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30324414
Superfund
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UNITED STATES ENVIRONMENTAL PROTECTION AGENCYREGION VII
EMERGENCY RESPONSE AND REMOVAL
QUALITY ASSURANCE PROJECT PLAN for the REMOVAL ASSESSMENT
at the
ALBERT CITY SBA SITE ALBERT CITY. IOWA
CERCLIS I.D. No.: IAD984601039
FEBRUARY 1997
Ecology and Environment, Inc.
SUPERFUND TECHNICAL ASSESSMENT AND RESPONSE TEAM CONTRACT No: 68-W6-0012
TDD: S07-9701-044 PAN: 0438ACSFXX
A
ecology and environment, inc.International Specialists in the Environment
Cloverteaf Building 3, 6405 MetcalfOverland Park, Kansas 66202Tel: (913) 432-9961, Fax: (913) 432-0670
QUALITY ASSURANCE PROJECT PLAN FOR THE REMOVAL ASSESSMENT AT THE
ALBERT CITY SBA SITE ALBERT CITY, IOWA
CERCLIS ID No.: IAD984601039
PREPARED FOR THEEMERGENCY RESPONSE AND REMOVAL PROGRAM
SUPERFUND DIVISION U.S. EPA REGION Vn
February 26, 1997
Prepared by:
ECOLOGY AND ENVIRONMENT, INC.SUPERFUND TECHNICAL ASSESSMENT AND RESPONSE TEAM
Contract No.: 68-W6-0012 TDD No.: S07-9701-044
APPROVED:
E & E START Program Manager
EPA Site Manager
EPA Regional Quality Assurance Manager
Date
Date
Date
recycled paper
QUALITY ASSURANCE PROJECT PLAN FOR THE REMOVAL ASSESSMENT AT THE
ALBERT CITY SBA SITE ALBERT CITY, IOWA
CERCLIS ID No.: IAD984601039
PREPARED FOR THEEMERGENCY RESPONSE AND REMOVAL PROGRAM
SUPERFUND DIVISION U.S. EPA REGION Vn
February 26,1997
Prepared by:
ECOLOGY AND ENVIRONMENT, INC.SUPERFUND TECHNICAL ASSESSMENT AND RESPONSE TEAM
Contract No.: 68-W6-0012 TDD No.: S07-9701-044
APPROVED:
E & E START Project Manager
E & E START Program Manager
EPA Site Manager
Date
Date
Date
EPA Regional Quality Assurance Manager Date
TABLE OF CONTENTS
Section Pag®
1.0 PROJECT MANAGEMENT............................................................................................ 1-1
1.1 Distribution List..................................................................................................... 1-1
1.2 Project/Task Organization....................................................................................... 1-1
1.3 Problem Definition/Background............................................................................. 1-2
1.3.1 Site Background .......................................................................................... 1-2
1.3.2 Previous Investigations and Summary of Findings....................................... 1-2
1.4 Project/Task Definition .......................................................................................... 1-6
1.5 Quality Objectives and Criteria for Measurement Data......................................... 1-7
1.6 Special Training Requirements/Certification.......................................................... 1-8
1.7 Documentation and Records ......................................................... 1-8
2.0 MEASUREMENT/DATA ACQUISITION .................................................................... 2-1
2.1 Sampling Process Design and Methods Requirements............................................ 2-1
2.1.1 Soil Sampling On Site.................................................................................. 2-1
2.1.2 Soil Gas Survey............................................................................................ 2-2
2.1.3 Monitoring Well Installation, Development, Sampling, and Aquifer Testing 2-4
2.1.3.1 Monitoring Well Installation................................................... .. .. 2-4
2.1.3.2 Monitoring Well Borehole Sampling ............................................ 2-5
2.1.3.3 Well Development ......................................................................... 2-6
2.1.3.4 Monitoring Well Sampling............................................................. 2-6
2.1.3.5 Aquifer Testing............................................................................. 2-7
2.1.4 Drinking Water Sampling ........................................................................... 2-7
2.1.5 Air Sampling ............................................................................. 2-8
2.1.6 Storm Sewer Sampling ................................................................................ 2-8
2.2 Sampling Handling and Custody Requirements..................................................... 2-9
2.3 Analytical Methods Requirements............................................................................. 2-10
2.4 Quality Control Requirements..................................................................................2-10
2.5 Instrument/Equipment Testing, Inspection, and Maintenance Requirements..........2-10
2.6 Instrument Calibration and Frequency................................ 2-10
RO/LKM i 0438ACSFXX/9701044/F
TABLE OF CONTENTS
Section Page
2.7 Inspection/Acceptance Requirements for Supplies and Consumables ............. 2-11
2.8 Data Acquisition Requirements ............................................................................... 2-11
2.9 Data Management..................................................................................................... 2-11
3.0 ASSESSMENT/OVERSIGHT.......................................................................................... 3-1
3.1 Assessments and Response Actions......................................................................... 3-1
3.2 Reports to Management.......................................................................................... 3-1
4.0 DATA VALIDATION AND USEABILITY .................................................................... 4-1
4.1 Data Review, Validation, and Verification Requirements....................................... 4-1
4.2 Validation and Verification Methods................... 4-1
4.3 Reconciliation with User Requirements................................................................. 4-1
5.0 REFERENCES.......................................................................... 5-1
ATTACHMENTS................................................................................................... ..................... 5-1
Attachment 1: Figures
Figure 1. Site Location Map and Water Well Sample Locations
Figure 2. Site Map with Proposed Monitoring Well Locations
Figure 3. General Geologic/Hydrogeologic Column
Figure 4. Site with Proposed Soil Sampling Grid
Figure 5. Proposed Initial Soil Gas Sampling Locations
Figure 6. Monitoring Well Construction Details
Figure 7. Distribution System and Air Sample Locations
Figure 8. Storm Sewer Sample Locations
Attachment 2: Analytical Services Request Form
RO/LKM u 0438ACSFXX/9701044/F
1.0 PROJECT MANAGEMENT
1.1 Distribution List
The Ecology and Environment, Inc. (E & E), Superfund Technical Assessment and Response Team
(START) was tasked by the U.S. Environmental Protection Agency (EPA) Region VII Emergency
Response and Removal program, under Technical Direction Document (TDD) S07-9701-044 to prepare
and implement a Quality Assurance Project Plan (QAPP) for the Albert City SBA site in Albert City, Iowa.
Copies of the QAPP have been provided to the following:
EPA-Region VII Paul Doherty, START PO
Janice Kroone, OSC
Ernie Arnold, QA Manager
Ecology and Environment, Inc./START Bob Overfelt, Project Manager
Joe Chandler, QA Manager
Hieu Q. Vu, Program Manager
1.2 Project/Task Organization
Janice Kroone, on-scene coordinator (OSC) for the EPA, will serve as the site manager for the
activities described in this QAPP. She will be responsible for overall coordination of site activities,
ensuring implementation of the QAPP, and providing periodic updates to EPA regional management
concerning status of the project, as needed. Ernie Arnold, Region VII EPA Quality Assurance (QA)
manager, will be responsible for review and approval of this QAPP.
The field sampling team will be composed of four START members. Bob Overfelt will serve as the
project manager, with the other members to be selected at a future date. The START will be responsible
for calibration of sampling equipment, sample collection, field documentation, submittal of samples to the
Region VII EPA Laboratory in Kansas City, Kansas, and preparation of a summary report. Joe Chandler,
E & E QA manager, will provide technical assistance, as needed, to ensure QA issues are adequately
addressed.
