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2013 Site Monitoring Report
Prepared for: U.S. Environmental Protection Agency
Region IX
Prepared by:
NIBW Participating Companies
February 28, 2014
i
CONTENTS
Page ANNUAL SITE MONITORING REPORT .................................................................. 1 1.0 GROUNDWATER MONITORING PROGRAM .................................................. 3
1.1 GROUNDWATER LEVEL MONITORING ................................................. 3 1.2 GROUNDWATER QUALITY MONITORING ............................................. 7 1.3 CONTINGENCY ACTIONS ..................................................................... 10 1.4 GROUNDWATER PRODUCTION DATA ................................................ 11
2.0 GROUNDWATER REMEDIATION PROGRAM .............................................. 13 2.1 GROUNDWATER REMEDIATION AT THE CENTRAL GROUNDWATER
TREATMENT FACILITY .......................................................................... 14 2.1.1 2013 Overview ............................................................................. 15
2.2 GROUNDWATER REMEDIATION AT THE MILLER ROAD TREATMENT FACILITY ................................................................................................. 16 2.2.1 2013 Overview ............................................................................. 16 2.2.2 Operational Summary for October through December 2013 ....... 18
2.3 GROUNDWATER REMEDIATION AT THE NIBW GRANULAR ACTIVATED CARBON (GAC) TREATMENT FACILITY .......................... 19 2.3.1 2013 Overview ............................................................................. 19
2.4 GROUNDWATER REMEDIATION AT AREA 7 ....................................... 22 2.4.1 2013 Overview ............................................................................. 22 2.4.2 Operational Summary for October through December 2013 ....... 24
2.5 GROUNDWATER REMEDIATION AT AREA 12 ..................................... 25 2.5.1 2013 Overview ............................................................................. 26 2.5.2 Operational Summary for October through December 2013 ....... 27
3.0 SOIL REMEDIATION PROGRAM .................................................................. 28 4.0 EVALUATION OF NIBW REMEDIAL ACTION PERFORMANCE ................. 30
4.1 ASSESSMENT OF GROUNDWATER MONITORING PERFORMANCE STANDARDS .......................................................................................... 30 4.1.1 Optimization of Long Term UAU Groundwater Monitoring
Program ....................................................................................... 30 4.1.2 Assessment of MAU Source Control Performance Measures ..... 31 4.1.3 Assessment of LAU Groundwater Containment Performance
Measures ..................................................................................... 32 4.2 ASSESSMENT OF GROUNDWATER CONTAINMENT PERFORMANCE
STANDARDS .......................................................................................... 33 4.2.1 Evaluation of UAU Mass Flux ...................................................... 33 4.2.2 Evaluation of MAU/LAU Hydraulic Containment .......................... 34 4.2.3 Evaluation of Area 7 MAU Source Area Program ........................ 37 4.2.4 Evaluation of Area 12 MAU Source Area Program ...................... 41 4.2.5 Evaluation of Northern LAU Hydraulic Capture ........................... 43 4.2.6 Evaluation of Need for Modeling Analyses .................................. 46
ii
CONTENTS (continued)
Page 4.3 ASSESSMENT OF GROUNDWATER TREATMENT PERFORMANCE
STANDARDS .......................................................................................... 47 4.3.1 Evaluation of the Central Groundwater Treatment Facility .......... 48 4.3.2 Evaluation of the Miller Road Treatment Facility ......................... 48 4.3.3 Evaluation of the NIBW GAC Treatment Facility ......................... 49 4.3.4 Evaluation of the Area 7 Groundwater Treatment System .......... 50 4.3.5 Evaluation of the Area 12 Groundwater Treatment System ........ 51
4.4 PROGRESS TOWARD ACHIEVEMENT OF REMEDIAL ACTION OBJECTIVES .......................................................................................... 52
4.5 MANAGEMENT OF UNTREATED GROUNDWATER ............................ 57 5.0 SUMMARY ...................................................................................................... 62 6.0 DOCUMENTS SUBMITTED IN 2013 .............................................................. 64
TABLES Table
1 SUMMARY OF GROUNDWATER LEVEL MEASUREMENTS TAKEN
BY TERRANEXT, NORTH INDIAN BEND WASH AREA, SCOTTSDALE, ARIZONA, APRIL 2013
2 SUMMARY OF GROUNDWATER LEVEL MEASUREMENTS TAKEN
BY TERRANEXT, NORTH INDIAN BEND WASH AREA, SCOTTSDALE, ARIZONA, OCTOBER 2013
3 SUMMARY OF GROUNDWATER LEVEL DIFFERENCE BETWEEN
OCTOBER 2012 AND OCTOBER 2013, NORTH INDIAN BEND WASH AREA, SCOTTSDALE, ARIZONA
4 2013 LABORATORY RESULTS FOR GROUNDWATER
MONITORING WELLS, NORTH INDIAN BEND WASH SUPERFUND SITE, SCOTTSDALE, ARIZONA
5 2013 LABORATORY RESULTS FOR GROUNDWATER
EXTRACTION WELLS, NORTH INDIAN BEND WASH SUPERFUND SITE, SCOTTSDALE, ARIZONA,
6 SUMMARY OF 2013 MONTHLY GROUNDWATER PRODUCTION,
NORTH INDIAN BEND WASH AREA, SCOTTSDALE, ARIZONA
iii
CONTENTS (continued)
TABLES Table
7 SUMMARY OF ANNUAL GROUNDWATER PRODUCTION FROM
1991 THROUGH 2013, NORTH INDIAN BEND WASH AREA, SCOTTSDALE, ARIZONA
8 SUMMARY OF 2013 NIBW EXTRACTION WELL PUMPAGE AND
ESTIMATED TCE MASS REMOVED, NORTH INDIAN BEND WASH AREA, SCOTTSDALE, ARIZONA
9 2013 LABORATORY RESULTS FOR TREATMENT SYSTEM
SAMPLES, NORTH INDIAN BEND WASH SUPERFUND SITE, SCOTTSDALE, ARIZONA
10 SUMMARY OF VOC MASS ESTIMATES IN UAU GROUNDWATER
FOR OCTOBER 2013, NORTH INDIAN BEND WASH SITE, SCOTTSDALE, ARIZONA
11 AVERAGE TCE CONCENTRATIONS FOR MONITOR WELLS
WITHIN ZONE OF HYDRAULIC CAPTURE, MIDDLE ALLUVIUM UNIT, AREA 7
12 AVERAGE TCE CONCENTRATIONS FOR MONITOR WELLS
WITHIN ZONE OF HYDRAULIC CAPTURE, MIDDLE ALLUVIUM UNIT, AREA 12
iv
CONTENTS (continued)
FIGURES Figure
1 WELL LOCATION MAP
2 GROUNDWATER LEVEL CONTOURS, MIDDLE ALLUVIUM UNIT
WELLS, APRIL 2013
3 GROUNDWATER LEVEL CONTOURS, LOWER ALLUVIUM UNIT WELLS, APRIL 2013
4 GROUNDWATER LEVEL CONTOURS, UPPER ALLUVIUM UNIT
WELLS, OCTOBER 2013
5 GROUNDWATER LEVEL CONTOURS, MIDDLE ALLUVIUM UNIT WELLS, OCTOBER 2013
6 GROUNDWATER LEVEL CONTOURS, LOWER ALLUVIUM UNIT
WELLS, OCTOBER 2013
7 CHANGE IN UPPER ALLUVIUM UNIT GROUNDWATER LEVEL, OCTOBER 2012 TO OCTOBER 2013
8 CHANGE IN MIDDLE ALLUVIUM UNIT GROUNDWATER LEVEL,
OCTOBER 2012 TO OCTOBER 2013
9 CHANGE IN LOWER ALLUVIUM UNIT GROUNDWATER LEVEL, OCTOBER 2012 TO OCTOBER 2013
10 CONCENTRATION OF TCE IN UPPER ALLUVIUM UNIT WELLS,
OCTOBER 2013
11 CONCENTRATION OF TCE IN MIDDLE ALLUVIUM UNIT WELLS, OCTOBER 2013
12 CONCENTRATION OF TCE IN LOWER ALLUVIUM UNIT WELLS,
OCTOBER 2013
13 CONCENTRATION OF TCE IN UPPER ALLUVIUM UNIT WELLS, OCTOBER 2001 – OCTOBER 2013
v
CONTENTS (continued)
Figure 14 CONCENTRATION OF TCE IN MIDDLE ALLUVIUM UNIT WELLS,
OCTOBER 2001 – OCTOBER 2013
15 CONCENTRATION OF TCE IN LOWER ALLUVIUM UNIT WELLS, OCTOBER 2001 – OCTOBER 2013
16 ANNUAL WELL PRODUCTION – 2013
17 LOCATIONS FOR EXTRACTION WELLS, PIPELINES, AND
TREATMENT FACILITIES, NIBW SUPERFUND SITE
18 TOTAL MASS OF VOLATILE ORGANIC COMPOUNDS IN SATURATED PORTION OF UPPER ALLUVIUM UNIT
19 ESTIMATED HYDRAULIC CAPTURE OF ZONE OF MIDDLE
ALLUVIUM UNIT PLUME, OCTOBER 2013
20 ESTIMATED HYDRAULIC CAPTURE OF ZONE OF LOWER ALLUVIUM UNIT PLUME, OCTOBER 2013
21 WATER LEVELS, TCE CONCENTRATIONS, AND ESTIMATED
HYDRAULIC CAPTURE, UPPER MIDDLE ALLUVIUM UNIT, VICINITY OF AREA 7, OCTOBER 2013
22 FIVE-YEAR RUNNING AVERAGE TCE CONCENTRATIONS, UPPER
MIDDLE ALLUVIUM UNIT, VICINITY OF AREA 7
23 WATER LEVELS, TCE CONCENTRATIONS, AND ESTIMATED HYDRAULIC CAPTURE, UPPER MIDDLE ALLUVIUM UNIT, VICINITY OF AREA 12, OCTOBER 2013
24 FIVE-YEAR RUNNING AVERAGE TCE CONCENTRATIONS, UPPER
MIDDLE ALLUVIUM UNIT, VICINITY OF AREA 12 25 WATER LEVELS, TCE CONCENTRATIONS, AND ESTIMATED
HYDRAULIC CAPTURE, NORTHERN LOWER ALLUVIUM UNIT, OCTOBER 2013
26 DISTRIBUTION OF PUMPING IN VICINITY OF PV PUMPING
CENTER
vi
CONTENTS (continued)
APPENDICES Appendix
A ROLES AND RESPONSIBILITIES FOR NIBW SUPERFUND SITE REMEDIAL ACTIONS
B NORTHERN LAU CONTINUOUS WATER LEVEL MONITORING
GRAPHS, 2013
C WATER LEVEL HYDROGRAPHS AND TCE TIME-SERIES DATA FOR NIBW MONITOR, PRODUCTION AND EXTRACTION WELLS
D 2013 INSPECTION REPORT, GROUNDWATER TREATMENT
FACILITIES E ANNUAL GROUNDWATER PRODUCTION AND TCE TIME-SERIES
DATA FOR NIBW EXTRACTION WELLS
vii
LIST OF ACRONYMS
ADEQ Arizona Department of Environmental Quality ADHS Arizona Department of Health Services ADWR Arizona Department of Water Resources AF acre-feet AFY acre-feet per year APP Aquifer Protection Permit AWC Arcadia Water Company AWQS Aquifer Water Quality Standard AZPDES Arizona Pollutant Discharge Elimination System CD Consent Decree CGTF Central Groundwater Treatment Facility CERP Contingency and Emergency Response Plan CMR Compliance Monitoring Report COC Contaminant of Concern COS City of Scottsdale COT City of Tempe CWTP Chaparral Water Treatment Plant DCE 1,1- dichloroethene DMR Discharge Monitoring Report EPA U.S. Environmental Protection Agency ESD Explanation of Significant Differences FSA Feasibility Study Addendum GAC Granular Activated Carbon gpm gallons per minute GMEP Groundwater Monitoring and Evaluation Plan GWETS Groundwater Extraction and Treatment System IOP Interim Operating Plan LAU Lower Alluvial Unit MAU Middle Alluvial Unit MCESD Maricopa County Environmental Services Department MCL Maximum Contaminant Level MG Million Gallons MRL Method Reporting Limit MRTF Miller Road Treat Facility NGTF NIBW Granular Activated Carbon Treatment Facility NIBW North Indian Bend Wash O&M Operation and Maintenance PCE Tetrachloroethene PCs Participating Companies PE Performance Evaluation PV Paradise Valley PVARF Paradise Valley Arsenic Removal Facility RAO Remedial Action Objective ROD Record of Decision SAP Sampling and Analysis Plan
viii
LIST OF ACRONYMS (Continued)
SCMP Start-Up and Commissioning Monitoring Plan SMR Site Monitoring Report SOW Statement of Work SRP Salt River Project SVET Soil Vapor Extraction and Treatment TCA 1,1,1-trichloroethane TCE Trichloroethene TCM Chloroform UAU Upper Alluvial Unit UIC Underground Injection Control UV/Ox Ultraviolet Oxidation VOC Volatile Organic Compound µg/L microgram per liter
ANNUAL SITE MONITORING REPORT January - December 2013
North Indian Bend Wash Superfund Site
Scottsdale, Arizona
This 2013 Site Monitoring Report (SMR) summarizes remedial activities
performed and data collected by the North Indian Bend Wash Participating
Companies (i.e., Motorola Solutions, Inc., Siemens, and GlaxoSmithKline) and Salt
River Project (SRP) pursuant to the Amended Consent Decree, CV-91-1835-PHX-
FJM, entered by the U.S. District Court for the District of Arizona on June 5, 2003. A
detailed summary of the components and work requirements of the remedial action
program can be found in the Record of Decision Amendment – Final Operable Unit,
Indian Bend Wash Area (Amended ROD), dated September 27, 2001 and
Statement of Work (SOW), Appendix A to the Amended Consent Decree (Amended
CD). An organizational chart identifying the key parties involved in the North Indian
Bend Wash (NIBW) Superfund Site is provided in Appendix A along with current
personnel having assigned roles and responsibilities for operations and emergency
response.
