0
2.
0
30.
0
0
0
0
0
33.
201.
0
0
0
138.
0
0
0
0
0
0
114.
9.
0
0
0
0
0
8.
149.
0
0
0
932.
Solid Waste
Conv.
Factor
0
0
4E-08
0
0
IE-OS
4E-07
0
0
0
0
4E-07
0
4E-07
0
IE-OS
0
0
0
0
0
1E-07
0
0
0
0
0
8E-07
8E-07
1E-06
2E-06
0
2E-05
0.0006
0.0003
IE-OS
0
0.0024
8E-06
9E-06
0
0
0
0
0
0
6E-07
0.0001
0
0
0
0
Generated
tons
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
5.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
6.
Haz. Waste
Conv.
Factor
0
0
0
0
0
0
0
0
0
0
0
0
0
1E-06
0
5E-07
0
0
0
0
0
0
0
0
0
0
0
0
0
0
2E-06
0
5E-07
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Generated
tons
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.047
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.12
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.167
Air Toxics
Conv.
Factor
0
4E-07
IE-OS
0.058
0
0.043
0.0001
0
0
0
0
0.0002
4E-07
3E-06
0
0.0002
8E-07
0
0
6E-06
0.0003
5E-05
0
0.0003
IE-OS
0
5E-05
0.0004
2E-05
0.0006
0.0005
0
6E-05
0.0001
7E-05
6E-06
0
0.0006
0.0014
0.0015
0.0001
0
0
0
0
0
0.0003
0.048
0
0
0
0
Emitted
Ibs
0
0
0
0
0
0
0.5594
0
0
0
0
0.2207
0
0
0
22.54
0
0
0
0.1443
0
10.638
0
1.429
0
0
0
12.0546
0.188
0
0
0
15.872
0
0
0
0
0
0
0.4004
2.769
0
0
0
0
0
3.2392
63.24
0
0
0
133.2946
Mercury
Conv.
Factor
0
6E-11
5E-09
6E-05
0
4E-05
5E-08
0
0
0
0
9E-08
6E-11
3E-09
0
0
2E-11
0
0
2E-08
6E-09
3E-09
0
2E-09
1E-09
0
2E-09
2E-08
8E-09
4E-08
3E-07
0
2E-07
0
1E-07
2E-09
0
4E-08
1E-06
1E-06
8E-09
0
0
0
0
0
IE-OS
3E-06
0
0
0
0
Released
Ibs
0
0
0
0
0
0
0.00022374
0
0
0
0
0.000117225
0
0
0
0
0
0
0
0.000496797
0
0.000591
0
0.000008377
0
0
0
0.000770157
0.000102792
0
0
0
0.05632
0
0
0
0
0
0
0.00027742
0.00017892
0
0
0
0
0
0.000186253
0.0036363
0
0
0
0.062908981
Lead
Conv.
Factor
0
1E-09
2E-07
0.0001
0
1E-04
2E-06
0
0
0
0
2E-06
1E-09
2E-09
0
0
1E-10
0
0
9E-07
4E-08
4E-08
0
IE-OS
1E-07
0
5E-08
2E-07
7E-08
4E-07
1E-07
0
3E-08
5E-07
3E-06
6E-08
0
4E-07
8E-06
8E-06
9E-08
0
0
0
0
0
1E-07
2E-05
0
0
0
0
Released
Ibs
0
0
0
0
0
0
0.006991888
0
0
0
0
0.003034051
0
0
0
0
0
0
0
0.0212913
0
0.006895
0
0.000049277
0
0
0
0.007735058
0.000839887
0
0
0
0.0064
0
0
0
0
0
0
0.0021736
0.0018105
0
0
0
0
0
0.001376651
0.026877
0
0
0
0.085474212
Dioxins
Conv.
Factor
0
2E-16
3E-15
9E-11
0
6E-11
3E-14
0
0
0
0
3E-14
2E-16
1E-09
0
0
0
0
0
5E-14
0
3E-14
0
3E-15
6E-14
0
0
2E-13
1E-13
4E-13
7E-09
0
2E-14
2E-12
7E-12
0
0
3E-13
1E-11
1E-11
8E-14
0
0
0
0
0
2E-13
3E-11
0
0
0
0
Released
Ibs
0
0
0
0
0
0
0.00000000014
0
0
0
0
0.000000000043
0
0
0
0
0
0
0
0.000000001207
0
0.000000006304
0
0.000000000015
0
0
0
0.000000007152
0.000000001254
0
0
0
0.000000006144
0
0
0
0
0
0
0.000000003432
0.0000000016S3
0
0
0
0
0
0.000000001944
0.000000037944
0
0
0
0.000000067262
This workbook is for testing and research purposes only. It does not represent EPA guidance or a requirement.
For more information contact: scheuermann.karen@epa.gov or pachon.carlos@epa.gov.
-------�
Green Remediation Footprint Analysis Spreadsheets
Vineland Chemical SuperfundSite, Vineland, NJ, P&T-P&T
Totals
ON-SITE
Energy
Diesel (on-site use)
Gasoline (on-site use)
Natural gas (on-site use)
Electricity (on-site use)
Photovoltaic (on-site system)
Other Energy 2
Other Energy 3
Water
Groundwater Extracted On-site
Potable Water Used On-site
Other On-Site Water 1
Other On-Site Water 2
Other On-Site Water 3
Waste Generation
On-Site Solid Waste Generation
On-Site Solid Waste Disposal
On-Site Hazardous Waste Generation
On-Site Hazardous Waste Disposal
Other
On-site process emissions (HAPs)
On-site process emissions (GHGs)
On-site GHG storage
On-site NOx reduction
On-site SOx reduction
On-site PM reduction
Other 1
Other 2
ON-SITE TOTAL
ELECTRICITY GENERATION
Electricity production
Purchased Renewa ble Electricity
TRANSPORTATION
Diesel (off-site use)
Gasoline (off-site use)
Natural gas (off -site use)
Other Transportation 1
Other Transportation 2
Other Transportation 3
Other Transportation 4
Other Transportation 5
TRANSPORTATION TOTAL
gal
gal
ccf
MWh
MWh
TBD
TBD
gal x 1000
gal x 1000
gal x 1000
gal x 1000
gal x 1000
ton
ton
Ibs
Ibs C02e
Ibs C02e
Ibs
Ibs
Ibs
TBD
TBD
MWh
MWh
gal
gal
ccf
TBD
TBD
TBD
0
0
Quantity
Used
10.2
0
0
441.6
0
0
0
0
99
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
441.6
441.6
127
26.7
0
0
0
0
0
0
Level 1 (Extraction) Parameters Used, Extracted, Emitted, or Generated - P&T
Energy
Conv.
Factor
139
124
103
3413
37922
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
7800
0
139
124
103
0
0
0
0
0
0
Used
Mbtu
5,185,466.
1,418.
0
0
1,507,181.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1,508,599.
3,444,480.
0
17,653.
3,311.
0
0
0
0
0
0
20,964.
Grid Electricity
Conv.
Factor
0
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.06
0
0
0
0
0
0
0
0
0
0
Used
MWh
521.
0
0
0
442.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
442.
26.
0
0
0
0
0
0
0
0
0
0
All Water
Conv.
Factor
0
0
0
0
0
0
0
1
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0
900
-2
0
0
0
0
0
0
0
0
0
Used
gal x 1000
396,764.
0
0
0
0
0
0
0
0
99.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
99.
397,440.
-883.
0
0
0
0
0
0
0
0
0
Potable Water
Conv.
Factor
0
0
0
0
0
0
0
0
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Used
gal x 1000
99.
0
0
0
0
0
0
0
0
99.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
99.
0
0
0
0
0
0
0
0
0
0
0
Groundwater
Conv.
Factor
0
0
0
0
0
0
0
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Extracted
gal x 1000
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
C02e
Conv.
Factor
22.5
19.6
12.2
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
-1
0
0
0
0
0
0
2400
-1979
22.5
19.6
12.2
0
0
0
0
0
0
Emitted
Ibs
275,595.
230.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
230.
1,059,840.
-873,846.
2,858.
523.
0
0
0
0
0
0
3,381.
NOx
Conv.
Factor
0.17
0.11
0.01
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
-1
0
0
0
0
0
6.7
-3.045
0.17
0.11
0.01
0
0
0
0
0
0
Emitted
Ibs
1,853.
2.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
2.
2,959.
-1,345.
22.
3.
0
0
0
0
0
0
25.