RO/LKM 1-1 0438ACSFXX/9701044/F
1.3 Problem Definition/Background
1.3.1 Background
The Albert City SBA site is located on Orchard Street in the east-central portion of Albert City, Iowa
(see Figure 1, Attachment 1). The site is the location of the former Superior Manufacturing Company
(SMC), which manufactured various products on the property from 1924 to 1967. The primary product
was a line of grease guns. An estimated 17 million grease guns were manufactured by SMC during the
years of operation. Part of the production process required the use of degreasing solvents. Based on
analytical results of soil and ground water at the site, the primary solvent used was TCE (Reference 1).
The site is situated in a mixed commercial/residential area of Albert City (see Figure 2, Attachment
1). The nearest residence is located approximately 70 feet to the west of the former SMC plant property.
The Albert City-Truesdale School with 380 students is located approximately 100 feet northwest of the site
(Reference 1).
The site consists of two areas, including the former SMC plant property and the former SMC waste
storage area (see Figure 2, Attachment 1). The former plant property was used for manufacturing, which
included degreasing. The original plant building on the former SMC plant property has been razed and
the property now consists of a grass-covered open lot with a pole bam on the east portion. The former
SMC waste storage area was an open lot where waste metal shavings produced during the manufacturing
process were stored. The metal shavings were reportedly coated with oil and solvents when placed on the
ground. The former SMC waste storage area is currendy owned by the
three historical/museum buildings are on the property. These buildings include a garage used for storing
maintenance equipment, a museum annex building, and a historic school house (Reference 1).
1.3.2 Previous Investigations and Summary of Findings
Prior to the expanded site inspection (ESI) conducted by the E & E Technical Assistance Team for
$£.0 A- ; . a preliminary assessment (PA) and screening site inspection (SSI) in 1992 by IDNR;
and a site inspection (SI) in 1994 by IDNR. These investigations determined that tetrachloroethane (PCE),
TCE, and degradation products were present in soil and shallow ground water on site. TCE was
detected up to 570,000 milligrams per liter (qg/L) in shallow ground water on the former plant property
(Reference 1).
RO/LKM 1-2 0438ACSFXX/9701044/F
EPA in 1995, previous investigations of the site included a 1991 property assessment by
The ESI field investigation included collection of source (soil on site), soil off site, and ground water
samples. The on-site source soil sampling included collection of screening samples using an Organic
Vapor Analyzer (OVA) and selected laboratory confirmation samples. Based on the OVA results, VOC
contamination is present in an area approximately 100 feet by 200 feet on the former SMC plant property
and an area approximately 70 feet by 150 feet on the former SMC waste storage area. This screening was
not definitive, however, because all areas of VOC contamination were not defined and OVA results are
not contaminant specific. VOC contamination was detected in both areas at depths from 0 to 5 feet below
ground surface (BGS). PCE, TCE, and degradation products, including 1,1-dichloroethene (1,1-DCE),
cis-l,2-DCE, trans-l,2-DCE, and vinyl chloride, were the hazardous substances detected that are
attributable to the site. The highest VOC concentrations detected in on-site soil included cis-l,2-DCE at
40,000 micrograms per kilogram (/xg/kg); trans-l,2-DCE at 240 /xg/kg; PCE at 180 /xg/kg; TCE at 17,000
/xg/kg, and vinyl chloride at 1,400 /xg/kg. Concentrations of vinyl chloride detected in soil on site exceed
the EPA Cancer Risk Screening Concentration of 310 /xg/kg and the EPA Region III Risk-Based
Concentration (RBC) for residential soil of 340 /xg/kg (Reference 1).
The primary aquifer used for drinking water in the area is the glacial drift aquifer consisting of
approximately 400 feet of unconsolidated glacial deposits containing varying amounts of clay, silt, sand,
and gravel. The glacial deposits extend from the surface to approximately 400 feet BGS. All known wells
in the area, including the two Albert City municipal wells, are set in the glacial drift aquifer. Both
municipal wells are located approximately 1,600 feet northwest of the site. The depth to ground water in
the site area ranges from approximately 5.5 to 7 feet BGS. Shallow ground water flow in the immediate
area of the site is to the southeast and is apparendy controlled by a network of drainage tiles in the area.
Ground water flow direction in deeper intervals of the aquifer is unknown (Reference 1). Figure 3,
Attachment 1 illustrates the general geology and hydrogeology of the area.
To characterize shallow ground water on site, ESI samples were collected from temporary
Geoprobe® wells on site and existing monitoring wells at adjacent UST sites. Results indicated that the
shallow ground water underlying the site and the surrounding area has been impacted by VOCs from the
site. The highest concentrations of VOCs detected included 1,2-DCE at 22 /xg/L; cis-l,2-DCE at 23,000
/xg/L; trans-1,2-DCE at 62 /xg/L; PCE at 50 /xg/L; TCE at 23,000 /xg/L, and vinyl chloride at 13 /xg/L.
Concentrations of VOCs in that sample exceeded the respective MCLs for all compounds except trans-1,2-
DCE (Reference I).
RO/LKM 1-3 0438ACSFXX/9701044/F
Municipal wells and the distribution system samples were collected to determine whether the site is
impacting Albert City's water supply. It was found that Albert City municipal well # 1 contained TCE at
2 /xg/L in the primary sample and 1 /xg/L in the duplicate sample. The depth of municipal well # 1 is 190
feet BGS and it is located approximately 1,600 feet northwest of the site (see Figure 1). These concentra
tions are below the maximum contaminants level (MCL) of 5 /xg/L for TCE. Results of the municipal
water distribution sampling indicated that the sample collected from the Albert City Fire Station tap located
adjacent to the former SMC waste storage area contained TCE at 38 /xg/L and cis-l,2-DCE at 15 /xg/L.
The TCE concentration exceeded the MCL of 5 /xg/L. Water supply lines leading to the fire station are
constructed of PVC and lie under Orchard Street between the former SMC plant property and the former
SMC waste storage area. The water supply lines are buried approximately 5.5 feet BGS and the depth to
ground water is approximately 5 to 6 feet BGS in the area. This suggests that contaminants in the shallow
ground water have apparently degraded the distribution system's PVC piping underlying Orchard Street
and are entering the municipal distribution system (Reference 1).
Private wells outside the city limits were sampled to determine whether the site had impacted the
ground water in the area. TCE at 31 /xg/L and cis-l,2-DCE at 40 /xg/L were detected in the
residence's private well located approximately 0.75 mile^fitheast of the site. The TCE concentration in the.-well exceeded the MCL. The depth of ^^^Cwlll is 40 feet BGS. Due to the distances from
the site and because the ground water gradients in deeperm^rvals of the aquifer are unknown, attribution
of the contaminants in the municipal well and th^^/Well to the site is indefinite. In addition, it is unknown whether other potential sources may exisfnear these wells. An estimated 1,159 people are served
by the Albert City municipal well supply. There are approximately 456 people within a 4-mile radius of the site who obtain drinking watj^^om private wells. There are six other residences with private wells
located in the vicinity of thg$5^fc well (north and northeast of the site) and within 0.75 to 1.25 miles of
the site (Reference 1).
Surface water from the site is drained by storm drains located adjacent to the site. The storm drains
apparently drain both stormwater runoff and shallow ground water away from the area. Surface water
runoff flows through a series of underground drainage tiles for approximately 3.25 miles to the southeast
and enters a perennial stream. Due to the distance to the surface water from the site, no surface water or
sediment samples were collected as part of the ESI. However, during the ESI field work a city employee
reported that while recently excavating near the east side of the site a 10-inch diameter clay drainage pipe
was unearthed and accidentally broken. Inside the pipe black sludge with a strong volatile and petroleum-
like odor was observed. A sheen was also observed on the water in the drainage pipe (Reference 1).