Additional information describing remedial activities conducted at the NIBW
Site in 2013 was provided in Quarterly Reports submitted to the U.S. Environmental
Protection Agency (EPA) and Arizona Department of Environmental Quality (ADEQ)
on May 30, August 28, and November 27, 2013. Consistent with requirements
defined in the Amended CD and SOW, the 2013 SMR includes operational
summaries and updates for fourth quarter 2013.
This 2013 SMR presents a summary and overview of compliance monitoring
data acquired to demonstrate performance of the remedial action program. In
conjunction with development of the 2013 SMR, the NIBW Participating Companies
(PCs) and SRP have compiled compliance monitoring data, laboratory analytical
2
reports, quality assurance reports, and other monitoring data required by the
Amended CD, SOW, governing work plans, and agency requests. Accordingly,
supplemental data reports will be issued as part of this SMR under separate cover.
The supplemental data reports will be submitted as electronic files on compact disks
and include:
Laboratory analytical reports and a quality assurance report issued by SRP
for sampling and analysis conducted for the 2013 NIBW Groundwater
Monitoring Program during January 2013.
Level IV data analytical reports and a quality assurance report issued by
TestAmerica (primary NIBW laboratory analytical contractor) for analysis of
compliance process water samples obtained in 2013 at NIBW groundwater
treatment systems and for analysis conducted for the 2013 NIBW
Groundwater Monitoring Program. The NIBW groundwater treatment systems
report will also include NIBW Granular Activated Carbon Treatment Facility
(NGTF) summary of start-up sampling results from TestAmerica, results of
the NIBW PCs annual audit activities at TestAmerica, summary of
performance evaluation sample results, and Level IV data analytical report
issued by Trans West Analytical Services, LLC (dba XENCO Laboratories,
and back-up NIBW laboratory analytical contractor) for split sampling
conducted at the Area 7 Groundwater Extraction Treatment System
(GWETS).
Technical Memorandum and TestAmerica laboratory analytical reports for
inorganic water quality samples collected from four (4) Area 7 Upper Alluvium
Unit (UAU) wells and the Area 7 GWETS effluent sample port.
2013 air sampling data summary and Air Toxics final laboratory reports.
3
1.0 GROUNDWATER MONITORING PROGRAM
Groundwater monitoring at the NIBW Superfund Site includes collection,
analysis, and reporting of extensive water level, water quality, and production data
from a network of groundwater monitor, extraction, and production water wells
completed in the Upper Alluvium Unit (UAU), Middle Alluvium Unit (MAU), and
Lower Alluvium Unit (LAU). Locations of monitor, extraction, and production wells in
the vicinity of the NIBW Site, including 30 UAU monitor wells abandoned in 2013,
are shown on Figure 1. Groundwater monitoring requirements for the NIBW Site
are specified in the Groundwater Monitoring and Evaluation Plan (GMEP), approved
by the EPA on October 8, 2002. The GMEP was prepared by the NIBW PCs and
defines the: 1) scope and frequency of monitoring activities; 2) requirements for data
reporting and preparation of interpretive work products; 3) approach to conducting
groundwater model updates; and 4) performance criteria, achievement measures,
contingency initiation criteria, and contingency response actions for evaluation of the
on-going effectiveness of remedial actions. With the exception of the first quarterly
sampling round (January 2013), which included samples for 20 MAU and LAU
monitor wells that were analyzed by SRP Environmental Laboratory, Test America,
Inc. was the Analytical Laboratory Supervising Contractor for NIBW Site
groundwater monitoring program activities during 2013. SRP was the Groundwater
Monitoring Program Supervising Contractor for the NIBW Site until the role was
transitioned to Terranext in April 2013. Appendix A contains contact information,
roles, and responsibilities for parties involved in key aspects of the NIBW Site
remedial actions.
1.1 GROUNDWATER LEVEL MONITORING
Groundwater level monitoring was conducted semi-annually in a network of
75 monitor wells in April and 106 monitor wells in October 2013. Water level
measurements obtained and reported by Terranext in April and October are
summarized in Tables 1 and 2, respectively. As approved by EPA and ADEQ, a
total of 30 UAU monitor wells were abandoned during August 2013 to January 2014,
4
as shown on Table 2. Additionally, water level monitoring for the UAU has been
discontinued for April and will be conducted annually in October at the remaining
network of 28 UAU monitor wells into the future. April 2013 water level contour
maps for the MAU and LAU, are shown on Figures 2 and 3, respectively. October
2013 water level contour maps for the UAU, MAU, and LAU, are shown on
Figures 4, 5, and 6, respectively.
In addition to periodic water level monitoring conducted at unit-specific
monitor wells, continuous water level monitoring was conducted at a group of six
LAU monitor wells and one extraction well in the vicinity of the EPCOR (referred to
as the Paradise Valley [PV] well field) as part of the enhanced northern LAU
monitoring program. Hydrographs showing continuous water level data for wells in
the northern LAU monitoring program are provided in Appendix B. Additional
continuous water level data was obtained during 2013 at selected MAU monitor
wells as part of the Work Plan for Area 7 Middle Alluvial Unit Source Control,
Proposed Actions in Response to Non-Conformance with Performance Measures,
dated April 12, 2013, as described in Section 4.2.3.
Pumping, chiefly in the MAU and LAU, influences water levels and patterns of
groundwater movement in the three alluvial units. The principal pumping centers
are discussed in Section 1.3. While introduced in Section 1.3, Table 6, which
summarizes monthly pumping for wells in the vicinity of the NIBW Site, may be a
helpful reference in regards to the water level discussion below.
Based on the October 2013 water level contour map (Figure 4), direction of
groundwater movement in the UAU is from east to west across much of the
monitored area but, flows generally in a northeast to southwest pattern in the area
north of Thomas Road. UAU groundwater migrates toward the southwest margin of
the Site, where it moves vertically into underlying units. In October 2013, UAU
horizontal hydraulic gradients, expressed as feet per foot (unitless), are fairly
consistent across the Site, ranging from about 0.0025 in the north to about 0.0033 in
the south.
5
The complex pattern of groundwater movement observed in the MAU results
from competing influences between the various pumping centers and the western
margin, where vertical movement into the LAU occurs. April 2013 water level data
depicted in Figure 2, indicate that four distinct cones of depression associated with
MAU pumping occur in the vicinity of: 1) production wells COT-6 and COS-25,
2) Area 12 GWETS wells, 3) Central Groundwater Treatment Facility (CGTF) wells
and Area 7 GWETS wells, and 4) Arcadia Water Company (AWC) wells.
October 2013 water level data displayed in Figure 5 shows that patterns of
groundwater movement were generally similar to those observed in April, except
that: 1) in the south, a more prominent cone of depression has developed in the
vicinity of production wells COT-6 and COS-25 due to the added pumping at SRP
well 22.5E,5.5N, and 2) to the north, the cone of depression formed by CGTF and
Area 7 extraction wells is less elongated to the east due to discontinuation of
pumping at COS-31 in October.
In the south part of the Site, horizontal hydraulic gradients ranged from about
0.021 in April, when only COT-6 and COS-25 were pumping, to 0.046 in October,
when pumping at SRP well 22.5E,5.5N was added. In the north part of the Site,
where groundwater migrates toward the Area 7 and CGTF extraction wells,
horizontal gradients ranged from about 0.027 in April, when the cone of depression
was more spread out due to pumping at COS-31, to 0.040 in October, when
pumping was discontinued at COS-31 and the cone of depression became more
pronounced in the area south from Area 7. In the area between the southern and
northern pumping centers, where water migrates toward the western margin,
horizontal hydraulic gradient was very low – about 0.0023 in both April and
October 2013.
Groundwater movement in the LAU is generally from recharge areas in the
south and southwest parts of the Site to points of discharge at extraction and
production wells to the north, as shown for April and October 2013 on Figures 3
and 6, respectively. Numerous wells, including CGTF extraction wells, Miller Road
Treatment Facility (MRTF) extraction wells (PV-15 and PV-14), NGTF extraction well
PCX-1, and production wells operated by SRP, AWC, EPCOR, and the City of
6
Scottsdale (COS) withdraw groundwater from the LAU throughout the NIBW Site.