SOx
Conv.
Factor
0.0054
0.0045
6E-06
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
-1
0
0
0
0
15
-11.58
0.0054
0.0045
6E-06
0
0
0
0
0
0
Emitted
Ibs
2,144.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
6,624.
-5,115.
1.
0
0
0
0
0
0
0
1.
PM
Conv.
Factor
0.0034
0.0005
0.0008
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
-1
0
0
0
1.7
-0.94
0.0034
0.0005
0.0008
0
0
0
0
0
0
Emitted
Ibs
388.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
751.
-415.
0
0
0
0
0
0
0
0
0
Solid Waste
Conv.
Factor
0
0
0
0
0
0
0
0
0
0
0
0
1
0
0
0
0
0
0
0
0
0
0
0
0
0.0009
-9E-04
0
0
0
0
0
0
0
0
0
Generated
tons
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.4
-0.4
0
0
0
0
0
0
0
0
0
Haz. Waste
Conv.
Factor
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Generated
tons
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Air Toxics
Conv.
Factor
5E-06
4E-05
8E-06
0
0
0
0
0
0
0
0
0
0
0
0
0
1
0
0
0
0
0
0
0
0
0.7
-0.4
5E-06
4E-05
8E-06
0
0
0
0
0
0
Emitted
Ibs
155.1555
0.0001
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.0001
309.12
-176.64
0.0007
0.001
0
0
0
0
0
0
0.0017
Mercury
Conv.
Factor
0
0
3E-08
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.0002
-2E-05
0
0
3E-08
0
0
0
0
0
0
Released
Ibs
0.097065532
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.105984
-0.0101568
0
0
0
0
0
0
0
0
0
Lead
Conv.
Factor
0
0
5E-08
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
4E-05
-2E-04
0
0
5E-08
0
0
0
0
0
0
Released
Ibs
-0.047184838
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.0185472
-0.075072
0
0
0
0
0
0
0
0
0
Dioxins
Conv.
Factor
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
4E-10
-2E-10
0
0
0
0
0
0
0
0
0
Released
Ibs
0.00000006S7SS
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.000000158976
-0.000000105984
0
0
0
0
0
0
0
0
0
-------�
Green Remediation Footprint Analysis Spreadsheets
Vineland Chemical SuperfundSite, Vineland, NJ, P&T-P&T
OFF-SITE OTHER
Materials
Asphalt
Bentonite
Borrow (clean soil)
Cement
Cheese Whey
Concrete
Diesel Produced
Emulsified vegetable oil
GAC: regenerated
GAC: virgin coal-based
GAC: virgin coconut-based
Gasoline Produced
Gravel/sand/clay
HOPE
Hydrochloric acid (30%, SG = 1.18)
Hydrogen peroxide (50%, SG=1.19)
Hydroseed
Lime
Molasses
Natural Gas Produced
Nitrogen fertilizer
Other Material #1 - Ferric Chloride
(salt)
Other Material #2 - Mulch
Other Material #3 - acetic acid
Other Material #4 - guar gum
Other Material #5
Phosphorus fertilizer
Polymer
Potable Water
Potassium permanganate
PVC
Sequestering agent
Sodium hydroxide (dry bulk)
Stainless Steel
Steel
Tree: root ball
Tree: whip
Off-Site Services
Off-site waste water treatment
Off-site Solid Waste Disposal
Off-site Haz. Waste Disposal
Off-site Laboratory Analysis
Other 1
Other 2
Other 3
Other 4
Others
Other
Potable Water Transported
Electricity transmission
Other 1
Other 2
Others
OFF-SITE OTHER TOTAL
tons
tons
tons
dry-ton
Ibs
tons
gal
Ibs
Ibs
Ibs
Ibs
gal
ton
Ib
Ibs
Ibs
Ibs
Ibs
Ibs
ccf
Ibs
Ibs
cy
Ib
Ib
TBD
Ibs
Ibs
gal x 1000
Ibs
Ibs
Ibs
Ibs
Ib
Ib
trees
trees
gal x 1000
ton
ton
$
TBD
TBD
TBD
TBD
TBD
gal x 1000
MWh
TBD
TBD
TBD
Quantity
Used
0
0
0
0
0
0
137.2
0
0
0
0
26.7
0
0
0
0
0
0
0
0
0
0
0
4927.7076
0
0
0
0
99
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
99
441.6
0
0
0
Level 1 (Extraction) Parameters Used, Extracted, Emitted, or Generated - P&T
Energy
Conv.
Factor
0
55
15.75
4100
1.87
3019
18.5
3.6
9.6
10.8
0
21
55
31
0
4.95
0.049
0
1.31
5.2
16.2
2.31
0
5.2
0.91
0
3.39
15.39
9.2
29.22
22
0
6.6
11.6
4.4
3.7
0
15
160
176
6.49
0
0
0
0
0
7.4
410
0
0
0
0
Used
Mbtu
0
0
0
0
0
0
2,538.
0
0
0
0
561.
0
0
0
0
0
0
0
0
0
0
0
25,624.
0
0
0
0
911.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
733.
181,056.
0
0
0
211,423.
Grid Electricity
Conv.
Factor
0
0.0027
6E-05
0.13
0
0.096
0.0006
6E-05
0.0004
5E-05
0
0.0006
0.0027
0.0003
0
0.0006
1E-07
0
5E-06
0.0003
2E-05
0.0003
0
2E-05
5E-05
0
7E-05
0.0023
0.0004
0.0016
0.0006
0
0.0003
0.0006
0.0002
2E-06
0
0.0007
0.0077
0.0085
0.0004
0
0
0
0
0
0.0006
0.12
0
0
0
0
Used
MWh
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
53.
0
0
0
53.
All Water
Conv.
Factor
0
0.13
8E-05
0.41
0
0.34
0.0008
2E-05
0.0064
0
0
0.0008
0.13
0.0023
0
0.019
0.0001
0
9E-05
8E-05
0
0.0003
0
0
0.0001
0
0
0.0018
0.021
0.003
0.0069
0
0.0012
0.0023
0.0006
0.004
0
0.0029
0.15
0.165
0.0007
0
0
0
0
0
0.0013
0.24
0
0
0
0
Used
gal x 1000
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
2.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
106.
0
0
0
108.
Potable Water
Conv.
Factor
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Used
gal x 1000
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Groundwater
Conv.
Factor
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Extracted
gal x 1000
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
C02e
Conv.
Factor
0
6.7
2.52
1800
1.1
1322
2.7
3.51
2
4.5
0
4.4
6.7
1.9
0
1.35
0.0046
0
0.4
2.2
1.5
0.41
0
0.67
1
0
0.35
2.72
5
4.5
2.6
0
1.37
3.4
1.1
0.6
0
4.4
25
27.5
1
0
0
0
0
0
0.9948
184.8
0
0
0
0
Emitted
Ibs
0
0
0
0
0
0
370.
0
0
0
0
117.
0
0
0
0
0
0
0
0
0
0
0
3,302.
0
0
0
0
495.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
98.
81,608.
0
0
0
85,990.
NOx
Conv.
Factor
0
0.033
0.0176
3.6
0.0083
2.6
0.0064
0.0265
0.025
0.12
0
0.008
0.033
0.0032
0
0.0087
3E-06
0
0.003
0.0037
0.0008
0.0019
0
0.0006
0.073
0
0.0017
0.013
0.0097
0.021
0.0048
0
0.003
0.0075
0.0014
0.003
0
0.016
0.14
0.154
0.0048
0
0
0
0
0
0.0025
0.468
0
0
0
0
Emitted
Ibs
0
0
0
0
0
0
1.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
3.
0
0
0
0
1.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
207.
0
0
0
212.
SOx
Conv.
Factor
0
0.03
0.0018
2.1
0.0099
1.5
0.013
0.031
0.015
0.074
0
0.019
0.03
0.0041
0
0.0066
5E-05
0
0.0026
0.0046
0.0174
0.0015
0
0.02
0.0068
0
0.017
0.0098
0.0059
0.016
0.0076
0
0.0048
0.012
0.0017
0.0006
0
0.015
0.075
0.0825
0.0036
0
0
0
0
0
0.0065
1.2
0
0
0
0
Emitted
Ibs
0
0
0
0
0
0
2.
0
0
0
0
1.
0
0
0
0
0
0
0
0
0
0
0
99.
0
0
0
0
1.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1.
530.
0
0
0
634.
PM
Conv.