RO/LKM 1-4 0438ACSFXX/9701044/F
Surface soil samples were collected during the ESI on and off site to establish contaminant concentra
tions and determine whether migration off site has occurred. It was found that VOCs are present on site
at both the former SMC plant property and the former SMC waste storage area. In addition, surface soil
samples collected at the nearest residence and at the background location contained cis-l,2-DCE at 12
jig/kg and 22 fig/kg, respectively. Vinyl chloride was detected in soil on the former SMC waste storage
area at concentrations exceeding the CR and RBC. Both site areas are readily accessible to the public.
The Albert City-Truesdale School with a student population of 380 is located approximately 100 feet to the
west of the site. Students from the school occasionally visit the historical buildings and museum on the
former SMC waste storage area. Approximately 830 people live within 1 mile of the site and 1,153 people
live within 4 miles of the site (Reference 1).
A removal assessment was conducted by START at the Albert City SBA site in Albert City, Iowa
from August 12 to 16, 1996. Sampling included wells, the municipal distribution system, the storm sewer,
and ambient air on site. Sampling of ground water included active private drinking water wells outside
Albert City, the two Albert City municipal wells, and private wells (active and inactive) in Albert City.
This ground water sampling was conducted because the ground water on site is known to be significantly
contaminated with TCE and its transformation products and previous ESI results indicated that a municipal
well and a private well located 0.75 miles northeast of the site contained TCE contamination. Additional
distribution system sampling was conducted because previous ESI results indicated that TCE was present
in a system sample collected at the fire station which is adjacent to the site. Sample results from the well
sampling and the distribution system sampling indicated no VOCs were present above detection limits,
including the samples collected at locations that had VOC contamination during the ESI. It was concluded
that this variance in sample results may be due to temporal and/or spatial changes in ground water
conditions and that additional periodic sampling is necessary to verify and monitor contaminant
concentrations (Reference 2).
Storm sewer water and sediment sample results indicate that VOCs attributable to the site are entering
the storm sewer to the east and west of the site. Sampling of the storm sewer outfall located 3.25 miles
south of the site indicated that no VOCs were present above detection limits. The storm sewer piping is
constructed of perforated piping that serves two functions: draining storm water and shallow ground water.
Because the piping is perforated, it was concluded that it may act as a conduit for water drainage that is
potentially facilitating the spread of contaminants through the system and to the shallow ground water
adjacent to the piping (Reference 2).
RO/LKM 1-5 0438ACSFXX/9701044/F
Air samples collected inside buildings (museum annex and historic school house) built or
reconstructed on top of the former SMC waste storage area indicated the presence of site-related VOCs,
including cis-l,2-DCE and TCE, in the ambient air. Concentrations of TCE in both buildings significantly
exceeded the Region III RBC for TCE in ambient air. These contaminants were also detected in surface
and subsurface soil samples previously collected around the buildings. Therefore, it was concluded that
site-related VOCs from the former SMC waste storage area are apparently being released to the ambient
air and are impacting the air inside two buildings on site. The buildings are museum buildings that are open
one day per week from Memorial Day through Labor Day and by appointment throughout the year
(Reference 2).
Currently, EPA is conducting periodic sampling of the municipal wells, selected private wells, sewer
sampling, and air sampling at the site. The last sampling event was conducted in December 1996. Not
all sample results have been received from the December sampling. Partial results from the storm sewer
sampling indicate that TCE and DCE are present in the storm sewer approximately 2,200 feet southeast
of the site. This indicates that contamination is migrating from the site in the storm sewer and because the
piping is perforated it may be releasing contaminants to the adjacent shallow ground water along the piping.
Because the site is located adjacent to a residential area and a school, residents and school children
can be exposed to contaminated soil on site via direct contact or inhalation. In addition, ground water at
the site is contaminated with VOCs and the extent of contamination has not been delineated. Albert City
acquires municipal water from two wells located 1,600 feet from the site and residents outside of the town
have private wells to supply their drinking water; therefore, if contaminants migrate in the ground water
to these drinking water sources residents could also be exposed to contaminants via ingestion.
1.4 Project/Task Description
The objectives of this project are to determine the extent and concentration levels of VOC-
contaminated soil on site and to determine whether levels exceed health-based action levels; determine the
extent and concentrations of ground water contamination on site and whether they exceed health-based
action levels; approximate the extent of soil vapor or ground water contamination off site to determine
whether it is migrating toward a drinking water source; and conduct an additional round of air, drinking
water, and storm sewer sampling at locations previously sampled or suspected of being impacted for
monitoring purposes. The resulting data will be used to determine whether the site poses a threat to
residents and to recommend further removal or response action.
RO/LKM 1-6 0438ACSFXX/9701044/F
Selected site-specific action levels have not been developed by EPA Region VII for the site. Table
1 presents general guideline values for action levels for the primary contaminants of concern based on the
Region VII Screening Table. The EPA Region VII analytical SOPs listed in Section 2.4 will provide
adequate detection limits for the soil, air, and water samples.
Table 1
GENERAL GUIDELINE ACTION LEVELS
Contaminant
Air RBC
IE-06 ug/M3
Soil RBC
IE-06
ug/kg
(resident)
Soil
Industrial
ug/kg
Soil Migration
to GW DAF 1
ug/kg
Tap
Water
ug/L
Tap Water
RAL
ug/L
Surface
Water
ug/L
Sediments
ug/kg
Acetone 370 2E+06 9E+D6 800 610 3,500 — —Benzene 0.23 630 1,400 2 0.39 100 46 57
2-Butanone -- — — — — ... — —Carbon disulfide 10 7,500 24,000 2,000 21 — -- —1,4-Dichlorobenzene 0.28 3,600 — 100 0.47 750 15 350
1,1 -Dichloroethylene 0.038 37 80 3 0.046 70 -- —1,2-Dichloroethylene (cis) 37 31,000 100,000 20 61 400 — —1,2-Dichloroethylene (trans) 73 78,000 270,000 30 120 600 — . —1,2-Dichloroethylene (mixture) 33 35,000 120,000 -- 55 — — —
sylbenzene 1,100 230,000 230,000 700 1,300 1,000 —nylene chloride 4.1 7,800 18.000 1 4.3 500 — —
Tetrachloroethylene (PCE) 3.3 5,400 17,000 3 1.1 70 120 530
Toluene 400 790,000 880,000 600 720 2,000 130 670
1,1,1 -T richloroethane 1,000 1E+06 3E+06 100 790 1,000 62 170
Trichloroethylene (TCE) 1.1 3,200 7,000 3 1.6 300 350 1,600
Vinyl chloride 0.0022 16 35 0.7 0.02 2 — —m-Xylene 730 320,000 320,000 10,000 1,400 -- — —o-Xylene 730 320,000 320.000 9,000 1,400 — — —p-Xylene -- 320,000 320,000 10,000 — — -- —
Xylene (M and/or P mixed) 730 320,000 320,000 10,000 1,400 40,000 — —KEY:
RBC = Region in Risk-Based ConcentrationRAL = Removal Action Level— = Not Listed
The field work will take 14 to 18 days to complete and will be initiated within 3 weeks of EPA’s
approval of this project plan.
1.5 Quality Objectives and Criteria for Measurement Data
The project data quality objective is to provide valid data of known and documented quality for the
area sampled to determine the area impacted by VOC contamination for comparison to the associated
action levels. The data quality indicators to be measured are identified below.
RO/LKM 1-7 0438ACSFXX/9701044/F
The goals for analytical precision and accuracy are described in Region VII EPA/ENSV SOP
3122.2C and will be applicable to this project. Representativeness will be addressed by collecting the
samples as described in this document. Comparability will be addressed by collecting, analyzing, and
reporting the data as described in this document. A completeness goal of 100 percent is required for this
project. Valid data are required to allow an appropriate decision regarding further action at this site.