The combined cone of depression (or depressions, in April 2013) created by
pumping at MRTF extraction wells, PCX-1, and nearby SRP and PV production
wells represents a regional sink for LAU groundwater. While patterns of
groundwater movement in the southern half of the Site are fairly consistent for both
monitoring periods in 2013, contours in the north are somewhat different. This is
due to the fact that combined pumping from the MRTF and PV wells was
significantly higher in October compared with April. Pumping was also occurring at
SRP well 22.6E,10N (adjacent to PV-14) in October, whereas this well was shut
down in April. Horizontal hydraulic gradients generally increase from south to north
toward extraction well COS-75A, and then decrease sharply in the area down-
gradient from COS-75A (Figures 3 and 6). Horizontal hydraulic gradients ranged
from a maximum of about 0.013 in April and 0.016 in October in the area
immediately upgradient from CGTF extraction well COS-75A to a minimum of about
0.0035 in April and 0.0031 in October in the area between extraction wells COS-75A
and PCX-1.
Change in groundwater levels over time is evaluated by comparing recent
and long-term water level data trends at UAU, MAU, and LAU monitor wells.
Table 3 summarizes the difference in water level between October 2012 and
October 2013 for all monitor wells included in the 2013 water level monitoring
program. Differences are illustrated using bar graphs on Figures 7 through 9 for
the UAU, MAU, and LAU, respectively. Wells are arranged based on location (north
to south) rather than by name both in Table 3 and on the associated illustrations. It
should be noted that water level differences computed at individual wells using
October 2012 and October 2013 data are representative of changes between two
point measurements. Changes observed between these two points in time may not
be reflective of long-term trends. In addition, water level changes on the order of
10 feet or more observed in monitor wells adjacent to extraction wells are attributed
to production well cycling rather than to water level conditions in the aquifer. Water
level data trends are more accurately tracked by reviewing a larger set of water level
data obtained over a longer time period. Hydrographs showing water level data for
the 10-year period from 2004 through 2013 for wells included in the monitoring
program are provided in Appendix C.
7
In the time period from October 2012 to October 2013, water levels generally
declined slightly in UAU monitor wells (Figure 7). While the large water level
decline measured at PG-19UA may be reflective of pumping at nearby production
well SRP well 22.5E,5.5N, this data point, along with the measurement reported for
PG-10UA, may alternatively be anomalous. Water level declines were observed
between October 2012 and October 2013 at most MAU monitor wells, although the
magnitude of the decline increased from north to south at the Site (Figure 8). This
trend is believed to be due to a significant increase in pumping at COT-6 in October
relative to April, and startup of pumping at SRP well 22.5E,5.5N just prior to the
October 2013 monitoring round. In the LAU, declines were noted between
October 2012 and October 2013 at all monitor wells and the magnitude of decline
generally increased from north to south across the Site. This trend is also believed
to be attributed to pumping of COT-6 and SRP well 22.5E,5.5N to the south
(Figure 9). The net effect of water level change ranged from: 1) a decline of
10.73 feet to a decline of 2.19 feet in the UAU (excluding data from wells PG-10UA
and PG-19UA), 2) a decline of 64.02 feet to a rise of 4.42 feet in the MAU, and 3) a
decline of 14.29 feet to a decline of 1.11 feet in the LAU between October 2012 and
October 2013.
1.2 GROUNDWATER QUALITY MONITORING
Groundwater quality monitoring of volatile organic compounds (VOCs)
designated as NIBW contaminants of concern (COCs), including trichloroethene
(TCE), tetrachloroethene (PCE), 1,1,1-trichloroethane (TCA), 1,1-dichloroethene
(DCE), and chloroform (TCM), was conducted in accordance with requirements of
the GMEP. Water quality monitoring for the five NIBW COCs for 2013 included the
following components:
monthly sampling (when operating) at the four (4) CGTF extraction
wells, three (3) MRTF extraction wells (until PCX-1 was disconnected) and one (1) NGTF extraction well (when PCX-1 was connected);
quarterly sampling (when operating) at the two (2) remaining Area 7 extraction wells, two (2) Area 12 extraction wells, and at a network of 21 MAU and LAU monitor wells;
8
semi-annual sampling at three (3) LAU monitor wells; and,
annual sampling at all of the wells noted above plus an additional 64 UAU, MAU, and LAU monitor wells.
Monthly and quarterly groundwater quality monitoring is generally conducted
during the first week of the month, beginning in January. The annual groundwater
quality monitoring program is conducted in October.
A summary of laboratory results of VOCs for NIBW monitor wells for 2013 is
provided in Table 4. Production and extraction well VOC results are summarized in
Table 5. As evident from the data, TCE is the principal COC at the site and is,
therefore, depicted in SMR plume maps and time-series graphs. TCE concentration
contours for October 2013 for the UAU, MAU, and LAU are shown on Figures 10,
11, and 12, respectively. Hydrographs, showing TCE concentrations and water
levels for the 10-year period from 2004 through 2013, are shown for all monitor wells
in Appendix C. Changes in magnitude and extent of TCE between the baseline
dataset, which is defined as October 2001, coinciding with the release of the
Amended ROD, and October 2013, the current monitoring period, are shown for the
UAU, MAU, and LAU on Figures 13, 14, and 15, respectively.
TCE concentrations in UAU monitor wells are consistently low and continuing
to decrease over time, with a maximum concentration in October 2013 of
9.1 micrograms per liter (g/L) detected at monitor well PG-22UA. This well is
located west of Area 12 (Figure 10). The occurrence of TCE concentrations in UAU
groundwater at or in excess of the Federal Maximum Contaminant Level (MCL)1 of
5 g/L is limited to three (3) monitor wells located in discrete zones down-gradient
from Area 12. Data from October 2013 continue to demonstrate that TCE
concentrations in all UAU monitor wells down-gradient from Area 7 are below the
5 g/L MCL. The magnitude of TCE concentrations in UAU groundwater has
decreased significantly with time, as reflected in Appendix C hydrographs. Based
on recent data, TCE concentration trends are continuing to decline at two of the
1 As set forth in the Amended ROD, cleanup standards for all NIBW COCs except chloroform are equivalent to MCLs adopted by EPA pursuant to the Safe Drinking Water Act (42 U.S.C. §§ 300f-300j-11). The chloroform cleanup standard is 6 g/L.
9
three UAU monitor wells that remain above the MCL of 5 g/L. The aerial extent of
the UAU plumes has also decreased over time, as depicted in Figure 13, which
compares the extent of TCE concentrations in UAU groundwater observed in
October 2001 and October 2013. The area of impact, as defined by the TCE
plumes in the UAU, has decreased by 85 percent from October 2001 to
October 2013.
TCE concentrations in MAU groundwater are generally higher than in the
other two units, with a maximum concentration of 4,000 g/L detected in
October 2013 at monitor well W-2MA, which is located down-gradient from Area 7
(Figure 11). The maximum concentration of TCE detected in October 2013 in the
vicinity of Area 12 was 85 g/L at monitor well M-6MA. The third area of elevated
TCE concentrations in MAU groundwater coincides with the location of single
monitor well, PG-6MA, located in the vicinity of the southwest margin, where the
TCE concentration was 170 g/L in October 2013. While longer term decreases in
TCE concentrations have been observed at many MAU monitor wells, more recent
trends are stable to slowly declining at most MAU wells (Appendix C). Changes in
the extent of TCE concentrations in MAU groundwater observed between
October 2001 and October 2013 are generally small (Figure 14). Some notable
decreases in TCE concentrations have occurred in the area south and down-
gradient from Area 7 due to implementation of the source control program
(Figure 11 and Appendix C). It should be noted that the extent of the west flank of
the MAU plume is more accurately represented in maps generated after the
October 2001 baseline, due to the availability of data at monitor well M-17MA/LA
following its installation in 2002.
TCE concentrations in LAU groundwater are intermediate between the UAU
and the MAU, with a maximum concentration of 240 g/L detected in October 2013
at monitor well PA-6LA (Figure 12). The highest concentrations of TCE in LAU
groundwater occur in the north-central part of the Site. Changes in the magnitude
and extent of TCE concentrations in LAU groundwater observed between
October 2001 and October 2013 are generally small (Figure 15). A predictable
migration of the LAU plume to the north in response to the regional gradient
(Figure 6) and implementation of the LAU groundwater remedy through extraction at
10
CGTF, NGTF, and MRTF is being tracked. The western migration of the LAU TCE
plume in the vicinity and north from S-2LA is being closely monitored and will be
discussed in the following section and in Section 4.2.2.
As shown on the Appendix C hydrographs, TCE concentrations have
declined substantially in most monitor and extraction wells in the south portion of the
LAU plume due to mass removal at extraction wells and the influx over time of UAU
groundwater with progressively lower TCE concentrations. Monitor and extraction
wells in the north plume area have historically shown increasing TCE concentration
trends due to anticipated migration of LAU mass toward PCX-1 and the MRTF
extraction wells. Recently, increasing concentration trends in the northernmost part
of the LAU appear to be slowing and leveling off to some extent. This encouraging
trend is attributed to active management of pumping at PCX-1, PV-14, and PV-15,
as well as other PV wells north of the MRTF, in accordance with the optimal plume
containment strategy.
1.3 CONTINGENCY ACTIONS
Water quality data obtained in 2013 indicate that TCE concentrations
observed at monitor wells S-2LA and PG-42LA and extraction well PV-14 exceeded
GMEP metrics associated with groundwater containment of the LAU plume. With
respect to the quarterly sampling of northern LAU monitor wells, well PG-42LA
exceeded the GMEP performance metric of 2 g/L TCE in the first quarter only,
whereas well S-2LA exceeded the GMEP performance metric of 15 g/L TCE during
each of the four quarterly sampling rounds. The results of monthly sampling
conducted at extraction well PV-14 indicate TCE concentrations exceeded the
GMEP performance criterion of 2 g/L for this well for November and December
2013.
Similar GMEP exceedances and trends were observed and reported at wells
S-2LA, PG-42LA, and PV-14 in 2011, triggering contingency response actions and
preparation of three separate Technical Memoranda, which were summarized in the
2011 SMR. Subsequently, the NIBW PCs proposed, in a letter dated May 24, 2012,
11
to suspend further contingency response actions until the NIBW Technical
Committee could reassess GMEP performance measures and, as appropriate,
establish updated metrics. EPA agreed to the temporary suspension of contingency
response actions in an email dated June 1, 2012, but asked for continued reporting
of data to the Technical Committee. The NIBW PCs have kept EPA and other
members of the NIBW Technical Committee informed of northern LAU performance
metrics through the course of monthly NIBW meetings.
1.4 GROUNDWATER PRODUCTION DATA
Monthly data for total groundwater production were compiled for all wells that
pump at rates higher than 35 gallons per minute (gpm) and are located in the area
bounded by Indian Bend Road on the north, one mile south of McKellips Road on
the south, Dobson Road on the east, and Invergordon Road on the west. Monthly
production data for 2013 are summarized in Table 6. Annual well production data
for 1991 through 2013 are summarized in Table 7, and 2013 well production data is
shown on Figure 16. Production data were obtained from municipal and private
water providers, SRP, and Arizona Department of Water Resources (ADWR).
Review of monthly production data (Table 6) indicates seasonal trends in
pumping in response to fluctuations in demand for groundwater. In general,
maximum production for municipal demand corresponds to summer months while
minimum production for municipal demand corresponds to winter months.
Combined monthly pumping for all wells at the NIBW Site ranged from 1,393 acre-
feet (AF), which is equivalent to about 454 million gallons (MG), in January 2013 to
3,429 AF (about 1,117 MG) in July 2013.