Factor
0
0.004
0.0004
0.0063
0.0002
0.0054
0.0003
0.0017
0
0
0
0.0005
0.004
0.0006
0
0.0025
3E-07
0
6E-05
7E-05
7E-05
0.0002
0
6E-05
0.0001
0
0.0001
0.001
0.016
0.0017
0.0012
0
0.0005
0.0044
0.0006
3E-05
0
0.0017
0.4
0.44
0.0004
0
0
0
0
0
0.0006
0.1128
0
0
0
0
Emitted
Ibs
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
2.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
50.
0
0
0
52.
Solid Waste
Conv.
Factor
0
0
4E-08
0
0
IE-OS
4E-07
0
0
0
0
4E-07
0
4E-07
0
IE-OS
0
0
0
0
0
1E-07
0
0
0
0
0
8E-07
8E-07
1E-06
2E-06
0
2E-05
0.0006
0.0003
IE-OS
0
0.0024
8E-06
9E-06
0
0
0
0
0
0
6E-07
0.0001
0
0
0
0
Generated
tons
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Haz. Waste
Conv.
Factor
0
0
0
0
0
0
0
0
0
0
0
0
0
1E-06
0
5E-07
0
0
0
0
0
0
0
0
0
0
0
0
0
0
2E-06
0
5E-07
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Generated
tons
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Air Toxics
Conv.
Factor
0
4E-07
IE-OS
0.058
0
0.043
0.0001
0
0
0
0
0.0002
4E-07
3E-06
0
0.0002
8E-07
0
0
6E-06
0.0003
5E-05
0
0.0003
IE-OS
0
5E-05
0.0004
2E-05
0.0006
0.0005
0
6E-05
0.0001
7E-05
6E-06
0
0.0006
0.0014
0.0015
0.0001
0
0
0
0
0
0.0003
0.048
0
0
0
0
Emitted
Ibs
0
0
0
0
0
0
0.0165
0
0
0
0
0.0043
0
0
0
0
0
0
0
0
0
0
0
1.429
0
0
0
0
0.0015
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.0256
21.1968
0
0
0
22.6737
Mercury
Conv.
Factor
0
6E-11
5E-09
6E-05
0
4E-05
5E-08
0
0
0
0
9E-08
6E-11
3E-09
0
0
2E-11
0
0
2E-08
6E-09
3E-09
0
2E-09
1E-09
0
2E-09
2E-08
8E-09
4E-08
3E-07
0
2E-07
0
1E-07
2E-09
0
4E-08
1E-06
1E-06
8E-09
0
0
0
0
0
IE-OS
3E-06
0
0
0
0
Released
Ibs
0
0
0
0
0
0
0.000006586
0
0
0
0
0.00000227
0
0
0
0
0
0
0
0
0
0
0
0.000008377
0
0
0
0
0.000000812
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.000001471
0.001218816
0
0
0
0.001238332
Lead
Conv.
Factor
0
1E-09
2E-07
0.0001
0
1E-04
2E-06
0
0
0
0
2E-06
1E-09
2E-09
0
0
1E-10
0
0
9E-07
4E-08
4E-08
0
IE-OS
1E-07
0
5E-08
2E-07
7E-08
4E-07
1E-07
0
3E-08
5E-07
3E-06
6E-08
0
4E-07
8E-06
8E-06
9E-08
0
0
0
0
0
1E-07
2E-05
0
0
0
0
Released
Ibs
0
0
0
0
0
0
0.0002058
0
0
0
0
0.00005874
0
0
0
0
0
0
0
0
0
0
0
0.000049277
0
0
0
0
0.000006633
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.000010872
0.00900864
0
0
0
0.009339962
Dioxins
Conv.
Factor
0
2E-16
3E-15
9E-11
0
6E-11
3E-14
0
0
0
0
3E-14
2E-16
1E-09
0
0
0
0
0
5E-14
0
3E-14
0
3E-15
6E-14
0
0
2E-13
1E-13
4E-13
7E-09
0
2E-14
2E-12
7E-12
0
0
3E-13
1E-11
1E-11
8E-14
0
0
0
0
0
2E-13
3E-11
0
0
0
0
Released
Ibs
0
0
0
0
0
0
D.DDDDDDDDDDD4
0
0
0
0
D.DDDDDDDDDDD1
0
0
0
0
0
0
0
0
0
0
0
0.000000000015
0
0
0
0
0.00000000001
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.000000000015
0.000000012718
0
0
0
0.000000012763
This workbook is for testing and research purposes only. It does not represent EPA guidance or a requirement.
For more information contact: scheuermann.karen@epa.gov or pachon.carlos@epa.gov.
-------�
Green Remediation Footprint Analysis Spreadsheets
Vineland Chemical SuperfundSite, Vineland, NJ, P&T-P&T
Totals
ON-SITE
Energy
Diesel (on-site use)
Gasoline (on-site use)
Natural gas (on-site use)
Electricity (on-site use)
Photovoltaic (on-site system)
Other Energy 2
Other Energy 3
Water
Groundwater Extracted On-site
Potable Water Used On-site
Other On-Site Water 1
Other On-Site Water 2
Other On-Site Water 3
Waste Generation
On-Site Solid Waste Generation
On-Site Solid Waste Disposal
On-Site Hazardous Waste Generation
On-Site Hazardous Waste Disposal
Other
On-site process emissions (HAPs)
On-site process emissions (GHGs)
On-site GHG storage
On-site NOx reduction
On-site SOx reduction
On-site PM reduction
Other 1
Other 2
ON-SITE TOTAL
ELECTRICITY GENERATION
Electricity production
Purchased Renewa ble Electricity
TRANSPORTATION
Diesel (off-site use)
Gasoline (off-site use)
Natural gas (off -site use)
Other Transportation 1
Other Transportation 2
Other Transportation 3
Other Transportation 4
Other Transportation 5
TRANSPORTATION TOTAL
gal
gal
ccf
MWh
MWh
TBD
TBD
gal x 1000
gal x 1000
gal x 1000
gal x 1000
gal x 1000
ton
ton
Ibs
Ibs C02e
Ibs C02e
Ibs
Ibs
Ibs
TBD
TBD
MWh
MWh
gal
gal
ccf
TBD
TBD
TBD
0
0
Quantity
Used
0
0
23657
875.9
0
0
0
0
12436.623
0
0
0
0
0
260
0
0
0
0
0
0
0
0
0
875.9
875.9
4524.0588
1213.3
0
0
0
0
0
0
Level 2 (O&M) Parameters Used, Extracted, Emitted, or Generated - P&T
Energy
Conv.
Factor
139
124
103
3413
37922
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
7800
0
139
124
103
0
0
0
0
0
0
Used
Mbtu
17,152,609.
0
0
2,436,671.
2,989,447.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
5,426,118.
6,832,020.
0
628,844.
150,449.
0
0
0
0
0
0
779,293.
Grid Electricity
Conv.
Factor
0
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.06
0
0
0
0
0
0
0
0
0
0
Used
MWh
1,349.
0
0
0
876.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
876.
53.
0
0
0
0
0
0
0
0
0
0
All Water
Conv.
Factor
0
0
0
0
0
0
0
1
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0
900
-2
0
0
0
0
0
0
0
0
0
Used
gal x 1000
801,813.
0
0
0
0
0
0
0
0
12,437.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
12,437.
788,310.
-1,752.
0
0
0
0
0
0
0
0
0
Potable Water
Conv.
Factor
0
0
0
0
0
0
0
0
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Used
gal x 1000
12,436.6
0
0
0
0
0
0
0
0
12,436.6
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
12,436.6
0
0
0
0
0
0
0
0
0
0
0
Groundwater
Conv.
Factor
0
0
0
0
0
0
0
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Extracted
gal x 1000
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
C02e
Conv.
Factor
22.5
19.6
12.2
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
-1
0
0
0
0
0
0
2400
-1979
22.5
19.6
12.2
0
0
0
0
0
0
Emitted
Ibs
1,770,639.
0
0
288,615.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
288,615.
2,102,160.
-1,733,247.
101,791.
23,781.
0
0
0
0
0
0
125,572.
NOx
Conv.
Factor
0.17
0.11
0.01
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
-1
0
0
0
0
0
6.7
-3.045
0.17
0.11
0.01
0
0
0
0
0
0
Emitted
Ibs
7,602.
0
0
237.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
237.
5,869.
-2,667.
769.
133.
0
0
0
0
0
0
902.