1.6 Special Training Requirements/Certification
The only required formal training of site personnel will be the completion of a basic 40-hour health
and safety training course (Hazardous Waste Operations and Emergency Response [HAZWOPER]) and
annual refreshers of the same. Familiarization with sampling equipment and procedures will also be
necessary for the START sampling team.
1.7 Documentation and Records
START personnel will maintain a field logbook to record all pertinent activities associated with the
sampling event. Sample documentation will follow Region VII EPA/ENSV SOP 2130.3B: “Identification,
Documentation and Tracking of Samples”. Information pertaining to samples (i.e. sample dates, times,
matrix, location) collected during this project will be recorded on field sheets provided by Region VII EPA
Laboratory personnel (generated by the Labor and Sample Tracking System [LAST]).
Analytical information will be handled according to Region VII EPA/ENSV SOPs 2410: “LABO
Branch Data Management Procedures” and 2410.10A: “Analytical Data Submission Packages”.
RO/LKM 1-8 0438ACSFXX/9701044/F
2.0 MEASUREMENT/DATA ACQUISITION
2.1 Sampling Process Design and Methods Requirements
The sampling approach will be divided into six tasks: 1) Soil sampling on site; 2) Soil gas survey;
3) Monitoring well installation, development, sampling, and aquifer testing; 4) Drinking water sampling;
5) Air sampling; 6) Storm sewer sampling. Each of these tasks is discussed in detail in subsections 2.1.1
through 2.1.6.
2.1.1 Soil Sampling On Site
To delineate the areal and vertical extent of VOC-contaminated soil on site in the vadose zone and
to establish contaminant concentration levels, soil samples will be collected and then screened in the field
using a gas chromatograph (GC). Approximately 10% of the samples will be submitted for laboratory
analysis to confirm screening results. Samples will be collected from the former SMC plant property and
at the former SMC waste storage area. Properties adjacent to the storage area will also be sampled because
information indicates waste may also have been stored on those properties.
Initially, a grid with 30-foot spacing will be set up over the properties. Figure 4 illustrates the grid.
Samples will be collected at the grid centers from depth intervals of 0 to 2 feet and 3 to 5 feet BGS. A
maximum depth of 5 feet BGS will be sufficient to characterize the vadose zone soil contamination because
depth to ground water is approximately 5.5 to 6 feet BGS. Past experience at similar sites indicates that
a 30-foot grid spacing and the depth interval sampling will be sufficient to delineate the VOC contamination
for removal considerations. Grid spacing may be adjusted to a smaller spacing (e.g. 15 foot) in selected
locations depending on the results and need to more precisely define areas. It is estimated that
approximately 120 to 140 screening samples will be collected and 12 to 14 samples will be submitted for
laboratory confirmation.
Soil sampling procedures with a Geoprobe sampling unit will follow the Region VII SOP 2230.7A:
“Geoprobe Operations”. A sampling tube (2-foot length and 1-inch inside diameter with a disposable
inner acetate soil sampling sleeve) attached to the probe rod will be advanced through the soil to the
starting sampling depth. A 2-foot composite soil sample will be collected from 0 to 2 feet BGS and 3 to
5 feet BGS. Sample containers (40-mL VOA vials) will be filled immediately with aliquots collected along
the entire length of the sample core. In addition, the lithology of each sample will be logged. All soil
RO/LKM 2-1 0438ACSFXX/9701044/F
sampling will follow Region VII SOP 2230.3B: “ Sampling Soils for Determination of Volatile Organic
Compounds” and Region VII SOP 2231.12A: ERT tt 2012; “Soil Sampling”.
The samples will be screened on site with a GC, which will provide rapid real-time, semiquantifiable
results of the target VOCs. The GC will be calibrated to detect 1,2-DCE, TCE, and vinyl chloride, which
are the contaminants previously detected at the highest concentrations in the soil and ground water at the
site. The operation of the GC will follow Region VII SOP 2231.109A: ERT #2109; “Photovac GC
Analysis for Air, Soil Gas, Water & Soil”. Analytical documentation will consist of a sample printout with
the sample number or identifier, date, time, TDD number, and chromatographic results. A logbook will
be kept with entries pertaining to calibration, instrument settings, sample locations, and analytical results.
All confirmation samples will be submitted to the Region VII EPA Laboratory for VOC analyses. Table
2, on page 2-9, provides a summary of the proposed samples.
2.1.2 Soil Gas Survey
To delineate the extent of soil vapor contamination in the vadose zone in areas off site, a soil gas
survey will be conducted. A grid with an approximately 150 foot spacing will be set up surrounding the
site area in all directions. Grid spacing ranging from 100 feet to 300 feet has been used for soil gas
surveys at similar sites by START and has been adequate to delineate soil vapor contamination. A vertical
profile will be performed by collecting soil gas samples at various depths at a location near the site to
determine the optimum sample depth. Soil gas samples will be analyzed in the field using a GC. Once
the sample depth has been established, samples will be collected at the grid nodes. Initially, samples will
be collected at or near the site and then subsequent samples will be collected from the grid in areas where
soil vapor contamination is present and continue until the boundaries of soil vapor contamination are
defined. The specific locations and number of samples will be determined in the field, based on field
screening results. It is estimated a maximum of 35 soil gas samples will be collected. The approximate
locations of the grid nodes are illustrated on Figure 5. It is anticipated that locations will be adjusted based
on field conditions (i.e. access to property, buried utilities, buildings).
The soil type underlying the area consists of clayey glacial till, which may be dense and contain little
pore space for soil gas. If the soil pore space is insufficient, collection of adequate volume for soil gas
sampling may not be possible. If this occurs, soil samples from the vadose zone will be collected at the
grid locations in the manner described previously and screened for target VOCs.
RO/LKM 2-2 0438ACSFXX/9701044/F
Laboratory confirmation of the on-site analyses will include submittal of samples to the EPA Region
VII Laboratory. Confirmation samples for laboratory analysis will be collected and submitted for
approximately 10 percent (3 samples) of the soil gas or soil headspace screening samples. These sample
locations will be selected based on screening results, with a goal of confirming a range of concentrations.
Soil gas or soil sampling procedures, using the Geoprobe sampling unit will follow the Region VII
SOP 2230.7A: “Geoprobe Operations”. The techniques for collection of soil gas and soil samples are
briefly described below.
Soil gas samples will be collected by pushing successive 3-foot sections of (1-inch outside diameter,
0.75-inch inside diameter) steel rods with a disposable point into the subsurface using a hydraulically driven
Geoprobe. When the desired depth is attained, the rod sections will be raised approximately 6 inches.
Polyethylene tubing will be inserted inside the rod, threaded downward, and secured to the bottom section
with a hollow nipple attachment. The soil gas from the bottom of the rod will then be extracted through
the tubing using a vacuum pump and collected in a glass bulb for field screening or a Summa canister for
laboratory analysis. Summa canister samples will be collected in accordance with Region VII SOP
2231.704A : ERT#1704; Summa Canister Sampling.
Soil samples will be collected using a sampling tube (2-foot length and 1 inch inside diameter with
a disposable inner acetate soil sampling sleeve) attached to the probe rod. The tube will be advanced
through the soil to the starting sampling depth. A 2-foot composite soil sample will be collected. Sample
containers (40-mL VO A vials) will be filled immediately with aliquots collected along the entire length of
the sample core. All soil sampling will follow Region VII SOP 2230.3B: “ Sampling Soils for
Determination of Volatile Organic Compounds” and Region VII SOP 2231.12A: ERT # 2012; “Soil
Sampling”.