Review of the spatial distribution of groundwater production for 2013
(Figure 16) indicates the presence of several pumping centers. The predominant
pumping center is associated with the PV well field, located along the Arizona Canal
in the vicinity of McDonald Road. Total production for 2013 at the six PV wells was
10,250 AF (3,340 MG). SRP well 22.5E,9.3N (also known as PCX-1, which was
treated at the MRTF and NGTF in 2013) and SRP well 22.6E,10N pumped a total of
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3,072 AF (1,001 MG) and 210 AF (68 MG) in 2013, respectively, and contribute to
the pumping center in this area. Pumping at PV and SRP wells in the northern LAU
results in a regional cone of depression that controls groundwater movement in the
LAU across the site. Extraction and treatment of TCE at key wells in this cone of
depression (PCX-1, PV-14 and PV-15) is critical to the LAU remedy.
Outside of the northern LAU pumping center described above, production at
the four CGTF extraction wells (COS-31, COS-71, COS-72, and COS-75A) is the
most significant pumping that occurs within the boundaries of the NIBW Site. Total
production for 2013 at the CGTF extraction wells was 5,847 AF (1,905 MG). Total
production for the four CGTF wells in 2012 was 6,721 AF (2,190 MG). Pumping
associated with the Area 7 and Area 12 groundwater extraction and treatment
programs is also fairly substantial, totaling 412 AF (134 MG) and 1,216 AF (396 MG)
for 2013, respectively. The AWC well field comprises another pumping center in the
vicinity of the NIBW Site. Total production for 2013 at the five (5) AWC wells, which
pump from the MAU and LAU, was 3,503 AF (1,142 MG). Finally, well COT-6, in
conjunction with adjacent wells SRP well 22.5E,5.5N and COS-25, comprises
another significant pumping center. A total of 1,554 AF (506 MG) was pumped from
COT-6 in 2013, principally from the MAU.
Table 7 summarizes annual groundwater production for wells in the vicinity of
the NIBW Site for the period 1991 through 2013. From 1991 through 1995, annual
groundwater production in the vicinity of the NIBW Site ranged from 18,887 AF
(6,154 MG) to 31,824 AF (10,370 MG). From 1996 through 2004, groundwater
production in the vicinity of the NIBW Site increased to an average of just over
40,165 AF (13,088 MG) per year. The increased groundwater withdrawals from the
mid-1990s correlate to, among other factors, implementation of the NIBW
groundwater remedy, which allowed water providers to return wells to service.
Additionally, groundwater pumping increased in this period due to dryer than normal
Arizona climatic conditions that predominated. In recent years, however,
groundwater production in this area has declined, averaging 29,893 acre-feet per
year (AFY) (9,740 MG) for the period from 2005 through 2013. The recent decline in
groundwater production is likely correlated to an increase in surface water supply
availability to users such as SRP and COS. In this same period, COS started up the
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Chaparral Water Treatment Plant (CWTP) to utilize SRP surface water supply and
shut down some local COS wells due to implementation of the revised arsenic
maximum contaminant level.
2.0 GROUNDWATER REMEDIATION PROGRAM
As provided by the Amended CD, the NIBW remedy requires containment of
the MAU/LAU plumes and restoration of groundwater to drinking water standards.
The groundwater remediation program consists of groundwater extraction and
treatment at the CGTF, MRTF, Area 7 GWETS, Area 12 GWETS, and NGTF.
Following completion of the post-construction operational prove-out period, NGTF
was initially started-up in July 2013. Commissioning of the NGTF was completed
during fourth quarter 2013. The locations of the five (5) GWETS are shown on
Figure 17. The NIBW PCs are responsible for operation of the Area 7 GWETS,
Area 12 GWETS, and NGTF; and COS is responsible for CGTF operations.
EPCOR Water USA (EPCOR), as owner of the MRTF, is responsible for operation
of treatment of water produced from wells PV-14 and PV-15.
A monthly summary of groundwater production and estimated TCE mass
removed from NIBW extraction wells is presented on Table 8. Mass removal
estimates for individual extraction wells are computed by using a single (or average)
TCE concentration value for each month or quarter in which a given well is in
operation, and the total pumping from that well during the associated monitoring
period.
To assure data quality and consistency associated with collection of
compliance monitoring data at the treatment plants, the NIBW PCs and COS have
contracted with TestAmerica (designated as primary analytical laboratory) and Trans
West Analytical Services, LLC (dba XENCO Laboratories and designated as back-
up to TestAmerica), both located in Phoenix, Arizona. TestAmerica and Trans West
Analytical are licensed by the Arizona Department of Health Services (ADHS) under
analytical laboratory license numbers AZ0728 and AZ0757, respectively. To help
14
assure laboratory performance and data quality, COS and the NIBW PCs conducted
its annual audit of TestAmerica on November 19, 2013.
The NIBW PCs coordinated inspections of Area 7 and Area 12 GWETS on
December 3, 2013 and MRTF, PCX-1, CGTF, and NGTF on December 4, 2013 in
accordance with Section VI.B.4.d of the SOW. The groundwater treatment and
extraction systems were inspected for malfunctions, deterioration, operator practices
or errors, and discharges that may be causing or could result in a release of
untreated groundwater. At each facility, the major system components were
identified and examined for operability, condition of operating equipment, and
management of untreated groundwater and residual materials. Additionally, data
related to routine operation, system startup and shutdown, routine and non-routine
maintenance, and sampling were made available for review during the inspections.
Representatives of EPA and ADEQ were present for the annual inspections at
MRTF, PCX-1, CGTF, and NGTF. Representatives of EPA were present for the
inspections at the Area 7 and Area 12 GWETS. No hazards, significant
deterioration, procedural or equipment malfunctions were noted in the course of the
inspections at the Area 7 and Area 12 GWETS, MRTF, CGTF, and NGTF that would
affect groundwater treatment performance standards or compliance with the
Amended CD/SOW. Additional details of the NIBW Site inspections are described in
the Inspection Report provided in Appendix E.
2.1 GROUNDWATER REMEDIATION AT THE CENTRAL GROUNDWATER
TREATMENT FACILITY
The CGTF was the first GWETS constructed at the NIBW Site. The CGTF is
located at 8650 East Thomas Road, as shown on Figure 17. As required by the first
NIBW Consent Decree, the NIBW PCs constructed the CGTF and transferred
ownership to COS on March 18, 1994, at which time the treatment plant came into
service. The NIBW PCs and COS subsequently modified the CGTF, and it has
operated continuously, except for scheduled maintenance shutdowns, since
December 1995 to treat groundwater according to EPA-approved design
specifications. The exemplary plant performance is demonstrated by thousands of
15
samples collected at the CGTF over the past 20 years to validate treatment
effectiveness for safe drinking water use. The data confirm all samples of treated
water meet clean-up goals and drinking water standards and are routinely below the
laboratory Method Reporting Limit (MRL) for the NIBW COCs.
Groundwater extraction is performed at four COS-owned or contract supply
wells designated as COS-31, COS-71, COS-72, and COS-75A (the CGTF extraction
wells). Extracted groundwater is pumped through approximately 18,000 feet of
buried transmission pipelines to the CGTF where it is treated by air stripping.
Treated groundwater from the CGTF is primarily used in the COS drinking water
system, but may be discharged to the SRP water distribution system via an irrigation
lateral.
COS owns and operates the CGTF and reports results of laboratory testing
and plant operations directly to EPA and ADEQ. A summary of the key operational
results follows. Detailed reporting of the 2013 operational status, laboratory data,
and system performance was provided by COS in CGTF Compliance Monitoring
Reports (CMRs) submitted on May 29, August 29, and November 21, 2013, and
February 21, 2014.
2.1.1 2013 Overview
During 2013, groundwater extraction tied into the CGTF contributed to
capture and containment of the MAU/LAU plume (as discussed in Section 4.2.2) and
treatment provided water for beneficial use that met groundwater treatment
performance standards (as discussed in Section 4.3.1).
COS reported that approximately 5,847 AF, or 1,905 MG, of groundwater
were pumped and treated at the CGTF in 2013. Of the total, 257 MG were extracted
from well COS-31, 370 MG from well COS-71, 169 MG from well COS-72, and
1,108 MG from well COS-75A. Based on extraction well data presented in Table 8,
an estimated 1,004 pounds of TCE were removed at the CGTF during 2013. VOC
concentrations for NIBW COCs in samples obtained at CGTF extraction wells in
2013 are summarized in Table 5. Historical groundwater production and TCE
16
concentrations at CGTF extraction wells are graphed in Appendix E. As
demonstrated in operations reports and CMRs provided by COS, NIBW COCs were
not detected in groundwater treated at the CGTF.
2.2 GROUNDWATER REMEDIATION AT THE MILLER ROAD TREATMENT
FACILITY
The MRTF was constructed to capture and treat groundwater containing
NIBW COCs in the northern LAU, to provide beneficial use of groundwater pumped
from remedy extraction wells, and to prevent migration to peripheral production
wells. The MRTF is located at 5975 North Miller Road, Scottsdale, as shown on
Figure 17. Groundwater extraction and treatment is currently performed at two
groundwater production wells, designated as PV-14 and PV-15, which are
individually connected to the MRTF. Groundwater extraction and treatment of
PCX-1 was also performed at MRTF until the PCX-1 pipeline was disconnected from
the MRTF on August 6, 2013. VOCs in extracted groundwater are reduced by air
stripping at MRTF. Treated groundwater from wells PV-14 and PV-15 is pumped to
the Paradise Valley Arsenic Removal Facility (PVARF). MRTF began operation in
1997 and is owned and operated by EPCOR.
2.2.1 2013 Overview
Operation of the PCX-1 treatment train at the MRTF was performed in
accordance with an EPA-approved Interim Operating Plan (IOP), dated April 25,
2008 with amendments dated June 13 and November 21, 2008. Treatment of
groundwater produced from well PCX-1 at the MRTF, under this IOP, commenced
on April 25, 2008 and ceased on August 6, 2013. As demonstrated through
extensive monitoring conducted pursuant to the IOP, NIBW COCs in treated water
from well PCX-1 consistently met drinking water standards.
Groundwater extraction tied into the MRTF contributed to capture and
containment of the LAU plume (as discussed in Section 4.2.5) and treatment
provided water for beneficial use by SRP and EPCOR. Approximately 6,456 AF or
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2,104 MG of groundwater were pumped and treated at MRTF in 2013, including
576 MG of groundwater extracted at PCX-1, 696 MG at PV-14, and 831 MG at
PV-15 (Table 8). Based on production totals and reported TCE concentrations, an
estimated 401 pounds of TCE were removed from groundwater at MRTF during
2013.
According to procedures developed in the EPA-approved Phase 2 Sampling
and Analysis Plan (SAP) and MRTF Operation and Maintenance (O&M) Plan,
samples of treated groundwater from the PCX-1 Treatment Train were collected for
compliance purposes on a weekly basis (until August 6, 2013) by the MRTF
Operator. The treated groundwater samples were submitted to TestAmerica for
analysis of NIBW COCs. Additionally, extraction well samples were collected during
the first week of each month at PCX-1, PV-14, and PV-15 (when the wells were
operating) and analyzed by TestAmerica.