SOx
Conv.
Factor
0.0054
0.0045
6E-06
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
-1
0
0
0
0
15
-11.58
0.0054
0.0045
6E-06
0
0
0
0
0
0
Emitted
Ibs
7,008.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
13,139.
-10,146.
24.
5.
0
0
0
0
0
0
29.
PM
Conv.
Factor
0.0034
0.0005
0.0008
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
-1
0
0
0
1.7
-0.94
0.0034
0.0005
0.0008
0
0
0
0
0
0
Emitted
Ibs
1,579.
0
0
18.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
18.
1,489.
-823.
15.
1.
0
0
0
0
0
0
16.
Solid Waste
Conv.
Factor
0
0
0
0
0
0
0
0
0
0
0
0
1
0
0
0
0
0
0
0
0
0
0
0
0
0.0009
-9E-04
0
0
0
0
0
0
0
0
0
Generated
tons
6.3
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.8
-0.8
0
0
0
0
0
0
0
0
0
Haz. Waste
Conv.
Factor
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Generated
tons
260.167
0
0
0
0
0
0
0
0
0
0
0
0
0
0
260.
0
0
0
0
0
0
0
0
0
260.
0
0
0
0
0
0
0
0
0
0
0
Air Toxics
Conv.
Factor
5E-06
4E-05
8E-06
0
0
0
0
0
0
0
0
0
0
0
0
0
1
0
0
0
0
0
0
0
0
0.7
-0.4
5E-06
4E-05
8E-06
0
0
0
0
0
0
Emitted
Ibs
373.4041
0
0
0.1987
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.1987
613.13
-350.36
0.0235
0.0473
0
0
0
0
0
0
0.0708
Mercury
Conv.
Factor
0
0
3E-08
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.0002
-2E-05
0
0
3E-08
0
0
0
0
0
0
Released
Ibs
0.252329088
0
0
0.000615082
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.000615082
0.210216
-0.0201457
0
0
0
0
0
0
0
0
0
Lead
Conv.
Factor
0
0
5E-08
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
4E-05
-2E-04
0
0
5E-08
0
0
0
0
0
0
Released
Ibs
-0.035257151
0
0
0.00118285
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.00118285
0.0367878
-0.148903
0
0
0
0
0
0
0
0
0
Dioxins
Conv.
Factor
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
4E-10
-2E-10
0
0
0
0
0
0
0
0
0
Released
Ibs
0.0000001S946
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.000000315324
-0.000000210216
0
0
0
0
0
0
0
0
0
-------�
Green Remediation Footprint Analysis Spreadsheets
Vineland Chemical SuperfundSite, Vineland, NJ, P&T-P&T
OFF-SITE OTHER
Materials
Asphalt
Bentonite
Borrow (clean soil)
Cement
Cheese Whey
Concrete
Diesel Produced
Emulsified vegetable oil
GAC: regenerated
GAC: virgin coal-based
GAC: virgin coconut-based
Gasoline Produced
Gravel/sand/clay
HOPE
Hydrochloric acid (30%, SG = 1.18)
Hydrogen peroxide (50%, SG=1.19)
Hydroseed
Lime
Molasses
Natural Gas Produced
Nitrogen fertilizer
Other Material #1 - Ferric Chloride
(salt)
Other Material #2 - Mulch
Other Material #3 - acetic acid
Other Material #4 - guar gum
Other Material #5
Phosphorus fertilizer
Polymer
Potable Water
Potassium permanganate
PVC
Sequestering agent
Sodium hydroxide (dry bulk)
Stainless Steel
Steel
Tree: root ball
Tree: whip
Off-Site Services
Off-site waste water treatment
Off-site Solid Waste Disposal
Off-site Haz. Waste Disposal
Off-site Laboratory Analysis
Other 1
Other 2
Other 3
Other 4
Others
Other
Potable Water Transported
Electricity transmission
Other 1
Other 2
Others
OFF-SITE OTHER TOTAL
tons
tons
tons
dry-ton
Ibs
tons
gal
Ibs
Ibs
Ibs
Ibs
gal
ton
Ib
Ibs
Ibs
Ibs
Ibs
Ibs
ccf
Ibs
Ibs
cy
Ib
Ib
TBD
Ibs
Ibs
gal x 1000
Ibs
Ibs
Ibs
Ibs
Ib
Ib
trees
trees
gal x 1000
ton
ton
$
TBD
TBD
TBD
TBD
TBD
gal x 1000
MWh
TBD
TBD
TBD
Quantity
Used
0
0
0
0
0
0
4524.0588
0
0
0
0
1213.3
0
0
0
98000
0
0
0
23657
0
197000
0
0
0
0
0
33485.1
12436.623
0
0
0
256000
0
0
0
0
0
0
260
19500
0
0
0
0
0
12436.623
875.9
0
0
0
Level 2 (O&M) Parameters Used, Extracted, Emitted, or Generated - P&T
Energy
Conv.
Factor
0
55
15.75
4100
1.87
3019
18.5
3.6
9.6
10.8
0
21
55
31
0
4.95
0.049
0
1.31
5.2
16.2
2.31
0
5.2
0.91
0
3.39
15.39
9.2
29.22
22
0
6.6
11.6
4.4
3.7
0
15
160
176
6.49
0
0
0
0
0
7.4
410
0
0
0
0
Used
Mbtu
0
0
0
0
0
0
83,695.
0
0
0
0
25,479.
0
0
0
485,100.
0
0
0
123,016.
0
455,070.
0
0
0
0
0
515,336.
114,417.
0
0
0
1,689,600.
0
0
0
0
0
0
45,760.
126,555.
0
0
0
0
0
92,031.
359,119.
0
0
0
4,115,178.
Grid Electricity
Conv.
Factor
0
0.0027
6E-05
0.13
0
0.096
0.0006
6E-05
0.0004
5E-05
0
0.0006
0.0027
0.0003
0
0.0006
1E-07
0
5E-06
0.0003
2E-05
0.0003
0
2E-05
5E-05
0
7E-05
0.0023
0.0004
0.0016
0.0006
0
0.0003
0.0006
0.0002
2E-06
0
0.0007
0.0077
0.0085
0.0004
0
0
0
0
0
0.0006
0.12
0
0
0
0
Used
MWh
0
0
0
0
0
0
3.
0
0
0
0
1.
0
0
0
59.
0
0
0
6.
0
67.
0
0
0
0
0
75.
5.
0
0
0
82.
0
0
0
0
0
0
2.
7.
0
0
0
0
0
8.
105.
0
0
0
420.
All Water
Conv.
Factor
0
0.13
8E-05
0.41
0
0.34
0.0008
2E-05
0.0064
0
0
0.0008
0.13
0.0023
0
0.019
0.0001
0
9E-05
8E-05
0
0.0003
0
0
0.0001
0
0
0.0018
0.021
0.003
0.0069
0
0.0012
0.0023
0.0006
0.004
0
0.0029
0.15
0.165
0.0007
0
0
0
0
0
0.0013
0.24
0
0
0
0
Used
gal x 1000
0
0
0
0
0
0
3.
0
0
0
0
1.
0
0
0
1,862.
0
0
0
2.
0
53.
0
0
0
0
0
60.
261.
0
0
0
294.
0
0
0
0
0
0
43.
13.
0
0
0
0
0
16.
210.
0
0
0
2,818.
Potable Water
Conv.
Factor
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Used
gal x 1000
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Groundwater
Conv.
Factor
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Extracted
gal x 1000
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
C02e
Conv.
Factor
0
6.7
2.52
1800
1.1
1322
2.7
3.51
2
4.5
0
4.4
6.7
1.9
0
1.35
0.0046
0
0.4
2.2
1.5
0.41
0
0.67
1
0
0.35
2.72
5
4.5
2.6
0
1.37
3.4
1.1
0.6
0
4.4
25
27.5
1
0
0
0
0
0
0.9948
184.8
0
0
0
0
Emitted
Ibs
0
0
0
0
0
0
12,215.
0
0
0
0
5,339.
0
0
0
132,300.
0
0
0
52,045.
0
80,770.
0
0
0
0
0
91,079.
62,183.
0
0
0
350,720.
0
0
0
0
0
0
7,150.
19,500.
0
0
0
0
0
12,372.
161,866.
0
0
0
987,539.
NOx
Conv.