The.soil gas or soil samples will be screened on site with a GC providing rapid real-time,
semiquantifiable results of the target VOCs. The GC will be calibrated to detect 1,2-DCE, TCE, and vinyl
chloride, which are the contaminants previously detected at the highest concentrations in the soil and
ground water at the site. The operation of the GC will follow Region VII SOP 2231.109A: ERT #2109;
“Photovac GC Analysis for Air, Soil Gas, Water & Soil”. Analytical documentation will consist of a
sample printout with the sample number or identifier, date, time, TDD number, and chromatographic
results. A logbook will be kept with entries pertaining to calibration, instrument settings, sample
locations, and analytical results. All confirmation samples will be submitted to the Region VII EPA
Laboratory for VOC analyses. Table 2, on page 2-9, provides a summary of the proposed samples.
RO/LKM 2-3 0438ACSFXX/9701044/F
2.1.3 Monitoring Well Installation, Development, Sampling, and Aquifer Testing
As previously described, the static water level at the site is between 5 to 7 feet BGS and is within
unconsolidated glacial drift deposits that are approximately 400 feet thick. This aquifer is used throughout
the site area for municipal and private water supplies. No monitoring wells have been installed on the site
to determine the contaminants and concentration levels; however, monitoring wells do exist in the site
vicinity at three UST sites. Therefore, six (6) shallow (—15 to 20 feet BGS) monitoring wells will be
installed and sampled on the former SMC properties to establish contaminant concentrations and six (6)
existing monitoring wells will be sampled at the UST sites to determine whether contaminants attributable
to the site are migrating off site in the shallow portion of the aquifer. To evaluate vertical migration of
contaminants and gradients single deep wells (~ 30 to 35 feet BGS) will be collocated at 3 of the shallow
well locations. In addition, aquifer testing will be conducted to establish aquifer properties for evaluating
flow rates, gradients, contaminant transport, and to assess the feasibility of removal or remedial
alternatives.
Three shallow monitoring wells will be installed on the former SMC plant property. Two shallow
monitoring wells will be installed on the former SMC waste storage area. One shallow well will serve as
a background well and will be located north of the properties. One deep well will be located on the former
SMC waste storage area and two will be located on the former SMC plant property. The proposed
approximate well locations are illustrated on Figure 2. The existing UST monitoring wells that will be
sampled include three at the Buena Vista County UST site, two at REDACT?^ -■ UST site,
and one at ReDAC site. figure 2 also illustrates the locations of the UST wells.
2.1.3.1 Monitoring Well Installation
The nine unconsolidated monitoring well boreholes will be drilled with 4.25-inch inside
diameter (I.D.) hollow-stem augers. For the shallow wells the hollow stem augers will be advanced to
approximately 8 feet beneath the top of the static water table, where a 2-inch I.D. stainless steel (type 304)
monitoring well will be constructed. It will necessary to use stainless steel rather than PVC because TCE,
which will degrade PVC, is known to be present in the ground water at high concentrations (up to 570,000
ug/L). Continuous soil cores will be collected from each borehole using a 5-foot-long wire line core
barrel. The lithology of each soil core will be described and recorded by the on-site geologist. The hollow
stem augers will be used as a temporary casing for the construction of the monitoring wells, preventing the
collapse of natural formation materials around the well screen and casing. The deep wells will be drilled
and constructed using the same procedures.
RO/LKM 2-4 0438ACSFXX/9701044/F
Figure 6 illustrates the proposed monitoring well construction details. The well casing will be
constructed of 2-inch I.D. 304 stainless steel with flush-threaded joints. No solvents or glues will be used
as joining compounds. The bottom of the casing will terminate with 10 feet of stainless steel screen. The
shallow wells will have 8 feet of screen below and 2 feet of screen above the water table, to allow for
seasonal water table fluctuations. Based on geologic information, it is anticipated formation materials in
the screened interval will be clay till with minor amounts of silt, sand, and gravel. Therefore, the screen
will be factory slotted with a slot size of 0.006 inches. The annular space between the well screen and the
borehole wall will be backfilled with 40-140 mesh clean silica sand. The sand will be rounded to
subrounded and placed to a level at least one and up to 2 feet above the top of screen. A 2-foot thick
bentonite seal will be placed above the sand pack. The remainder of the annular space will be backfilled
with a portland cement bentonite (5% bentonite by weight) grout to within 2 feet of ground surface. All
backfilled materials will be placed in 5-foot lifts prior to retraction of the augers with a minimum of two
feet of materials remaining in the augers at all times. Each lift will be tagged for depth prior to retraction
of the augers. The well installation will be completed with a concrete plug in the upper 2 feet of the
borehole in which a flush-mounted steel protective outer casing with locking cap will be installed. A 3-
by 3-foot sloping concrete pad 4 inches thick will be constructed at ground surface to divert any surface
water away for the well head.
2.1.3.2 Monitoring Well Borehole Soil Sampling
Each of the nine monitoring wells will be drilled using 4.25-inch internal diameter (ID) augers
and continuous soil samplers. The unconsolidated materials will be continuously sampled and logged to
obtain lithology. Each continuous sample will be field screened in the field laboratory using procedures
described in section 2.1.1. One screening sample will be collected for each 5-foot interval (e.g. 0'-5', 5'-
10', 10'-15’ etc.) at each of the nine monitoring well locations resulting in up to 30 soil screening samples.
Approximately 10 percent (3 samples) of the screening samples will be submitted for laboratory
confirmation. Samples will be collected in accordance with Region VII EPA SOP #2230.3B “Sampling
Soils for Determination of Volatile Organic Compounds”. Each laboratory sample will be collected into
two 40-mL vials and cooled to 4°Celsius. Soil confirmation samples will be submitted to the Region VII
EPA Laboratory for VOCs analysis.
In addition, six soil samples will be collected from three monitoring well locations (one on the
former SMC waste storage area and two on the former SMC plant property) and submitted for grain size,
moisture content, and total organic carbon (TOC) analyses. The specific locations will be determined in
RO/LKM 2-5 0438ACSFXX/9701044/F
the field. Two samples will be collected at each location, including one sample from the vadose zone and
one sample from the screened portion of the aquifer. Results of these analyses will be used when
evaluating the feasibility of alternative remedies. These analyses will be performed by a laboratory under
subcontract to START. Table 2, on page 2-9, provides a summary of the proposed samples.
2.1.3.3 Well Development
Newly completed monitoring wells will not be developed for at least 24 hours after well
completion. Each well will be developed by surging and pumping or bailing until the well is visibly free
of sediment. In addition, the pH, temperature, and specific conductance will be monitored during the
development. Stabilization will be considered to have been achieved when the variation between three
consecutive readings is no greater than 10 percent. No acids, dispersing agents, or explosives will be used
to enhance well development. No water or other liquid will be introduced into the well other than
formation water from that well.
2.1.3.4 Monitoring Well Sampling
After stabilization of the water levels in each well, an electronic water level indicator will be
used to measure the depth to ground water. Before a ground water sample is collected, a minimum of three
volumes of the standing water column will be purged. Ground water temperature, pH , and conductivity
will be measured after each volume has been purged to ensure that stagnant water in the well is removed.
Analytical samples will be collected from each well using a dedicated bailer. The samples will be poured
direcdy from the bailer into the appropriate sample container.