Concentrations of NIBW COCs in samples obtained in MRTF extraction wells
in 2013 are summarized in Table 5. Historical groundwater production and TCE
concentrations at MRTF extraction wells are presented graphically in Appendix E.
Results of analysis of treated groundwater at MRTF are summarized in Table 9.
The treated groundwater samples from the PCX-1 Treatment Train were used to
evaluate compliance with groundwater treatment performance standards. All treated
groundwater samples from the PCX-1 Treatment Train analyzed in 2013 were below
MRLs for all NIBW COCs. Numerous additional samples of PCX-1 Treatment Train
effluent (typically sampled every Wednesday and Friday when the PCX-1 Treatment
Train was operational) were obtained to validate treatment system performance in
accordance with the IOP and the data were submitted under separate cover to EPA
and ADEQ.
Treated water from well PCX-1 Treatment Train was delivered to the SRP
Arizona Canal. Discharges to the Arizona Canal are further regulated by an Arizona
Pollutant Discharge Elimination System (AZPDES) permit. Samples were collected
monthly at the Arizona Canal outfall for testing required under the AZPDES permit in
2013. The results of the sample analyses were summarized in monthly Discharge
Monitoring Reports (DMRs) and submitted directly to EPA and ADEQ under
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separate cover. Subsequent to the disconnection of the pipeline from well PCX-1 to
MRTF, the AZPDES permit was transferred to EPCOR. EPCOR began reporting
the DMRs beginning for the August reporting period. Laboratory analyses of all
Arizona Canal outfall samples reported in 2013 DMRs indicated that TCE was below
the MRL of 0.50 g/L.
2.2.2 Operational Summary for October through December 2013
A tabulation of the results of TCE analyses obtained by the NIBW PCs for
MRTF extraction wells during fourth quarter 2013 is as follows:
TCE Concentrations in g/L
Date: PV-15 PV-14
10/7/13 NS NS10/14/13 7.0 1.711/4/13 5.5 / 5.7 3.3 / 3.312/2/13 NS 2.2
12/16/13 4.1 NS Notes: NS = Not Sampled
Maintenance issues addressed during the quarter included replacing the
pump in well PV-15, and upgrades to the facility computer control system. Reduced
pumping from the MRTF wells was due to PV-15 being offline for several weeks
while the pump was out of service; and EPCOR operating the wells for only
approximately 8 hours per day when an operator was on-site during the control
system installation, testing, and validation activities in November and December.
Routine operation, maintenance, and monitoring of the treatment trains for
wells PV-14 and PV-15 are anticipated to continue by EPCOR throughout 2014.
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2.3 GROUNDWATER REMEDIATION AT THE NIBW GRANULAR ACTIVATED CARBON (GAC) TREATMENT FACILITY
NGTF was constructed by the NIBW PCs to treat groundwater extracted from
well PCX-1 to provide hydraulic capture at the leading edge of the northern LAU
plume, and limit migration of the plume toward the EPCOR well field. NGTF is
located at 5985 Cattletrack Road, at the southeast corner of the intersection of Miller
Road and McDonald Drive in Scottsdale (Figure 17). NGTF includes a pre-filter
located upstream of a Granular Activated Carbon (GAC) treatment system that
removes entrained solids to prevent accumulation of sediment in the media bed.
Groundwater extracted from PCX-1 is treated using two duty GAC treatment trains,
with one additional treatment train provided as standby. During 2013, treated water
from NGTF was delivered to the Arizona Canal for SRP beneficial use. A pipeline
was installed to deliver treated water from NGTF to the CWTP for use by COS in its
system. Once final approval of the project by Maricopa County Environmental
Services Department (MCESD) is received, treated water will be delivered primarily
to CWTP. In the event COS does not need or cannot take PCX-1 treated water, the
NGTF will deliver treated water to the SRP Arizona Canal. Final approval of the
project by MCESD is anticipated during the first quarter of 2014.
2.3.1 2013 Overview
EPA authorized NGTF as the long-term solution for extraction and treatment
of well PCX-1 in an Explanation of Significant Differences (ESD) dated March 2012.
The ESD requires that treated groundwater from the NGTF meet the cleanup
standards set forth in Table 3 of the Amended ROD. In 2013, the NGTF consistently
treated groundwater to concentrations below cleanup standards for NIBW COCs.
Treated water from the treatment system was delivered to the Arizona Canal under
the NGTF AZPDES permit. Since initial start-up, samples were collected monthly at
the Arizona Canal outfall for analyses required by the AZPDES permit. The results
of sample analyses were summarized in monthly DMRs, and submitted directly to
the EPA and ADEQ under separate cover.
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Compliance monitoring was performed in accordance with the EPA-approved
Start-Up and Commissioning Monitoring Plan (SCMP), dated May 21, 2013, and
NGTF O&M Plan, dated June 19, 2013, to verify removal of COCs from extracted
groundwater and assure groundwater treatment standards are achieved. EPA
approved the SCMP and the NGTF O&M Plan on June 24, 2013. In accordance
with the EPA-approved SCMP, treatment system samples were collected each week
and submitted to TestAmerica for analysis of NIBW COCs.
Functional testing and initial start-up commenced in early July 2013, with
testing the operation of each piece of equipment, calibrating the motor-operated
control valves on the system and each treatment train, and validation of the control
and treatment system. During start-up activities throughout July and early August,
groundwater from PCX-1 was treated at NGTF during the day and at MRTF
overnight and on weekends. During functional testing and initial start-up, NGTF was
operated intermittently and only while an operator was on-site. This mode of
operation was necessary to enable adjustments to the equipment and control
system during the functional testing activities. On August 6, 2013, the PCX-1
pipeline connection to MRTF was removed. Beginning on August 8, 2013, water
extracted from PCX-1 was treated solely at NGTF. COS began continuous
operation of NGTF on August 14, 2013.
An inspection of the internals to contactors T1A and T2A on September 17,
2013 revealed that the inlet water diffusers were not in-place on each GAC contactor
inlet. The water diffusers were relocated to the appropriate position on each
contactor between September 20 and 22, 2013. Considering the condition and
usage of the GAC while the water diffusers were not in the proper location on each
contactor, arrangements were made to replace the GAC in each vessel. The GAC
in the LEAD contactors of Treatment Train 1 and 2 (T1A and T2A) were replaced on
September 26th and September 28th, respectively. Contactors T1A and T2A were
then placed in the LAG position while the former LAG contactors, T1B and T2B,
were placed in the LEAD position. Carbon was replaced in contactors T1B and T2B
on October 19 and 21, 2013, respectively. Upon completion of the carbon
replacement activities in October, contactors T1A and T2A were put into the LEAD
positions of the respective treatment trains. Carbon was replaced in contactors T3A
21
and T3B on October 28 and 29, 2013, respectively. A 60-day commissioning period
was conducted following start-up to demonstrate treatment performance of NGTF.
Commissioning commenced once the water diffusers were located in the
appropriate positions on the GAC contactors and the carbon was replaced. NGTF
Commissioning began on October 28, 2013 and was successfully completed on
December 26, 2013.
The total volume of groundwater extracted and treated at NGTF during 2013
was 1,303 AF (425 MG), and an estimated 264 pounds of TCE were removed. A
summary of concentrations for NIBW COCs in samples obtained from well PCX-1
during 2013 is included in Table 5. Historical groundwater production and TCE
concentrations at PCX-1 are presented graphically in Appendix E. Results of
analysis of NGTF process and treated groundwater conducted by TestAmerica are
summarized in Table 9. All treated groundwater samples analyzed in 2013 from
NGTF were below the MRL of 0.50 g/L for TCE and all other NIBW COCs.
2.3.2 Operational Summary for October through December 2013
The results of TCE analyses for samples collected during fourth quarter 2013
are included in the following table.
TCE Concentrations in g/L
Week of: Influent Effluent
October 6 - 12 73 <0.50October 13 - 19 73 <0.50October 20 - 26 74 <0.50October 27 – November 2 86 <0.50November 3 - 9 69 <0.50November 10 - 16 91 / 79 <0.50November 17 - 23 77 <0.50November 24 - 30 75 <0.50December 1 - 7 69 <0.50December 8 - 14 70 <0.50December 15 - 21 73 <0.50December 22 - 28 71 <0.50December 30 – January 5 81 <0.50
Notes: NS = Not Sampled
22
Routine operation, maintenance, and monitoring are anticipated to continue at
NGTF throughout 2014.
2.4 GROUNDWATER REMEDIATION AT AREA 7
Area 7 is a former electronics manufacturing site located at the southeast
corner of 75th Street and 2nd Street in Scottsdale, as shown on Figure 17. Siemens
installed the Area 7 GWETS to enhance the NIBW groundwater remedy by
extracting and treating MAU groundwater containing relatively higher VOC
concentrations associated with the source area, reducing VOC mass allowed to
migrate to the CGTF extraction wells for removal and treatment. Groundwater
extraction is generally performed using three MAU groundwater extraction wells
designated as 7EX-3aMA, 7EX-4MA, and 7EX-5MA, and one UAU groundwater
extraction well designated as 7EX-1UA. The extracted groundwater is treated by
ultraviolet oxidation (UV/OX) followed by air stripping. Treated water is discharged
to the UAU using two up-gradient groundwater injection wells (7IN-1UA and
7IN-2UA). The Area 7 MAU source control GWETS was initially started in 1999 and
became fully functional when 7EX-5MA was brought on-line in early 2002.
2.4.1 2013 Overview
Although extraction well 7EX-5MA was out of service for all of 2013,
groundwater extraction tied into the Area 7 GWETS was generally effective in
localized MAU source control (as discussed in Section 4.2.3) and groundwater
treatment provided water for beneficial use that was safely below drinking water and
aquifer water quality standards for all NIBW COCs (as discussed in Section 4.3.4).
Compliance monitoring was conducted in accordance with an EPA-approved Area 7
GWETS O&M Plan to verify removal of VOCs from the extracted groundwater and
assure groundwater treatment standards are achieved. EPA approved the Area 7
GWETS O&M Plan on June 8, 2006.
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Several alternative well locations for replacement of well 7EX-5MA were
evaluated in 2013. Results of these evaluations were presented to the NIBW
Technical Committee. A prospective location near 74th Street and Earll Drive was
pursued; however, the property is currently being sold and negotiating access has
been difficult. Other alternative locations, including several in COS rights-of-way,
are being considered.
Well 7EX-1UA went out of service during October 2012 and remained out of
service for all of 2013. TCE concentrations in the UAU at Area 7 have consistently
been below the MCL of 5 g/L. As such, continued pumping at well 7EX-1UA does
not provide benefit to UAU restoration. Consequently, the NIBW PCs made a formal
proposal in a letter to EPA dated August 29, 2013 to terminate operation of Area 7
extraction well 7EX-1UA and allow formal abandonment of this well.
A total of approximately 412 AF, or 134 MG, of groundwater were pumped
and treated at the Area 7 GWETS in 2013 (Table 8). Of the total, 83 MG were from
7EX-3aMA and 51 MG from 7EX-4MA. Treatment system performance data
provided by the Area 7 GWETS operator indicates an estimated 933 pounds of TCE
were removed from extracted groundwater during 2013. Mass removal estimates
derived from quarterly monitoring of extraction wells indicate approximately
843 pounds of TCE mass were removed by the Area 7 GWETS (Table 8).