Factor
0
0.033
0.0176
3.6
0.0083
2.6
0.0064
0.0265
0.025
0.12
0
0.008
0.033
0.0032
0
0.0087
3E-06
0
0.003
0.0037
0.0008
0.0019
0
0.0006
0.073
0
0.0017
0.013
0.0097
0.021
0.0048
0
0.003
0.0075
0.0014
0.003
0
0.016
0.14
0.154
0.0048
0
0
0
0
0
0.0025
0.468
0
0
0
0
Emitted
Ibs
0
0
0
0
0
0
29.
0
0
0
0
10.
0
0
0
853.
0
0
0
88.
0
382.
0
0
0
0
0
435.
121.
0
0
0
768.
0
0
0
0
0
0
40.
94.
0
0
0
0
0
31.
410.
0
0
0
3,261.
SOx
Conv.
Factor
0
0.03
0.0018
2.1
0.0099
1.5
0.013
0.031
0.015
0.074
0
0.019
0.03
0.0041
0
0.0066
5E-05
0
0.0026
0.0046
0.0174
0.0015
0
0.02
0.0068
0
0.017
0.0098
0.0059
0.016
0.0076
0
0.0048
0.012
0.0017
0.0006
0
0.015
0.075
0.0825
0.0036
0
0
0
0
0
0.0065
1.2
0
0
0
0
Emitted
Ibs
0
0
0
0
0
0
59.
0
0
0
0
23.
0
0
0
647.
0
0
0
109.
0
296.
0
0
0
0
0
328.
73.
0
0
0
1,229.
0
0
0
0
0
0
21.
70.
0
0
0
0
0
80.
1,051.
0
0
0
3,986.
PM
Conv.
Factor
0
0.004
0.0004
0.0063
0.0002
0.0054
0.0003
0.0017
0
0
0
0.0005
0.004
0.0006
0
0.0025
3E-07
0
6E-05
7E-05
7E-05
0.0002
0
6E-05
0.0001
0
0.0001
0.001
0.016
0.0017
0.0012
0
0.0005
0.0044
0.0006
3E-05
0
0.0017
0.4
0.44
0.0004
0
0
0
0
0
0.0006
0.1128
0
0
0
0
Emitted
Ibs
0
0
0
0
0
0
2.
0
0
0
0
1.
0
0
0
245.
0
0
0
2.
0
30.
0
0
0
0
0
33.
199.
0
0
0
138.
0
0
0
0
0
0
114.
8.
0
0
0
0
0
8.
99.
0
0
0
879.
Solid Waste
Conv.
Factor
0
0
4E-08
0
0
IE-OS
4E-07
0
0
0
0
4E-07
0
4E-07
0
IE-OS
0
0
0
0
0
1E-07
0
0
0
0
0
8E-07
8E-07
1E-06
2E-06
0
2E-05
0.0006
0.0003
IE-OS
0
0.0024
8E-06
9E-06
0
0
0
0
0
0
6E-07
0.0001
0
0
0
0
Generated
tons
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1.3
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
4.9
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.1
0
0
0
6.3
Haz. Waste
Conv.
Factor
0
0
0
0
0
0
0
0
0
0
0
0
0
1E-06
0
5E-07
0
0
0
0
0
0
0
0
0
0
0
0
0
0
2E-06
0
5E-07
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Generated
tons
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.047
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.12
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.167
Air Toxics
Conv.
Factor
0
4E-07
IE-OS
0.058
0
0.043
0.0001
0
0
0
0
0.0002
4E-07
3E-06
0
0.0002
8E-07
0
0
6E-06
0.0003
5E-05
0
0.0003
IE-OS
0
5E-05
0.0004
2E-05
0.0006
0.0005
0
6E-05
0.0001
7E-05
6E-06
0
0.0006
0.0014
0.0015
0.0001
0
0
0
0
0
0.0003
0.048
0
0
0
0
Emitted
Ibs
0
0
0
0
0
0
0.5429
0
0
0
0
0.1941
0
0
0
22.54
0
0
0
0.1443
0
10.638
0
0
0
0
0
12.0546
0.1865
0
0
0
15.872
0
0
0
0
0
0
0.4004
2.535
0
0
0
0
0
3.2136
42.0432
0
0
0
110.3646
Mercury
Conv.
Factor
0
6E-11
5E-09
6E-05
0
4E-05
5E-08
0
0
0
0
9E-08
6E-11
3E-09
0
0
2E-11
0
0
2E-08
6E-09
3E-09
0
2E-09
1E-09
0
2E-09
2E-08
8E-09
4E-08
3E-07
0
2E-07
0
1E-07
2E-09
0
4E-08
1E-06
1E-06
8E-09
0
0
0
0
0
IE-OS
3E-06
0
0
0
0
Released
Ibs
0
0
0
0
0
0
0.000217155
0
0
0
0
0.000103131
0
0
0
0
0
0
0
0.000496797
0
0.000591
0
0
0
0
0
0.000770157
0.00010198
0
0
0
0.05632
0
0
0
0
0
0
0.00027742
0.0001638
0
0
0
0
0
0.000184782
0.002417484
0
0
0
0.061643706
Lead
Conv.
Factor
0
1E-09
2E-07
0.0001
0
1E-04
2E-06
0
0
0
0
2E-06
1E-09
2E-09
0
0
1E-10
0
0
9E-07
4E-08
4E-08
0
IE-OS
1E-07
0
5E-08
2E-07
7E-08
4E-07
1E-07
0
3E-08
5E-07
3E-06
6E-08
0
4E-07
8E-06
8E-06
9E-08
0
0
0
0
0
1E-07
2E-05
0
0
0
0
Released
Ibs
0
0
0
0
0
0
0.006786088
0
0
0
0
0.00266926
0
0
0
0
0
0
0
0.0212913
0
0.006895
0
0
0
0
0
0.007735058
0.000833254
0
0
0
0.0064
0
0
0
0
0
0
0.0021736
0.0016575
0
0
0
0
0
0.001365779
0.01786836
0
0
0
0.075675199
Dioxins
Conv.
Factor
0
2E-16
3E-15
9E-11
0
6E-11
3E-14
0
0
0
0
3E-14
2E-16
1E-09
0
0
0
0
0
5E-14
0
3E-14
0
3E-15
6E-14
0
0
2E-13
1E-13
4E-13
7E-09
0
2E-14
2E-12
7E-12
0
0
3E-13
1E-11
1E-11
8E-14
0
0
0
0
0
2E-13
3E-11
0
0
0
0
Released
Ibs
0
0
0
0
0
0
0.000000000136
0
0
0
0
0.000000000038
0
0
0
0
0
0
0
0.000000001207
0
0.000000006304
0
0
0
0
0
0.000000007152
0.000000001244
0
0
0
0.000000006144
0
0
0
0
0
0
0.000000003432
0.000000001541
0
0
0
0
0
0.000000001928
0.000000025226
0
0
0
0.000000054352
This workbook is for testing and research purposes only. It does not represent EPA guidance or a requirement.
For more information contact: scheuermann.karen@epa.gov or pachon.carlos@epa.gov.
-------�
Green Remediation Footprint Analysis Spreadsheets
Vineland Chemical SuperfundSite, Vineland, NJ, P&T-P&T
Totals
ON-SITE
Energy
Diesel (on-site use)
Gasoline (on-site use)
Natural gas (on-site use)
Electricity (on-site use)
Photovoltaic (on-site system)
Other Energy 2
Other Energy 3
Water
Groundwater Extracted On-site
Potable Water Used On-site
Other On-Site Water 1
Other On-Site Water 2
Other On-Site Water 3
Waste Generation
On-Site Solid Waste Generation
On-Site Solid Waste Disposal
On-Site Hazardous Waste Generation
On-Site Hazardous Waste Disposal
Other
On-site process emissions (HAPs)
On-site process emissions (GHGs)
On-site GHG storage
On-site NOx reduction
On-site SOx reduction
On-site PM reduction
Other 1
Other 2
ON-SITE TOTAL
ELECTRICITY GENERATION
Electricity production
Purchased Renewa ble Electricity
TRANSPORTATION
Diesel (off-site use)
Gasoline (off-site use)
Natural gas (off -site use)
Other Transportation 1
Other Transportation 2
Other Transportation 3
Other Transportation 4
Other Transportation 5
TRANSPORTATION TOTAL
gal
gal
ccf
MWh
MWh
TBD
TBD
gal x 1000
gal x 1000
gal x 1000
gal x 1000
gal x 1000
ton
ton
Ibs
Ibs C02e
Ibs C02e
Ibs
Ibs
Ibs
TBD
TBD
MWh
MWh
gal
gal
ccf
TBD
TBD
TBD
0
0
Quantity
Used
0
5.814
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
133.3
0
0
0
0
0
0
Level 3 (LTM) Parameters Used, Extracted, Emitted, or Generated - P&T
Energy
Conv.