A total of 15 ground water samples for VOCs will be collected from the nine newly installed
monitoring wells and the six existing UST monitoring wells (Table 2). The ground water samples will be
collected in accordance with Region VII SOP 2334.15A: “Ground Water Sample Collection”. The ground
water samples will be collected in four 40-mL VOA vials, preserved with hydrochloric acid to a pH less
than 2, and cooled to 4°Celsius. All monitoring well samples will be submitted to the Region VII EPA
Laboratory for lower detection limit (LDL) VOC analyses. In addition, three ground water samples will
be collected from three monitoring wells (one on the former SMC waste storage area and two on the
former SMC plant property) and submitted for total dissolved solids, hardness, pH, and sulfates analyses.
The specific locations will be determined in the field. Results of these analyses will be used when
evaluating the feasibility of alternative remedies. Table 2, on page 2-9, provides a summary of the
proposed samples.
RO/LKM 2-6 0438ACSFXX/9701044/F
2.1.3.5 Aquifer Testing
A slug test will be performed on selected wells including at least three (2 shallow and one deep)
on the former SMC plant property and two (one shallow and one deep) on the former SMC waste storage
area. The slug test will be performed by suddenly removing a slug (segment of solid PVC pipe) of known
volume and observing the recovery of the water surface to its original level. The slug will be removed
from the well as quickly as possible after measurements indicate that the water level has stabilized.
Depth-time measurements will commence immediately following removal of the slug (t=o) and will
continue until the water level returns to equilibrium conditions. The hydraulic conductivity will then be
estimated according to the following calculation:
K = r2 In (L/R)2 LT0
where:
K = hydraulic conductivity (ft/sec)
r = casing radius (ft)
L = length of open screen (or borehole) (ft)
R = filter pack (borehole) radius (ft)
T0= basic time lag (sec), where value of t on semilogarithmic plot of (H-h)/(H-H0) vs. t, when(H-h)/(H-H0) = 0.37.
H = initial water level prior to removal of slug
Hq= water level at t = 0
h = recorded water levels at t>0
The monitoring wells will be surveyed for elevation and the water levels will be measured to the
nearest 0.01 foot to determine precise ground water flow directions.
2.1.4 Drinking Water Sampling
As part of the continuing monitoring for the site, drinking water samples will be collected from wells
and the municipal distribution system at locations known or suspected to be impacted by the site. Samples
will be collected from five private wells, the two municipal wells, and at four distribution points. The
RO/LKM 2-7 0438ACSFXX/9701044/F
locations of the private wells and the municipal wells are illustrated on Figure 1. Three of the distribution
samples will be collected from the Albert City School and one from the Albert City Fire Department (see
Figure 7).
The drinking water samples will be collected in accordance with Region VII SOP 2334.10A:
“Drinking Water Sample Collection”. The samples will be collected in four 40-mL VOA vials, preserved
with hydrochloric acid to a pH less than 2, and cooled to 4°Celsius. All drinking water samples will be
submitted to the Region VII EPA Laboratory for LDL VOC analyses. Table 2, on page 2-9, provides a
summary of the proposed samples.
2.1.5 Air Sampling
Previous air samples collected in buildings on or adjacent to the former SMC storage area contained
elevated concentrations of TCE and cis-l,2-DCE. To determine whether other buildings near the site are
being impacted, three additional air samples will be conducted. Samples will be collected inside the two
nearest residences on Orchard Street west of the site and from the Albert City-Truesdale School. Figure
7 illustrates the proposed air sample locations.
Air sampling will be conducted with Summa canisters over a 10-hour sampling period, which will
run from approximately 0800 hours to 1800 hours. The evacuated canisters will be attached to a vacuum
pump to obtain a pressurized sample (filled to approximately 7 pounds-per-square-inch [psi]) to allow for
lower detection limits (as compared to subatmospheric pressure sampling). The air samples will be
collected in accordance with Region VII SOP 2231.704A: ERT #1704; “Summa Canister Sampling”.
Prior to sampling, the canisters will be cleaned according to Region VII SOP 2231.703A: ERT #1703;
“Summa Canister Cleaning”. Air samples will be submitted to the Region VII Laboratory for VOC
analysis. Table 2 summarizes the proposed samples.
2.1.6 Storm Sewer Sampling
As part of the continuing monitoring at the site, storm sewer water samples will be collected from
locations known to be impacted by the site. The storm sewers in Albert City are constructed of perforated
piping and serve two purposes: collection and draining storm water runoff; and draining of shallow ground
water. Samples previously collected from the storm sewer have contained TCE, 1,2-DCE, and vinyl
chloride. Three storm sewer water samples will be collected: one from the access on the southeast comer
of the former SMC plant property; one from the access located approximately 2,200 feet southeast of the
RO/LKM 2-8 0438ACSFXX/9701044/F
site; and one from the storm sewer outfall located approximately 3.25 miles south-southeast of the site.
Figures 2 and 8 illustrate the proposed sample locations.
The storm sewer water samples will be collected in accordance with Region VII SOP 2334.7A:
“Surface Water Sample Collection”. The samples will be collected in four 40-mL VOA vials, preserved
with hydrochloric acid to a pH less than 2, and cooled to 4°Celsius. All storm sewer water samples will
be submitted to the Region VII EPA Laboratory for low detection limit (LDL) VOC analyses. Table 2
provides a summary of the proposed samples.
Table 2
PROPOSED ANALYTICAL SAMPLE SUMMARYALBERT CITY SBA SITE, ALBERT CITY, IOWA
Media ScreeningSamples
LaboratorySamples
QC Samples TotalScreeningSamples
TotalLaboratory
SamplesField Blank Trip Blank Rinsate
‘Soil -170 17 — — 1 170 18
Soil Gas -35 3 — -- — 35 3
“Water ... *“29 1 1 — — 31
Air ... 3 ... 1 — ' — 4
Total 205 52 X 2 1 205 56
. Samples will be submitted for ROC Analysis.
KEY: *
**
***
Soil Samples include: • —140 screening from on site grid.• 30 screening from monitoring well boreholes.• 10% laboratory confirmation or 17 samples.
Water Samples include: • 9 from new monitoring wells.• 6 from existing UST monitoring wells.• 7 from private and municipal wells.• 4 from distribution system.
Three new monitoring well water samples will be submitted for total dissolved solids, hardness, pH, and sulfates analyses in addition
to VOCs.
NOTE: In addition to soil samples included on this table, 6 soil samples will be collected from monitoring well boreholes and submitted to a separate
laboratory for grain size, moisture content, and total organic carbon analyses.
2.2 Sample Handling and Custody Requirements
All water and soil samples will be placed into 40-mL VOA vials for VOC analysis. Air samples will
be collected in Summa canisters. All samples will be packaged and preserved according to Region VII
SOP 2130.4B: “Sample Container Selection, Preservation and Holding Times”. Documentation will follow
SOPs 2130.2A: “Field Chain of Custody for Environmental Samples” and 2130.3B: “Identification,
Documentation and Tracking of Samples”.
RO/LKM 2-9 0438ACSFXX/9701044/F
2.3 Analytical Methods Requirements
Laboratory analysis will follow EPA Region VII SOPs: 3230.1C “GC/MS Analysis of Volatile
Organic Compounds” for soil and sediment; 3230.9A “ GC/MS Analysis for Volatile Organic Compounds
at Drinking Water Levels” for water samples; 3230.4B “Analysis of Air Canister Samples for Volatile
Organic Compounds by GC/MS” for air samples; 3135.5A “pH Lab, Water” for selected water samples;
3135.3B “Sulfate in Aqueous Samples, Colorimetric, Automated, Methylthymol Blue for selected water
samples”; 2336.8A: “Determination of Water Hardness: EDTA Titrimeteric Method”. An analytical
services request (ASR) form has been attached to this report (Attachment 2).