In 2013, process samples, including treated groundwater discharged from the
Area 7 GWETS, were collected monthly by the Area 7 GWETS Operator and
submitted to TestAmerica for analyses of NIBW COCs. Samples from the Area 7
extraction wells were collected during the first week of the quarter by SRP (first
quarter) and by the NIBW PCs new groundwater monitoring contractor Terranext
(thereafter), and analyzed by TestAmerica. A summary of concentrations for NIBW
COCs in samples obtained from Area 7 extraction wells during 2013 is included in
Table 5. Historical groundwater production and TCE concentrations at Area 7
extraction wells are presented graphically in Appendix E. Results of analysis of
Area 7 process and treated groundwater conducted by TestAmerica are
summarized in Table 9. All treated groundwater samples analyzed in 2013 from the
24
Area 7 GWETS were below the MRL of 0.50 g/L for TCE and all other NIBW
COCs.
A Performance Evaluation (PE) sample, designated with sample identifier
SP-104, was submitted to TestAmerica during August 2013; with process water split
samples submitted to Trans West Analytical. A summary of the PE sample results
and final lab reports are included with other GWETS data and quality control
reporting submitted under separate cover as a supplemental data report (issued
concurrently with this SMR).
2.4.2 Operational Summary for October through December 2013
For the period from October to December 2013, the Area 7 GWETS operated
as designed to remove VOCs in extracted groundwater to meet Arizona Aquifer
Water Quality Standards (AWQS) for injection. The GWETS operated approximately
99 percent of the time during fourth quarter 2013.
During the fourth quarter 2013, process water samples were collected from
the combined influent to the GWETS at sample port SP-102, effluent from the
UV/OX reactor at sample port SP-103, and effluent from the air stripper at sample
port SP-105. Samples from the Area 7 extraction wells were collected in October by
Terranext at 7EX-3aMA and 7EX-4MA and analyzed by TestAmerica. Results of
TCE analyses for these Area 7 extraction wells and treatment process water
samples obtained during fourth quarter 2013 are as follows:
Area 7 Groundwater Extraction
TCE Concentrations in g/L
Date 7EX-3aMA 7EX-4MA
10/7/2013 440 1,300
25
Area 7 Groundwater Treatment System TCE Concentrations in g/L
Date/Description GWETS Influent
UV/OX Effluent
A/S Effluent
10/7/2013 1,000 140 <0.50
11/4/2013 930 150 <0.50
12/2/2013 850 120 <0.50
In addition to testing for NIBW COCs, sampling for inorganic water quality was
conducted during 2013 to monitor potential impacts of injection of treated water from
the Area 7 GWETS on UAU groundwater. Inorganic water quality was monitored in
groundwater samples obtained at four UAU monitor wells in the vicinity of Area 7
(i.e., PG-10UA, PG-16UA, PG-28UA and PG-29UA) and in treated water that is
recharged to the UAU through vadose zone injection well(s). Results of 2013
inorganic water quality analyses are provided in a letter entitled, “Supplemental Data
Collection at the Area 7 GWETS, During October 2013, NIBW Superfund Site” that
will be submitted by the NIBW PCs concurrent with this SMR as a supplemental
data report. The data indicate that treated groundwater from the Area 7 GWETS
has similar or slightly lower concentrations of inorganic water quality constituents
than UAU monitor wells in the vicinity of Area 7. The inorganic data indicate UAU
and MAU groundwater at Area 7 is generally of poor quality; however, the data verify
that injection of treated groundwater from the Area 7 GWETS does not contribute to
degradation of inorganic water quality in the UAU.
Routine operation, maintenance, and monitoring are anticipated to continue
at the Area 7 GWETS throughout 2014.
2.5 GROUNDWATER REMEDIATION AT AREA 12
The Area 12 GWETS is located at the former Motorola facility at 8201 East
McDowell Road, Scottsdale, as shown on Figure 17. Motorola installed the Area 12
GWETS to enhance the NIBW groundwater remedy by extracting and treating MAU
26
groundwater containing relatively higher VOC concentrations at the source area,
reducing VOC mass allowed to migrate to the southwest margin for removal and
treatment at the CGTF extraction wells. Groundwater extraction is performed using
two MAU groundwater extraction wells designated as MEX-1MA and SRP well
23.6E,6.0N, also known as the Granite Reef well. The extracted groundwater is
treated by air stripping and delivered to the SRP system for irrigation use. The
Area 12 MAU source control GWETS was implemented beginning in early 1999 with
start-up of well MEX-1MA. The Area 12 GWETS was fully functional when the
Granite Reef well was connected in late 1999.
2.5.1 2013 Overview
During 2013, groundwater extraction tied into the Area 12 GWETS was
effective in localized MAU source control (as discussed in Section 4.2.4) and
groundwater treatment provided water for beneficial use that consistently met water
quality standards for all NIBW COCs (as discussed in Section 4.3.5). Compliance
monitoring was conducted during 2013 in accordance with an EPA-approved
Area 12 GWETS O&M Plan to verify removal of VOCs from the extracted
groundwater and assess whether groundwater treatment standards were achieved.
EPA approved the Area 12 GWETS O&M Plan on June 8, 2006.
A total of 1,216 AF or 396 MG of groundwater were pumped and treated at
the Area 12 GWETS in 2013 (Table 8). Of the total, 319 MG were extracted from
MEX-1MA and 77 MG from the Granite Reef well. Treatment system performance
data provided by the Area 12 GWETS operator indicates an estimated 185 pounds
of TCE were removed from groundwater during 2013. Mass removal estimates
derived from quarterly monitoring of extraction wells indicate approximately
198 pounds of TCE mass was removed by the Area 12 GWETS (Table 8).
In 2013, process samples, including influent and treated groundwater, were
collected monthly by the Area 12 GWETS Operator and submitted to TestAmerica
for analysis of NIBW COCs. Samples from the Area 12 extraction wells were
collected during the first week of the quarter (when the treatment system was
operational) by SRP (first quarter) and Terranext (thereafter), and analyzed by
27
TestAmerica. A summary of concentrations for NIBW COCs in samples obtained
from Area 12 extraction wells in 2013 is included in Table 5. Historical groundwater
production and TCE concentrations at Area 12 extraction wells are presented
graphically in Appendix E. Results of analysis of Area 12 process and treated
groundwater conducted by TestAmerica are summarized in Table 9. Although the
Area 12 GWETS presently provides treated water for irrigation use, the treatment
system is consistently operated to ensure TCE is below the more stringent standard
for the drinking water MCL.
Treated groundwater from the Area 12 GWETS is delivered to an SRP
irrigation lateral in accordance with an AZPDES permit, executed on May 31, 2011.
Sampling and testing for limited inorganic water quality is conducted in accordance
with the permit and the results are transmitted in monthly DMRs to ADEQ.
2.5.2 Operational Summary for October through December 2013
The NIBW Area 12 GWETS operated as designed during fourth quarter 2013.
Groundwater was extracted from the MEX-1MA well during October, November, and
December, and from the Granite Reef well during October and November. The
treatment system was on-line continuously except for brief periods of routine
maintenance, short-term power outages or surges due to weather, and
communication/electrical errors at the wells, until it was shutdown on December 29,
2013 for scheduled annual SRP canal dry-up. During the fourth quarter 2013, the
Area 12 GWETS Operator collected samples of the combined influent to the
GWETS at sample port WSP-1 and effluent from the air stripper at sample port
WSP-2. Samples from the Area 12 extraction wells were collected by Terranext at
the beginning of the quarter and monthly by the Area 12 Operator (when the wells
were operating). The results of TCE analyses for extraction wells and treatment
process water samples obtained for fourth quarter 2013 are as follows:
28
TCE Concentrations in g/L
Date MEX-1MA Granite
Reef GWETS Influent
GWETS Effluent
10/6/2013 50 30 53 <0.50
10/7/2013 78 49 NS NS
10/31/2013 NS 78 NS NS
11/4/2013 50 NS 50 <0.50
12/2/2013 52 NS 54 <0.50
Notes: NS = Not sampled
Following SRP completion of canal dry-up in early February, routine
operation, maintenance, and monitoring are anticipated to continue at the Area 12
GWETS throughout 2014.
3.0 SOIL REMEDIATION PROGRAM
Soil remediation has been conducted at NIBW Areas 6, 7, 8, and 12.
Remediation using soil vapor extraction and treatment (SVET) has been completed
at Area 6, 8, and 12. At Area 7, SVET has resulted in removal of approximately
7,000 pounds of VOCs. Soil vapor monitoring and modeling conducted in 2013
indicate that SVE has effectively eliminated the threat to groundwater at Area 7, as
described below.
The Area 7 SVET system was shut down in May 2000 to allow VOC
concentrations in the soil to equilibrate and to begin long-term monitoring for
potential rebound. After an 18-month rebound period, soil vapor monitoring was
conducted to determine the level of residual soil VOC concentrations and calculate
the threat to groundwater. The results of long-term vapor monitoring and calculation
of groundwater threat were provided in a report dated May 21, 2002. Although the
report indicated SVET had achieved performance standards for Area 7 soils, EPA
and ADEQ believed the soil VOC levels had not reached asymptotic levels.
Consequently, it was decided to monitor the 125-foot interval of SVM 7-209 on a
29
semi-annual schedule to determine when TCE concentrations become asymptotic.
Soil vapor monitoring of this zone continued for five more years until April 2006.
In April 2006, the NIBW PCs collected soil vapor samples at Area 7 to
determine the level of residual soil VOC concentrations and calculate the threat to
groundwater. The results of soil vapor monitoring were included in a report
submitted to EPA in June 2006 and concluded that the residual TCE in Area 7 soils
did not pose a significant threat to groundwater. EPA and ADEQ did not approve
the NIBW PCs request for soil remedy completion and asked for further optimization
of the Area 7 soil remedy in a letter dated March 20, 2007. Following extensive
discussion between the PCs and EPA regarding potential soil remedy optimization,
a work plan to restart and operate the Area 7 SVE system was issued to EPA on
November 8, 2007. EPA approved the work plan in a letter dated July 14, 2008.
The Area 7 SVET was restarted on July 24, 2008, and operated under a
pulsing regime until December 2009. After that time, the Area 7 SVE system was
shut down for a planned 3-year period to observe overall vapor rebound. Since that
3-year period ended, soil-vapor samples were collected from the soil-vapor
monitoring wells and selected soil-vapor extraction wells in December 2012, with
confirmatory sampling in March 2013. The NIBW PCs summarized the results of
vapor rebound monitoring in a report entitled, 2013 Groundwater Threat Analysis for
Area 7, to demonstrate that soil cleanup actions at Area 7 have achieved
Performance Standards for completion of this work. The Groundwater Threat report
was submitted with a letter requesting Certification of Completion for the Area 7
Vadose Zone Work on August 29, 2013. EPA reviewed the Groundwater Threat
Analysis and provided comments in a Technical Memorandum dated December 19,
2013 prepared by Gilbane, the EPA technical oversight contractor. The independent
review by Gilbane indicates that the concentration of residual VOCs in the vadose
zone at Area 7 will not pose a threat to groundwater, even in multiple worst-case
scenarios that were evaluated. The NIBW PCs are in the process of preparing a
summary of the Area 7 Groundwater Threat Report that will refer to results of
Gilbane’s independent analysis and conclusions, providing the basis for discussions
with EPA regarding closure of the Area 7 soil remedy.