Factor
139
124
103
3413
37922
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
7800
0
139
124
103
0
0
0
0
0
0
Used
Mbtu
31,853.
0
721.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
721.
0
0
0
16,529.
0
0
0
0
0
0
16,529.
Grid Electricity
Conv.
Factor
0
0
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.06
0
0
0
0
0
0
0
0
0
0
Used
MWh
1.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
All Water
Conv.
Factor
0
0
0
0
0
0
0
1
1
1
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0
900
-2
0
0
0
0
0
0
0
0
0
Used
gal x 1000
1.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Potable Water
Conv.
Factor
0
0
0
0
0
0
0
0
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Used
gal x 1000
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Groundwater
Conv.
Factor
0
0
0
0
0
0
0
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Extracted
gal x 1000
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
C02e
Conv.
Factor
22.5
19.6
12.2
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
-1
0
0
0
0
0
0
2400
-1979
22.5
19.6
12.2
0
0
0
0
0
0
Emitted
Ibs
5,139.
0
114.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
114.
0
0
0
2,613.
0
0
0
0
0
0
2,613.
NOx
Conv.
Factor
0.17
0.11
0.01
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
-1
0
0
0
0
0
6.7
-3.045
0.17
0.11
0.01
0
0
0
0
0
0
Emitted
Ibs
26.
0
1.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1.
0
0
0
15.
0
0
0
0
0
0
15.
SOx
Conv.
Factor
0.0054
0.0045
6E-06
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
-1
0
0
0
0
15
-11.58
0.0054
0.0045
6E-06
0
0
0
0
0
0
Emitted
Ibs
10.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1.
0
0
0
0
0
0
1.
PM
Conv.
Factor
0.0034
0.0005
0.0008
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
-1
0
0
0
1.7
-0.94
0.0034
0.0005
0.0008
0
0
0
0
0
0
Emitted
Ibs
1.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Solid Waste
Conv.
Factor
0
0
0
0
0
0
0
0
0
0
0
0
1
0
0
0
0
0
0
0
0
0
0
0
0
0.0009
-9E-04
0
0
0
0
0
0
0
0
0
Generated
tons
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Haz. Waste
Conv.
Factor
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Generated
tons
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Air Toxics
Conv.
Factor
5E-06
4E-05
8E-06
0
0
0
0
0
0
0
0
0
0
0
0
0
1
0
0
0
0
0
0
0
0
0.7
-0.4
5E-06
4E-05
8E-06
0
0
0
0
0
0
Emitted
Ibs
0.2617
0
0.0002
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.0002
0
0
0
0.0052
0
0
0
0
0
0
0.0052
Mercury
Conv.
Factor
0
0
3E-08
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.0002
-2E-05
0
0
3E-08
0
0
0
0
0
0
Released
Ibs
0.000026945
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Lead
Conv.
Factor
0
0
5E-08
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
4E-05
-2E-04
0
0
5E-08
0
0
0
0
0
0
Released
Ibs
0.000459051
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Dioxins
Conv.
Factor
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
4E-10
-2E-10
0
0
0
0
0
0
0
0
0
Released
Ibs
0.000000000146
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
-------�
Green Remediation Footprint Analysis Spreadsheets
Vineland Chemical SuperfundSite, Vineland, NJ, P&T-P&T
OFF-SITE OTHER
Materials
Asphalt
Bentonite
Borrow (clean soil)
Cement
Cheese Whey
Concrete
Diesel Produced
Emulsified vegetable oil
GAC: regenerated
GAC: virgin coal-based
GAC: virgin coconut-based
Gasoline Produced
Gravel/sand/clay
HOPE
Hydrochloric acid (30%, SG = 1.18)
Hydrogen peroxide (50%, SG=1.19)
Hydroseed
Lime
Molasses
Natural Gas Produced
Nitrogen fertilizer
Other Material #1 - Ferric Chloride
(salt)
Other Material #2 - Mulch
Other Material #3 - acetic acid
Other Material #4 - guar gum
Other Material #5
Phosphorus fertilizer
Polymer
Potable Water
Potassium permanganate
PVC
Sequestering agent
Sodium hydroxide (dry bulk)
Stainless Steel
Steel
Tree: root ball
Tree: whip
Off-Site Services
Off-site waste water treatment
Off-site Solid Waste Disposal
Off-site Haz. Waste Disposal
Off-site Laboratory Analysis
Other 1
Other 2
Other 3
Other 4
Others
Other
Potable Water Transported
Electricity transmission
Other 1
Other 2
Others
OFF-SITE OTHER TOTAL
tons
tons
tons
dry-ton
Ibs
tons
gal
Ibs
Ibs
Ibs
Ibs
gal
ton
Ib
Ibs
Ibs
Ibs
Ibs
Ibs
ccf
Ibs
Ibs
cy
Ib
Ib
TBD
Ibs
Ibs
gal x 1000
Ibs
Ibs
Ibs
Ibs
Ib
Ib
trees
trees
gal x 1000
ton
ton
$
TBD
TBD
TBD
TBD
TBD
gal x 1000
MWh
TBD
TBD
TBD
Quantity
Used
0
0
0
0
0
0
0
0
0
0
0
139.114
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1800
0
0
0
0
0
0
0
0
0
0
Level 3 (LTM) Parameters Used, Extracted, Emitted, or Generated - P&T
Energy
Conv.
Factor
0
55
15.75
4100
1.87
3019
18.5
3.6
9.6
10.8
0
21
55
31
0
4.95
0.049
0
1.31
5.2
16.2
2.31
0
5.2
0.91
0
3.39
15.39
9.2
29.22
22
0
6.6
11.6
4.4
3.7
0
15
160
176
6.49
0
0
0
0
0
7.4
410
0
0
0
0
Used
Mbtu
0
0
0
0
0
0
0
0
0
0
0
2,921.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
11,682.
0
0
0
0
0
0
0
0
0
0
14,603.
Grid Electricity
Conv.
Factor
0
0.0027
6E-05
0.13
0
0.096
0.0006
6E-05
0.0004
5E-05
0
0.0006
0.0027
0.0003
0
0.0006
1E-07
0
5E-06
0.0003
2E-05
0.0003
0
2E-05
5E-05
0
7E-05
0.0023
0.0004
0.0016
0.0006
0
0.0003
0.0006
0.0002
2E-06
0
0.0007
0.0077
0.0085
0.0004
0
0
0
0
0
0.0006
0.12
0
0
0
0
Used
MWh
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1.
0
0
0
0
0
0
0
0
0
0
1.
All Water
Conv.
Factor
0
0.13
8E-05
0.41
0
0.34
0.0008
2E-05
0.0064
0
0
0.0008
0.13
0.0023
0
0.019
0.0001
0
9E-05
8E-05
0
0.0003
0
0
0.0001
0
0
0.0018
0.021
0.003
0.0069
0
0.0012
0.0023
0.0006
0.004
0
0.0029
0.15
0.165
0.0007
0
0
0
0
0
0.0013
0.24
0
0
0
0
Used
gal x 1000
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1.
0
0
0
0
0
0
0
0
0
0
1.
Potable Water
Conv.
Factor
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Used
gal x 1000
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Groundwater
Conv.
Factor
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Extracted
gal x 1000
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
C02e
Conv.
Factor
0
6.7
2.52
1800
1.1
1322
2.7
3.51
2
4.5
0
4.4
6.7
1.9
0
1.35
0.0046
0
0.4
2.2
1.5
0.41
0
0.67
1
0
0.35
2.72
5
4.5
2.6
0
1.37
3.4
1.1
0.6
0
4.4
25
27.5
1
0
0
0
0
0
0.9948
184.8
0
0
0
0
Emitted
Ibs
0
0
0
0
0
0
0
0
0
0
0
612.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1,800.
0
0
0
0
0
0
0
0
0
0
2,412.
NOx
Conv.