2.4 Quality Control Elements
Quality control (QC) samples are required to verify the validity of analytical results and to assess
whether the samples may have been contaminated as a result of improper decontamination, container
contamination, preservative contamination, contamination during transport to or from the site, or laboratory
contamination.
QC for this sampling event will be provided through the use of a combination of trip blank, field
blank, and rinsate samples. A total of three (3) QC samples will be collected during the field activities.
These QC samples include one trip blank (water), one field blank, and one rinsate sample from the
Geoprobe soil-sampling apparatus. The trip blank will remain in the sample coolers at all times, as a
measure of identifying contamination exposure during sample transport. The QC samples will be analyzed
for VOCs only. Laboratory quality control elements, including laboratory spikes and blanks, will be
performed in accordance with the previously referenced analytical SOPs and SOP 1610.1C: “Regional
Laboratory Quality Control Policy”.
2.5 Instrument/Equipment Testing, Inspection, and Maintenance Requirements
For the analytical instrumentation, the testing, inspection, and maintenance will be performed in
accordance with the referenced analytical SOPs and manufacturers’ recommendations.
2.6 Instrument Calibration and Frequency
Calibration of the field screening and laboratory analytical instrumentation will be in accordance with
the referenced SOPs and manufacturers’ recommendations.
RO/LKM 2-10 0438ACSFXX/9701044/F
2.7 Inspection/Acceptance Requirements for Supplies and Consumables
No special requirements are needed.
2.8 Data Acquisition Requirements
No data from other sources will be used .
2.9 Data Management
All laboratory data acquired by the Region VII Laboratory will be managed in accordance with
Region VII EPA/ENSV SOPs 2120.2A: “Document Control” and 2410. IB. Screening data generated in
the field will be recorded in a laboratory logbook and chromatograms from each sample will be generated
and filed.
RO/LKM 2-11 0438ACSFXX/9701044/F
3.0 ASSESSMENT/OVERSIGHT
3.1 Assessment and Response Actions
Because of the short duration of this sampling event, no field audits of sampling procedures will be
performed. Assessments and response actions pertaining to analytical phases of the project are addressed
in Region VII EPA/ENSV SOP 1610.1C and 1640.1A and in the previously referenced analytical
SOPs/methods. Those documents identify out-of-control conditions, who is responsible for initiating
corrective actions, and what corrective steps should be taken.
3.2 Reports to Management
Laboratory results will be reported to the EPA site manager (by laboratory personnel) in accordance
with Region VII EPA/ENSV SOP 2110. IB: “Labor and Sample Tracking (LAST) at ENSV”. A letter
report describing the sampling techniques, locations, problems encountered (with resolutions to those
problems), and interpretation of analytical results will be prepared by START and submitted to the EPA,
following completion of the field activities described herein and receipt of validated laboratory data.
RO/LKM 3-1 0438ACSFXX/9701044/F
4.0 DATA VALIDATION AND USABILITY
4.1 Data Review, Validation, and Verification Requirements
Data review and verification will be preformed by a qualified laboratory analyst and the laboratory’s
section manager, as described in Region VII EPA/ENSV SOPs 1610.1C and 1640.1A. The EPA site
manager will be responsible for overall validation and final approval of the data, in accordance with the
projected use of the results.
4.2 Validation and Verification Methods
The data will be validated in accordance with Region VII EPA/ENSV SOPs 1610.1C and 1640.1A.
QC spot checks will be performed by Region VII EPA Laboratory personnel, following criteria outlined
in Region VII EPA/ENSV SOPs 1640.1A and 1610.5A: “Quality Control Spot Checks of Regional
Laboratory Data Packages”. The EPA site manager will inspect the data to provide a final review and
approval before they are entered as valid data into the LAST system.
4.3 Reconciliation with User Requirements
If data quality indicators do not meet the project’s requirements as oudined in this QAPP, the data
may be discarded, and resampling and/or re-analysis may occur (as deemed by the EPA site manager).
RO/LKM 4-1 0438ACSFXX/9701044/F
5.0 REFERENCES
1. Ecology and Environment, Inc., START, July 1996, Expanded Site Inspection Report for the Albert City SBA site Albert City, Iowa, Overland Park, Kansas.
2. Ecology and Environment, Inc., START, November 1996, Removal Assessment Report Albert City SBA Site, Albert City, Iowa, Overland Park, Kansas.
ATTACHMENTS:
1. Figures
Figure 1. Site Location Map and Water Well Sample Locations
Figure 2. Site Map with Proposed Monitoring Well Locations.
Figure 3. General Geologic/Hydrogeologic Column
Figure 4. Site with Proposed Soil Sampling Grid
Figure 5. Proposed Initial Soil Gas Sampling Locations
Figure 6. Monitoring Well Construction Details
Figure 7. Distribution System and Air Sample Locations
Figure 8. Storm Sewer Sample Location.
2. Analytical Services Request Form
RO/LKM 5-1 0438ACSFXX/9701044/F
ATTACHMENT 1
FIGURES
RO/LKM 0438ACSFXX/9701044/F
ALBSTLOC.CDR
Figure 1: SITE LOCATION AND WATER WELL SAMPLE LOCATIONS
EXPLANATION
<>Storm Sewer Drop Inlets
Shallow Monitoring Well
UST Monitoring Well
♦ Deep Monitoring Well
Razed Building
Other Structures
V
aW°aU
(u£55IDQ.ao
<>Historic
Train Station
□ Museum
Building
p
Shop Q_O
CD
Buena Vista County Maintenance Facility
Former Pump H<j>i
♦
fr, HistoricSchool House
1rMuseumAnnex
EBGarage
<>
Albert City Fire Station
use £55"E (0 ■C o
Former SMC Waste
Storage Area
Former Superior Manufacturing Company Plant Building
<>
♦
<>♦
<ua55cto
Second Avenue
SCALE TDD: S07-9701-044 Albert City SBAAlbert City, Iowa
0 200PAN: 0438ACSFXX
Prepared by STM L.J.Baer
100 100 February 1997Source: Reference 1.
ALBMWELL.CDR
Figure 2: SITE MAP WITH PROPOSED MONITORING WELL LOCATIONS
# 4? 3£ & <£> a & &
<C<r SECTION
E III! = mi = mi 9
s&
isg
*■* GENERAL LITHOLOGY
Wisconsin glacial drift (Cary Till)
Dakota Sandstone (Nishnabotna Member)
■0k±-&krr-it
38&9£-cf
rri':c(?^r-5-;dl?^rrs*.-tf
Base of Kinderhookian
o
Lime Creek Formation
Shell Rock Formation
Ceder Valley Limestone
7i-i) rrr
~i.~r~i.~C~i.~T
MaquoketaFormation
GalenaFormation
Decorah Formation
Platteville Form.Glenwood Formation =rT=^=-~ unk
St. Peter Sandstone
Prairie du Chien
Formation
JordanSandstone
St. Lawrence Formation
iu£L'H=-u_li— i — i i ~t=t
W-WVri"i ‘ i l \ |,~t
i 'i i.7=£
yyjy-./y
WV/7/
‘TT'TT'T^rujxi'iriz
rrtiTH‘rII I / 2rfTrrrrrJ~7~
mrnn:T-r ,7V ! I ~rV7WVIII) I 77/
-5 Soil
400
0-
20
0-
20
350
unk
unk
unk
unk
unk
unk
unk
unk
HYDROLOGY KEY
Predominantly till, and poorly-sorted to well-sorted gravel, sand, silt and clay
Massive sandstone, medium to fine-grained, with shale interbedsSiltstone
Gray shale, argillaceous limestone or dolomite
Dolomite and limestone
Silty or argillaceous dolomite and limestone
Shale and dolomite
Dolomite and shale
ShaleShale and shaly dolomite
Shale and oolitic ironstone
Quartz sandstone
Argillaceous dolomite and dolomitic sandstone
Quartz sandstone
Dolomite with some silt and shale
Approximately 350 feet of Cambrian age (?) rock.