30
4.0 EVALUATION OF NIBW REMEDIAL ACTION PERFORMANCE
Evaluation of the NIBW remedy is based on Performance Standards set forth
in the SOW. Performance Standards are defined in the SOW for groundwater
monitoring, containment, and treatment. In the sections that follow, monitoring data
obtained during 2013 will be evaluated to assess achievement of performance
criteria.
4.1 ASSESSMENT OF GROUNDWATER MONITORING PERFORMANCE
STANDARDS
The GMEP requires an annual assessment of the scope and frequency of
monitoring activities to optimize program effectiveness over time. In the Five-Year
Review of the NIBW Superfund Site (2011), EPA comprehensively reviewed
groundwater monitoring data obtained pursuant to the GMEP and concluded
significant progress has been achieved toward restoration of the UAU. Based on
this finding, EPA and the NIBW PCs agreed to reassess and revise the UAU
groundwater monitoring program as part of an optimized approach to be adopted in
an updated GMEP. Results of this assessment are detailed below. Revisions to the
scope and frequency of the MAU and LAU groundwater monitoring program will be
evaluated in future years.
4.1.1 Optimization of Long Term UAU Groundwater Monitoring Program
Since May 2012, the NIBW Technical Committee has discussed an approach
for future UAU groundwater monitoring that included streamlined groundwater data
acquisition. This approach was documented in the NIBW PCs revised long-term
UAU groundwater monitoring program proposal entitled, Final Technical
Memorandum - Recommendations for Upper Alluvial Unit Aquifer Long-Term
Groundwater Monitoring Program, North Indian Bend Wash Superfund Site,
Scottsdale, Arizona, dated March 11, 2013. This proposal, which was approved by
EPA, recommended formal abandonment of 30 UAU monitoring wells that were no
longer needed to define either water level or water quality conditions in the UAU.
31
The UAU wells were successfully abandoned in accordance with all ADWR
requirements during field work conducted from August 2, 2013 to January 9, 2014.
The stated goals of the revised UAU monitoring program, consistent with the
GMEP, are to make the NIBW groundwater monitoring program less repetitive,
and to make resulting groundwater data reports more valuable to all interested
parties. The UAU well abandonment program helped accomplish these goals by the
following approaches.
Abandoning wells in areas where the groundwater has consistently been significantly below cleanup levels defined in the NIBW Site ROD.
Reducing the number of UAU wells that are monitored to 23.
Reducing the monitoring frequency to an annual water level and sampling event for UAU wells in October.
Focusing ongoing UAU groundwater monitoring activities on aquifer
restoration in the localized areas associated with Area 7 and Area 12 where low levels of TCE occur.
Water quality data indicate the UAU groundwater system has for the most
part been cleaned up and is soon anticipated to achieve the remedial action
objective of aquifer restoration (see Section 1.2). The more targeted and optimized
monitoring program described above will provide all necessary data to track patterns
of groundwater movement and VOC concentration declines, as well as to estimate
the rate of VOC mass reduction over time until UAU aquifer restoration is achieved.
4.1.2 Assessment of MAU Source Control Performance Measures
The MAU source control programs at Area 7 and Area 12 have been
operating since 1999 to locally pump and treat TCE impacted groundwater to
minimize the TCE mass that can migrate from the source areas to the western
margin. The effectiveness of MAU source control is evidenced by the approximately
23,000 pounds of TCE mass removed by groundwater extraction and treatment at
Area 7 and Area 12 and the fact that TCE concentrations are generally stable and
32
slowly declining in MAU monitor wells down-gradient of the source areas. Although
the NIBW PCs believe the results to date indicate the MAU source control program
is effective, some specific performance measures defined in the GMEP have not
been achieved for either Area 7 or Area 12 on several occasions since
implementation of the GMEP in 2002. In fact, some of these performance criteria
have been found, in practice, to be unsuitable as clear, objective, and accurate
measures of remedy performance. Consequently, the NIBW PCs have proposed
reassessment of the MAU source control performance measures as defined in the
GMEP. Work to review, analyze, and, where appropriate, establish updated MAU
source control metrics is planned following installation and operation of the
replacement Area 7 extraction well (7EX-6MA) and completion of a similar
evaluation of LAU groundwater containment performance measures, as discussed
below.
4.1.3 Assessment of LAU Groundwater Containment Performance Measures
Over the past several years, a small subset of northern LAU groundwater
data have not met monitoring objectives associated with plume containment on a
consistent basis. In response, the NIBW PCs have comprehensively assessed and
continue to evaluate the mechanisms associated with each specific triggering event.
Overall, the PCs’ evaluations show that the NIBW remedy is containing the LAU
plume. They have also proposed to the Technical Committee that some of the
GMEP-specified criteria used to demonstrate effectiveness may not be meaningful
measures of LAU hydraulic containment and should be re-evaluated. In response
and in accordance with EPA guidance in electronic mail dated June 1, 2012,
contingency actions associated with northern LAU containment have been
temporarily suspended pending review and analysis by the NIBW Technical
Committee to reassess GMEP performance measures and, as appropriate, establish
updated metrics. As discussed further in Section 4.2.2, part of the evaluation
process in relation to evaluation of LAU hydraulic containment will include enhanced
water quality monitoring that will be conducted in 2014 at S-2LA and PA-13LA to
more closely track increasing TCE concentrations at these two northern LAU
monitor wells and evaluate the mechanisms potentially responsible for observed
increasing data trends.
33
4.2 ASSESSMENT OF GROUNDWATER CONTAINMENT PERFORMANCE STANDARDS
Performance of the NIBW remedy is evaluated based on a rigorous approach
established in the GMEP. In the GMEP, monitoring program objectives are matched
with specific performance criteria, a methodology for measuring achievement of
performance criteria, a definition of when contingency evaluations or actions would
be initiated, and alternative contingency response actions that may be taken. Based
on review of 2013 monitoring data, five specific aspects of the remedy will be
evaluated with respect to groundwater containment performance standards, in
accordance with achievement measures established in the GMEP. Aspects of the
remedy that will be evaluated include: 1) UAU mass flux; 2) MAU/LAU containment;
3) Area 7 MAU source control; 4) Area 12 MAU source control; and 5) northern LAU
hydraulic capture.
4.2.1 Evaluation of UAU Mass Flux
The assessment of remedy performance for the UAU plumes involves
monitoring of VOC mass reduction over time. For the 2013 VOC mass flux analysis,
total mass of VOCs present in UAU groundwater was computed using data for
saturated thickness from the October 2013 water level monitoring round and VOC
concentration data from the October 2013 water quality monitoring round. Table 10
summarizes VOC mass estimates for the UAU for 2013. Note that beginning with
the 2013 UAU mass flux analysis, water level and water quality data are no longer
available for 30 UAU monitor wells that were formally abandoned. Based on 2013
data, a total of about 18 gallons, or 213 pounds, of VOCs are estimated to remain in
the saturated portion of the UAU (Table 10). Figure 18 illustrates the decline in total
VOC mass in UAU groundwater over time. Estimated total mass of VOCs present in
the saturated portion of the UAU has decreased substantially over the past 21 years,
declining from a high of over 11,000 pounds in 1993 to the current estimate of
213 pounds. As shown on Figure 18, the estimated VOC mass has been relatively
uniform over the past 12 years, in the range of about 210 to 600 pounds, indicating
that the change in mass with time has become generally asymptotic.
34
The inset table in Figure 18 lists the calculated 5-year running average of
VOC mass in UAU groundwater since annual mass estimates were initiated in 1996.
The most recent 5-year running average of 301 pounds represents a decrease in
average UAU mass relative to the previous 5-year average of 377 pounds, indicating
the performance measure for UAU mass reduction has been achieved.
4.2.2 Evaluation of MAU/LAU Hydraulic Containment
The assessment of remedy performance for the MAU/LAU plume involves
demonstrating that: 1) direction of groundwater movement along the periphery of the
plume is toward extraction wells or the western margin; 2) the estimated location of
the 5 μg/L contour for the TCE plume does not shift outward more than 1,000 feet
relative to plume interpretations for the baseline time period, October 2001; and
3) TCE concentrations at a set of sentinel MAU and LAU monitor wells do not
exceed specified levels. For 2013, compliance with all of these achievement
measures was attained, except for levels above the TCE concentration trigger at
monitor well S-2LA. This trigger was previously discussed in Section 1.2 and will be
discussed further in this section.
Water level and TCE concentration data for October 2013, with interpreted
hydraulic capture zones (MAU only) and arrows indicating direction of groundwater
movement, are shown for the MAU and LAU on Figures 19 and 20, respectively.
Where arrows are not present, note that inferred direction of groundwater movement
is perpendicular to water level contours. Containment of the MAU and LAU plumes
is demonstrated based on the fact that direction of groundwater movement along the
periphery of all areas where concentrations of TCE are in excess of 5 g/L is either
toward extraction wells tied into treatment or toward the southwest margin
(Figures 19 and 20). For the MAU (Figure 19), direction of groundwater movement
along the periphery of the plume is inferred to be toward CGTF extraction well
COS-71 and the Area 7 (7EX-3aMA and 7EX-4MA) extraction wells in the north part
of the Site. In the south part of the Site, direction of groundwater movement along
the periphery of the MAU plume is inferred to be toward the Area 12 extraction wells
(MEX-1MA and SRP 23.6E,6N) and the cone of depression caused by pumping of
wells COT-6, COS-25, and SRP 22.5E,5.5N. The MAU plume in the central part of
35
the Site moves toward the western margin. For the LAU (Figure 20), direction of
groundwater movement along the periphery of the plume is inferred to be toward
extraction wells associated with the NIBW remedy, principally CGTF extraction wells
COS-71 and COS-75A, NGTF extraction well PCX-1, and MRTF extraction wells
PV-15 and PV-14.
Figures 14 and 15 illustrate 5 g/L TCE contours for the October 2001 and
October 2013 plumes in MAU and LAU groundwater, respectively. The illustrations
demonstrate that generally very little change of the 5 g/L contour over the period
has occurred, with the exception of anticipated migration of the LAU plume toward
the MRTF extraction wells and PCX-1. Between 2001 and 2013 outward shifts in
the location of the 5 g/L TCE contour in the MAU and LAU were generally less than
the 1,000-foot performance measure. Small inward and outward shifts of the 5 g/L
contour interpreted between the two data sets are attributable to small changes in
reported TCE concentrations. Exceptions include shifts of the 5 g/L TCE
concentration contour on the order of between about 1,000 and 1,300 feet between
2001 and 2013 that have been observed at the northern and northwestern edge of
the LAU plume. Changes in the northern part of the LAU plume are indicative of
northern migration of the plume for capture by the MRTF extraction wells and are
not indicative of a lack of hydraulic containment (see Section 4.2.5 for further
information). Changes in the northwestern part of the LAU plume continue to be
closely monitored in relation to exceedance of a GMEP performance measure at
S-2LA, as discussed below. An area of apparent change located near Scottsdale
Road between Thomas and McDowell Roads is attributable to the availability of new
data at well M-17MA/LA beginning in 2002.