Factor
0
0.033
0.0176
3.6
0.0083
2.6
0.0064
0.0265
0.025
0.12
0
0.008
0.033
0.0032
0
0.0087
3E-06
0
0.003
0.0037
0.0008
0.0019
0
0.0006
0.073
0
0.0017
0.013
0.0097
0.021
0.0048
0
0.003
0.0075
0.0014
0.003
0
0.016
0.14
0.154
0.0048
0
0
0
0
0
0.0025
0.468
0
0
0
0
Emitted
Ibs
0
0
0
0
0
0
0
0
0
0
0
1.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
9.
0
0
0
0
0
0
0
0
0
0
10.
SOx
Conv.
Factor
0
0.03
0.0018
2.1
0.0099
1.5
0.013
0.031
0.015
0.074
0
0.019
0.03
0.0041
0
0.0066
5E-05
0
0.0026
0.0046
0.0174
0.0015
0
0.02
0.0068
0
0.017
0.0098
0.0059
0.016
0.0076
0
0.0048
0.012
0.0017
0.0006
0
0.015
0.075
0.0825
0.0036
0
0
0
0
0
0.0065
1.2
0
0
0
0
Emitted
Ibs
0
0
0
0
0
0
0
0
0
0
0
3.
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
6.
0
0
0
0
0
0
0
0
0
0
9.
PM
Conv.
Factor
0
0.004
0.0004
0.0063
0.0002
0.0054
0.0003
0.0017
0
0
0
0.0005
0.004
0.0006
0
0.0025
3E-07
0
6E-05
7E-05
7E-05
0.0002
0
6E-05
0.0001
0
0.0001
0.001
0.016
0.0017
0.0012
0
0.0005
0.0044
0.0006
3E-05
0
0.0017
0.4
0.44
0.0004
0
0
0
0
0
0.0006
0.1128
0
0
0
0
Emitted
Ibs
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
1.
0
0
0
0
0
0
0
0
0
0
1.
Solid Waste
Conv.
Factor
0
0
4E-08
0
0
IE-OS
4E-07
0
0
0
0
4E-07
0
4E-07
0
IE-OS
0
0
0
0
0
1E-07
0
0
0
0
0
8E-07
8E-07
1E-06
2E-06
0
2E-05
0.0006
0.0003
IE-OS
0
0.0024
8E-06
9E-06
0
0
0
0
0
0
6E-07
0.0001
0
0
0
0
Generated
tons
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Haz. Waste
Conv.
Factor
0
0
0
0
0
0
0
0
0
0
0
0
0
1E-06
0
5E-07
0
0
0
0
0
0
0
0
0
0
0
0
0
0
2E-06
0
5E-07
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Generated
tons
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
Air Toxics
Conv.
Factor
0
4E-07
IE-OS
0.058
0
0.043
0.0001
0
0
0
0
0.0002
4E-07
3E-06
0
0.0002
8E-07
0
0
6E-06
0.0003
5E-05
0
0.0003
IE-OS
0
5E-05
0.0004
2E-05
0.0006
0.0005
0
6E-05
0.0001
7E-05
6E-06
0
0.0006
0.0014
0.0015
0.0001
0
0
0
0
0
0.0003
0.048
0
0
0
0
Emitted
Ibs
0
0
0
0
0
0
0
0
0
0
0
0.0223
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.234
0
0
0
0
0
0
0
0
0
0
0.2563
Mercury
Conv.
Factor
0
6E-11
5E-09
6E-05
0
4E-05
5E-08
0
0
0
0
9E-08
6E-11
3E-09
0
0
2E-11
0
0
2E-08
6E-09
3E-09
0
2E-09
1E-09
0
2E-09
2E-08
8E-09
4E-08
3E-07
0
2E-07
0
1E-07
2E-09
0
4E-08
1E-06
1E-06
8E-09
0
0
0
0
0
IE-OS
3E-06
0
0
0
0
Released
Ibs
0
0
0
0
0
0
0
0
0
0
0
0.000011825
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.00001512
0
0
0
0
0
0
0
0
0
0
0.000026945
Lead
Conv.
Factor
0
1E-09
2E-07
0.0001
0
1E-04
2E-06
0
0
0
0
2E-06
1E-09
2E-09
0
0
1E-10
0
0
9E-07
4E-08
4E-08
0
IE-OS
1E-07
0
5E-08
2E-07
7E-08
4E-07
1E-07
0
3E-08
5E-07
3E-06
6E-08
0
4E-07
8E-06
8E-06
9E-08
0
0
0
0
0
1E-07
2E-05
0
0
0
0
Released
Ibs
0
0
0
0
0
0
0
0
0
0
0
0.000306051
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0.000153
0
0
0
0
0
0
0
0
0
0
0.000459051
Dioxins
Conv.
Factor
0
2E-16
3E-15
9E-11
0
6E-11
3E-14
0
0
0
0
3E-14
2E-16
1E-09
0
0
0
0
0
5E-14
0
3E-14
0
3E-15
6E-14
0
0
2E-13
1E-13
4E-13
7E-09
0
2E-14
2E-12
7E-12
0
0
3E-13
1E-11
1E-11
8E-14
0
0
0
0
0
2E-13
3E-11
0
0
0
0
Released
Ibs
0
0
0
0
0
0
0
0
0
0
0
D.DDDDDDDDDDD4
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
D.DDDDDDDDD142
0
0
0
0
0
0
0
0
0
0
D.DDDDDDDDD146
This workbook is for testing and research purposes only. It does not represent EPA guidance or a requirement.
For more information contact: scheuermann.karen@epa.gov or pachon.carlos@epa.gov.
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Power Sources and Global Emissions Factors for Electricity Provided by
Vineland Municipal Electric Utility
Type
Biomass
Coal
Geothermal
Hydro
Natural Gas
Nuclear
Oil
Solar
Wind
Other
Total based on kWh at plant
Total based on kWh at point of use (0.12
kWh/kWh lost in transmission)
% Used*
0%
100%
0%
0%
0%
0%
0%
0%
0%
0%
100%
Water (gal/kWh)
Full Load
168
0.94
0
0
0.79
0.72
3.52
0
0
0
Adjusted
0
0.94
0
0
0
0
0
0
0
0
0.9
1
C02e (Ibs/kWh)
Full Load
0
2.4
0
0
1.4
0.024
1.9
0
0
0
Adjusted
0
2.4
0
0
0
0
0
0
0
0
2.4
2.69
NOx (Ibs/kWh)
Full Load
0.0015
0.0067
0
0
0.0012
0.000056
0.0036
0
0
0
Adjusted
0
0.0067
0
0
0
0.0000000
0.0000000
0
0
0
0.0067
0.0075
SOx (Ibs/kWh)
Full Load
0.00060
0.015
0
0
0.012
0.000131
0.0041
0
0
0
Adjusted
0
0.015
0
0
0
0
0
0
0
0
0.015
0.0168
PM (Ibs/kWh)
Full Load
0.000084
0.0017
0
0
0.000088
0.0000126
0.00029
0
0
0
Adjusted
0
0.0017
0
0
0
0
0
0
0
0
0.0017
0.001904
HAPs (Ibs/kWh)
Full Load
0
0.0007
0
0
0.000193
0.0000053
0.0000902
0
0
0
Adjusted
0
0.0007
0
0
0
0
0
0
0
0
0.0007
0.000784
Lead (Ibs/kWh)
Full Load
0
0.00000024
0
0
1.31E-08
5.2E-09
0.00000129
0
0
0
Adjusted
0
0.00000024
0
0
0
0
0
0
0
0
0.00000024
0.00000027
Mercury (Ibs/kWh)
Full Load
0
0.000000042
0
0
2.9E-09
4.6E-10
1.01E-08
0
0
0
Adjusted
0
4.2E-08
0
0
0
0
0
0
0
0
4.2E-08
4.7E-08
Dioxins (Ibs/kWh)
Full Load
0
3.8E-13
0
0
0
2.9E-15
1.04E-12
0
0
0
Adjusted
0
3.572E-13
0
0
0
0
0
0
0
0
3.6E-13
4E-13
* Based on the following:
Obtain "generation mix" or "fuel blend" from the local utility provider and enter the percentages of each type ofelectrcity generation method into the "% Used*" column of the above table. Percentages should add to 100%.
The above table provides the conversion factors to convert each kWh of electricity from each generation type into each of the environmental parameters.
"Adjusted" refers to adjusting the footprint value by the percentage of electricity from that particular generation type (e.g., the adjusted value for C02e emitted by nuclear is 10% of the full-load value if the % of electricity generated by nuclear is 10%).