^7
Undifferentiated
Dolomite and dolomitic sandstone
Metamorphic and igneous rock
SurficialAquifer
Aquifer
Aquifer
Aquitard
Aquifer
Aquitard
Aquifer
Aquitard
Aquifer
Unknown
Soils
SWevaiO.evc
Sandy Clays/ Clayey Sands
Sandstone or Sands
Shale or Clays
TTTTTI ,"l, T
Albert City SBA TDD: S07-9701-0441 Albert City, Iowa PAN: 0438ACSFXX■f; ecology and environment, inc. Prepared by STM L.J.Baer
February 1997
ALBHYDRO.CDR
Source: Iowa Geologic Survey Water Supply Bulletin No. 13, 1983, and Iowa Geologic Survey Misc. Map Series 10, 1984.
Figure 3: GENERAL GEOLOGIC/HYDROGEOLOGIC COLUMN
• Geoprobe Soil Boring Location
EXPLANATION
Razed Building Q3 Other Structures
Albert City SBAAlbert City, Iowa
0
SCALE (feet)
200
TDD: S07-9701-044PAN: 0438ACSFXX
Prepared by STM L.J.BaerFebruary 1997
100 100 Source: Reference 1.
ALBSSMPL.CDRFigure 4: SITE MAP WITH PROPOSED SOIL SAMPLING GRID
ALB_SGAS.CDR
Figure 5: PROPOSED INITIAL SOIL GAS SAMPLING LOCATIONS
^ ecology and environment, inc.Albert City SBA Albert City, Iowa
TDD: S07-9701 -044PAN: 0438ACSFXX
Prepared by STM L.J.Baer February 1997
WELLNEST.CDR
Figure 6: MONITORING WELL CONSTRUCTION DETAILS
KEY TO SAMPLE LOCATIONS
7= Distribution Samples ★ Air Samples
© Albert City School (300 Orchard) © Albert City School (300 Orchard)© Albert City School (300 Orchard) 205 Orchard(3) Albert City School (300 Orchard) @ Fire Department
7 201 Orchard
□□□
□ ‘□ E
□ □□ D
-------rr □
□ j Rn
Grape Street
07"
7= ®
□cPD0
□ na.. u -
□ □ P
LP
A
Vine Street
SCALEAlbert City SBAAlbert City, Iowa
0 400
200 200
Source: Sidwell Maps, 1995.
TDD: S07-9701-044PAN: 0438ACSFXX
Prepared by STM L.J.BaerFebruary 1997
.FIG7.CDR
Figure 7: DISTRIBUTION SYSTEM AND AIR SAMPLE LOCATIONS
ALBOFALL.CDR
Figure 8: STORM SEWER SAMPLE LOCATIONS
ATTACHMENT 2
ANALYTICAL SERVICES REQUEST FORM
RO/LKM 0438ACSFXX/9701044/F
USEPA Region VII Analytical Services Request (ASR) Form
Activity No.: Date:______________________2/26/97Site Name, City, & State:Albert City SBA, Albert City,_IowaProject Manager: Janice Kroone_____________________________
Section/Branch:_£HEE: Phone No. :_____________________551-7005Contractor Contact: Bob OverfeltContractor: E&E Phone No.:______________________ 432-9961Projected Sample Delivery Date: April 11, 1997 Funding Program Element: Superfund• - -- -------- 1 1 ------ - ..... 1 -......... -■.......... ...................... - ■■ —«Request gnimwary;
No. of Samples
Matrix Group/Parameter Name Group/Parameter MGPCode
31 water LDL VOCs W13
18 soil VOCS SV
3 water sulfate, pH, hardness WT12,WG2 3,WG31
7 Air VOCs HV
Use additional pages as needed for clarity.Levels Of Interest Are Specified (mark one) : In The QA Document-CH or - X see attached list
Special Bnijiii i-arnantn nr rommont-n ;
Field Sheets and tags are requested.
Approval a;
EPA Project Manager (Date) EPA Branch or Section Chief (Date)
The Following Tb Pomp)atari By ENSV Personnel ONLYQA Document: □ -Generic QAPP □ -Site Specific QAPP □ -Other:__________________
Concurrences :
RQAM: Comment:
Chief, LABO:______________Laboratory Assignment:
Comment:________Scheduled Completion:
□ -Region VII
□-ESAT______
□-CLP_______
□-RECAP_____
□-Other_____
□-Routine:• Non-CLP = 4 weeks• CLP = 8 weeks
□ -Other:_____________
Date:
Distribution;■ EPA Project Manager
■ Chief, LABO/ENSV
□ Chief, GNAN/LABO
□ Chief, ORGN/LABO
■ Chief, CLPM/LABO
■ Data Coordinator
■ RSCC
□ Other:
{Revised February 1993)
USEPA Region VII Sampling Supplies Request (SSR) Form
Activity No.:_________ Site Name: Albert City SBAr Albert City, Iowaitact Name: Janice Kroone Telephone No. : 551-7QQ5
Date Equipment to be Picked Ups_____ March 28, 1997_____ ____________
Them nnaeription Amount Needed
Sample Containers:4-oz. (100 ml) Plastic Bottle....................................... • • -----1-Liter Plastic Cubitainer ............................................. .....4-Liter Plastic Cubitainer............................................. ..:8-Liter Plastic Cubitainer ............................................. .....20-Liter Plastic Cubitainer ............................................. .....40-ml Glass Vials (Routine - 2 ea in 1-1 cubie with charcoal thimble) ......... .....40-ml Glass Vials (Low DL - 4 ea in 1-1 cubie with charcoal thimble) ........ .....8-oz. (250 ml) Wide Mouth Glass Jar...................................... .....32-oz.(l Liter) Wide Mouth Glass Jar .................................... .....8-oz. (250 ml) Amber Glass Bottle....................................... .....80-oz. (2.5 Liter) Amber Glass Bottle .................................... .....4-Liter Amber Glass Bottle ............................................. .....
Sampling Supplies:Sampling Spoons ............................................................... .... ___________Aluminum Pans........................................................................... ...........
1-qt. (1 Liter) Metal Paint Can (with Vermiculite®)............................................ :1-gal. (4 Liter) Metal Paint Can (with Vermiculite®) ............................. ...........
Other:___Snmma Canisters....................... ........................................ ....... !_1___other:___Air pumps for Snmma Canisters................................................ ....... 4___
->sarvatives: (return preservative containers to the laboratory)
HC1 (1:1)............................................................. ........................................................................ .........1 Bottle.HNO, (1:1) .................................................................................................................................. ........................HjSO, (Concentrated) ...................................................... ........... ..............NaOH (Pellets) ........................................................................ ...........
Other: PI Water.......................................................................... ..... 1 GallonOther: Ascorbic Acid............................. ....................................... ..1 Bottle
Shipping Supplies:Large Plastic Bags (ice chest liner) .................................... ....Ice Chests.......................................................... ....Fiber Tape (by roll) ........................................................Custody-Seal Tape (by piece, not roll) ................. ................. ......Chain-Of-Custody Forms ................................................ ....Storage Bags for Chain-Of-Custody Forms ............... ................. ....Packing Foam...............................................................
Quality Control Samples:Water Trip Blanks (VOA only) ........................................... ...-LSoil Trip Blanks (VOA only)............................................. ....
Performance Evaluation (PE) Samples:
No. of PE Samples Matrix Target Analytes
Desired;Concentration
Range
II1(Revised Pebruery 1993)