Notes:
- Water consumption for thermoelectric power plants in U.S. -0.47 gallons per kWh *
- Water consumption for hydroelectric power assumed to be 0 gallons per kWh (i.e., considers evaporation from reservoir as non-additive)
- Water consumption for coal resource extraction and fuel processing - 0.16 cubic meters per GJ of extracted energy, and 33% thermal energy conversion to electricity**
- Water consumption for uranium resource extraction and fuel processing - 0.086 cubic meters per GJ of extracted energy and 33% thermal energy conversion to electricity**
- Water consumption for natural gas resource extraction and fuel processing -0.11 cubic meters per GJ of extracted energy and 33% thermal energy conversion to electricity*'
- Water consumption for oil resource extraction and fuel processing -1.06 cubic meters per GJ of extracted energy and 33% thermal energy conversion to electricity**
- Water consumption for biomass based on 55 cubic meters per GJ of extracted energy and 33% thermal energy conversion to electricity***
- C02e, Nox, SOx, and PM emissions from NREL LCI for each fuel type ****
* Consumptive Water Use for U.S. Power Production, December 2003 NREL/TP-550-33905
** Gleick PH. Water and energy. Annu. Rev. Energy Environ. Vol 19,1994. p 267-99.
*** The Water Footprint of Energy Consumption : an Assessment of Water Requirements of Primary Energy Carriers, Winnie Gerbens-Leenes, Arjen Hoekstra, Theo an der Meer, ISESCO
Science and Technology Vision, Volume 4 - Numbers, May 2008
**** "NREL LCI" refers to the U.S. Dept. of Energy, National Renewable Energy Laboratory (NREL), Life-Cycle Inventory Database (www.nrel.gov/lci) maintained by the Alliance for
Sustainable Energy, LLC.
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ATTACHMENT H
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Analysis of Delisting the Vineland Arsenic-Contaminated
Groundwater Treatment Sludge
Background:
I have reviewed the Vineland ROD (9/28/1989) and BSD (9/10/2001) and EPA should
be commended on these documents. EPA did an excellent job in thinking about the
regulatory issues associated with the treatment of the Vineland Chemical site
environmental media, specifically with media 'containing hazardous waste' and
what would be necessary in terms of treatment of the soils, groundwater and
sediments to make a determination that the media fno longer contains' a listed
hazardous waste (K031).
The ROD specifically states: "EPA Headquarters Site Policy and Guidance Branch
personnel (SPGB) have determined that the arsenic-contaminated soils, sediment
and groundwater at the Vineland Chemical Company site are considered the RCRA
listed hazardous waste K 031."
The ROD explained how the environmental media could be treated so it fno longer
contained-1 a listed waste which would allow the groundwater, soil and sediment to
be placed back onsite subject to meeting the necessary cleanup criteria.
-Soil and exposed sediment need to meet the cleanup criteria of 20 mg/kg
and the extract would need to meet 0.32mg/l (EP Toxicity Test) to be eligible for
delisting. The submerged sediment needs to achieve 120 mg/kg of arsenic. This
allows material to be considered as no longer hazardous and subject to RCRA
Subtitle C control.
-Groundwater treated in situ would not trigger LDRs, however, if
groundwater is removed and then treated, it needs to meet the MCL for arsenic (50
ug/1 at the time ROD was signed) in order for the groundwater to no longer
"contain" hazardous waste per the "contained-in policy". Groundwater meeting the
MCL for arsenic could be disposed onsite on land or surface water subject to
meeting applicable surface water criteria.
In addition, the ROD provides an good explanation of EPA's "delisting"
authorities and when NDDEP needs to be involved with a delisting petition
(Offsite disposal in ND) and when another RCRA authorized State may need to be
involved (Offsite disposal in another state) in the "delisting" petition process.
EPA discussed the delisting process for soil, groundwater and sediment but did
not mention treatment derived sludge (Derived-From-Rule).
EPA does have provisions in RCRA to formally petition for delisting of a waste
(40 CFR 260.22). As we discussed, this is an intensive effort to seek a
determination from EPA and the RCRA authorized state that a waste may be
fdelisted.J I also checked 40 CFR 261, Appendix IX, Table 2 to determine if any
other pesticide facilities had successfully fdelisted-" a treatment sludge and did
not find any. There are some facilities from non-specific sources (Appendix IX-
Table 1) that have obtained criteria and were successful in delisting a waste
that contained arsenic but again, these were not pesticide facilities.
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Concerns with attempting to Delist Water Treatment Sludge in order to allow
disposal at a RCRA Subtitle D landfill:
1. The ROD states for OU #2 that: "The arsenic-contaminated sludge from the
groundwater treatment process will be transported off-site for hazardous
waste treatment and disposal." For OU #3 & #4: "The sludge from the
extraction process will be transported off-site for hazardous waste
treatment and disposal." Although the ROD clearly anticipated the
possibility of fdelisting-" the soil, sediment and groundwater, it does not
include a discussion about delisting the sludge. My concern with this is
if changing the waste classification of the sludge would be considered a
''significant-' change or a ''fundamental-' change. This would be the
difference of whether EPA would need to issue an BSD or have to do a ROD
amendment. My concern with doing a ROD amendment for this site is based
on the fact that the MCL for arsenic in groundwater is now 10 ppb instead
of 50ppb. Furthermore, NDDEQ has promulgated their soil remediation
treatment standards (N.D.A.C. 7:26D) and these could all be potential
issues if a ROD amendment is determined by EPA to be necessary. It was
noted that the treatment standard for arsenic in soil appears to be
consistent with the existing ROD cleanup criteria.
2. It is understood that the treatment sludge does not fail TCLP for arsenic
and is not a characteristic hazardous waste (D004). Furthermore if you
look at the LDRs (40 CFR 268.40), the treatment standard for K031, non-
wastewater is meet 5.0 mg/1 TCLP. Therefore the TSDF does not have to
perform additional chemical treatment (e.g. stabilization) on the sludge
prior to this material being placed in Subtitle C landfill. It might
require treatment for free liquids if that is an issue.
3. There could be a potential cost savings if the arsenic containing
treatment sludge is not a K031 listed hazardous waste because the tipping
fees for a Subtitle D landfill versus Subtitle C landfill are typically
less than half the cost. In addition, there is a potential transportation
cost savings if there is a Subtitle D landfill closer to the Vineland
site. In addition, if the treatment sludge is not a RCRA hazardous waste,
there may be saving in preparing the shipments in accordance with EPA and
DOT regulations. However, it must be fully understood, re-opening the ROD
could present EPA with significant issues on the cleanup criteria since
there has been a significant change in the MCL for arsenic.
4. The process necessary to formally petition for a delisting determination
is an effort that could take over a year. The process described in 40 CFR
260.22 is specific on the information that must be submitted and it is not
certain that EPA and NDDEQ would approve the delisting petition.
Recommendation from the Regulatory Perspective:
Recommend that it be investigated whether it would be cost effective to perform
additional treatment on the arsenic-contaminated sludge to reduce the water
content in the arsenic containing sludge to reduce the tonnage of waste requiring
disposal at the RCRA Subtitle C landfill.
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ATTACHMENT I
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Attachment I
Summary of Water. Sediment and Soil Sampling and Analytical Program
Rationale for Analysis
Field SW/GW analyses (All field analyses performed on Total [un-
filtered] samples)
ured in the field bee
nange during sample storage/transport
h ferric oxide can be produced at the dischargeAdsorpfr'on of As onto ferric
e GW or spring discharge indicates possible migra
is about the physical appeara
GWfSW - All 0.45 rr
n Field Filtered, thus dissolved, (but not
acidified)
These GW and SW samples should be filtered with minimal exposure to air, particularly the GW and spring is
evaluate the potential presence of thi1
Dissolved Sulfide (D)
GW/SW - Totals, acidified in the field to pH<2 with HCI
(environmental grade)
NO Filtering, minimi
exposure into laboratory-supplied bottle containing sufficient HCI to achieve final pH <2
GW/SW - 0.45 micron Field Filtered w/o air contact (syringe/pressun
filtration, no head space) & acidified to pH<2 w/HCI (env'l grade)
0.45 micron Field Filter with minimal air exposure into laboratory-supplied bottle containing sufficient HCI to achieve final pH <2
Sediments/ Soil
les) and then take samples from both zones, if appropria
* Brooks Rand Labs does not have Oklahoma certif
(D)= Dissolved via field filtering with 0.45 rr
(T)= Total, NO filtering
C:\Vineland\Final RSE Report\Lily\Table02.xls
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