The final performance measure for MAU/LAU plume containment is a
comparison of observed TCE concentrations from the October 2013 sampling round
to numerical TCE concentrations specified in the GMEP at selected MAU and LAU
sentinel monitor wells, as summarized as follows:
36
Required and Observed TCE Concentrations in Selected NIBW Monitor Wells
TCE Concentration (g/L)
Well Name
Achievement Measure
October 2013 Sampling
Round Results MAU Monitor Wells
M-2MA 10 2.1 M-7MA 10 <0.5 S-1MA 2 <0.5 S-2MA 3 <0.5
LAU Monitor Wells M-5LA 10 <0.5 PA-2LA 3 <0.5 PA-15LA 10 <0.5 PA-18LA 10 1.5 PG-1LA 15 1.1
PG-44LA 5 <0.5 S-1LA 3 <0.5 S-2LA 15 29
As previously mentioned, TCE concentrations at well S-2LA have exceeded
the GMEP-established performance criterion since 2011. In response, the NIBW
PCs conducted significant investigation work to characterize LAU groundwater
conditions and update our assessment of plume containment that was summarized
in the 2011 SMR. The findings of this evaluation indicated that the increase in TCE
concentrations at S-2LA was attributed to migration of TCE mass from an upgradient
portion of the LAU plume that is within the combined hydraulic capture zone created
by pumping of CGTF and MRTF extraction wells that are part of the NIBW
groundwater remedy.
In the 2 years since contingency response actions were initiated at S-2LA, the
TCE concentrations at this well have continued to increase and a similar increasing
trend has been noted at well PA-13LA, located approximately 1,500 feet east of
S-2LA (Appendix C and Figure 25). Evaluation of water level data and simulation
analyses based on the conceptual model indicate that the observed trends at these
wells do not signify a concern regarding achievement of groundwater containment
performance standards. However, additional monitoring will be conducted in 2014
37
to more closely track changing water quality in this portion of the northern LAU and
evaluate the mechanisms potentially responsible for the observed data trends.
4.2.3 Evaluation of Area 7 MAU Source Area Program
The assessment of remedy performance for the Area 7 MAU source area
program involves demonstrating: 1) hydraulic capture, such that the direction of
groundwater movement from the vicinity of monitor well PA-12MA is toward the cone
of depression associated with Area 7 pumping; and 2) a decline in 5-year running
average TCE concentrations for monitor wells located within the hydraulic capture
zone associated with Area 7 pumping. The 5-year running average is calculated
following full implementation of the Area 7 remedy using indicator wells located
within the Area 7 hydraulic capture zone, as defined in the GMEP to include: D-2MA,
E-10MA, PA-10MA, PA-12MA, W-1MA, and W-2MA.
While the Area 7 remedy began with extraction at 7EX-3aMA and 7EX-4MA
in 1999, it achieved full implementation in 2002 when extraction was added at
7EX-5MA, prior to the period shown on the indicator well hydrographs. In April 2012,
extraction well 7EX-5MA was damaged during routine maintenance and has not
been operational since that time. Evaluation is currently underway, in coordination
with the Technical Committee, to select a site for a replacement Area 7 GWETS
extraction well (7EX-6MA).
Figure 21 includes graphs of water level and TCE concentration data for
indicator wells in the vicinity of Area 7. Data from these indicator wells are helpful
for evaluating long-term trends and overall effectiveness of the Area 7 GWETS.
Water levels in the vicinity of Area 7 display some seasonal patterns in response to
pumping but are otherwise fairly consistent with regional trends, increasing from
about 2004 to 2011 and leveling off and even beginning to decline after that time.
TCE concentrations in the MAU sentinel wells in the vicinity of Area 7 are generally
stable or declining. Concentration increases observed at monitor well W-1MA
beginning in 2012 can be attributed to changes in local patterns of groundwater
movement that occurred when pumping was increased at 7EX-3aMA and 7EX-4MA
38
following shutdown of 7EX-5MA as well as a summer seasonal pumping increase at
COS-31.
Figure 21 also shows MAU TCE concentration contours for October 2013
and the estimated extent of hydraulic capture associated with MAU extraction in the
vicinity of Area 7. MAU water level contours and the associated interpretation of
MAU hydraulic containment for the entire Site for October 2013 are shown on
Figure 19. Review of patterns of groundwater movement and the extent of
hydraulic capture for the vicinity of Area 7 indicates that a cone of depression,
centered north of Thomas Road, occurs as a result of MAU pumping at Area 7 and
CGTF extraction wells (Figure 19). In October 2013, the operational extraction
wells pumping from the MAU in the vicinity of Area 7 included 7EX-3aMA, 7EX-4MA,
COS-71, and COS-72 (Table 6). COS-72 did not pump immediately prior to the
October 2013 water level monitoring round and its pumping impacts are not likely to
be reflected in the data set. The estimated extent of MAU hydraulic capture
encompasses and provides effective capture for most of the greater than 500 g/L
and essentially all of the 1,000 g/L portion of the Area 7 MAU plume. However,
hydraulic capture does not appear to extend as far as the GMEP-stipulated location
at monitor well PA-12MA. Consequently, compliance with the hydraulic capture
component of the Area 7 remedy performance was not demonstrated, at least as
indicated by the October 2013 water level data.
Over the past 2 years, the NIBW PCs have noted during regular updates to
EPA and ADEQ at monthly Technical Committee meetings that MAU groundwater
extraction that is part of the Area 7 extraction and treatment program has decreased
due to the declining pumping rate at COS-71 and the loss of the 7EX-5MA extraction
well from service in May 2012. The reduced groundwater extraction from the MAU
in this region is reflected in the fact that inferred hydraulic capture zones based on
both October 2012 and October 2013 water level data do not appear to extend as
far to the southwest (e.g. vicinity of monitor well PA-12MA) as was inferred during
previous monitoring periods.
The second evaluation tool for the Area 7 MAU source control program is a
decline in the 5-year running average of TCE concentrations for the relevant monitor
39
wells following full implementation of the Area 7 groundwater remedy. Table 11
summarizes annual average TCE concentrations for the period 1995 through 2013
at the following MAU indicator monitor wells, located within the capture zone that
was specified in the GMEP for MAU extraction in the vicinity of Area 7: D-2MA,
E-10MA, PA-10MA, PA-12MA, W-1MA, and W-2MA. Annual average TCE
concentrations at each of the specified Area 7 MAU indicator wells were computed
for the period 1995 through 2013, and then a total combined annual TCE average
(for all wells) was determined. Using the total combined annual average TCE
values, the 5-year average was calculated to be 1,051 g/L for the period 2009
through 2013, which represents a decrease relative to the 5-year average of
1,066 g/L computed for 2008 though 2012. Accordingly, compliance with the mass
reduction component of the Area 7 remedy performance was achieved in 2013.
Figure 22 depicts the computed 5-year running average TCE concentrations
for Area 7 indicator wells, generally indicating that, except for the time periods 2007-
2011 and 2008-2012, a declining trend has been observed since this performance
measure came into effect in 2004. Increases in the 5-year running averages for
these two periods are directly correlated to variations in TCE concentrations
reported at monitor well W-2MA. Since W-2MA has the highest TCE concentrations
of all Area 7 indicator wells, slight variations in TCE concentrations can significantly
affect the averages. TCE concentrations at W-2MA have varied considerably over
time and have not demonstrated a clear trend over the past 10 years (Figure 21
and Appendix C). Since W-2MA is clearly within the capture zone created by
pumping of MAU groundwater by Area 7 and CGTF extraction wells (Figure 21),
changes in the magnitude of TCE concentrations at W-2MA from year to year are
not particularly meaningful other than to infer subtle shifts in local pumping within
this zone of hydraulic capture. As indicated above, a similar situation has been
occurring at well W-1MA over the past 2 years, with observed TCE concentration
increases being linked to a shift in pumping toward 7EX-3aMA and 7EX-4MA when
7EX-5MA was damaged and shut down.
In sum, MAU water level and water quality data obtained in October 2013 in
the Area 7 vicinity do not meet the performance measure for MAU source control
established in the GMEP with respect to hydraulic capture. The performance
40
measure involving a decline in 5-year running average TCE concentrations,
however, was achieved. The PCs conclude that a lack of achievement of the
hydraulic containment GMEP performance measure does not represent an overall
concern regarding the effectiveness of the Area 7 MAU remedy.
As a response measure and a GMEP contingency action associated with the
lack of achievement of Area 7 performance metrics noted in 2012, the NIBW PCs
prepared a Work Plan that was issued to the Technical Committee on April 12, 2013
and entitled "Area 7 Middle Alluvial Unit Source Control Proposed Actions in
Response to Non-Conformance with Performance Measures". The Work Plan
specified that the NIBW PCs would conduct enhanced groundwater level monitoring
to develop an increased understanding of hydraulic gradients across the upper MAU
plume in the vicinity of Area 7. Specifically, the goals of the enhanced water level
monitoring program were to:
Evaluate the effect of pumping on horizontal hydraulic gradients in the upper MAU to assess the down-gradient extent of capture;
Determine vertical hydraulic gradients at selected locations between the Upper MAU and Lower MAU;
Assess the MAU aquifer response in the monitor well network to different pumping regimes; and
Evaluate the proposed location for replacement extraction well 7EX-6MA.
The monitoring program, which was conducted by the PCs during the period
April through August 2013, involved installation of pressure transducers in several
monitor wells in the vicinity of Area 7 and coordination of on/off cycling of the Area 7
GWETS wells to generate water level response in the well network. The monitoring
program was also timed to coincide with a scheduled maintenance-related shutdown
and subsequent re-start of the CGTF and associated production wells. Results of
the Area 7 enhanced water level monitoring program are being evaluated by the
PCs and will be summarized in a technical memorandum to be submitted to the
NIBW Technical Committee during the first quarter of 2014.
41
4.2.4 Evaluation of Area 12 MAU Source Area Program
The assessment of remedy performance for the Area 12 MAU source area
program involves demonstrating: 1) hydraulic capture such that the direction of
groundwater movement from the vicinity of Hayden Road is toward the cone of
depression associated with Area 12 pumping; and 2) a declining, or non-increasing
trend, in 5-year running average TCE concentrations for monitor wells located within
the hydraulic capture zone associated with Area 12 pumping. The 5-year running
average is calculated following full implementation of the Area 12 groundwater
remedy using indicator wells located within the Area 12 hydraulic capture zone, as
defined in the GMEP, including: E-1MA, M-4MA, M-5MA, M-6MA, M-7MA, M-9MA,
M-15MA, and PA-21MA. The groundwater remedy at Area 12 was fully operational
in 2000, once both extraction wells MEX-1MA and SRP 23.6E,6N were brought on-
line in 1999, and 2004 was the first year when five (5) years of data were available
to conduct the running average performance assessment.
Figure 23 includes graphs of water level and TCE concentration data for
indicator wells in the vicinity of Area 12. Data from these indicator wells are helpful
for evaluating long-term trends and verifying overall effectiveness of the Area 12
groundwater extraction and treatment system. Water levels in the vicinity of Area 12
display seasonal patterns in response to pumping. Water level trends at the Area 12
indicator wells are generally increasing from 2004 to 2011, flat in 2012, and
declining in 2013, as shown on Figure 23. Water level declines in 2013 are
interpreted to result from pumping at wells COT-6, COS-25, and SRP 22.5E,5.5N
(Table 6). Although TCE concentration trends at most MAU monitoring wells in the
vicinity of Area 12 are stable or declining slowly over time, others exhibit variability
that is attributed to local groundwater pumping influences. The cause for an
increasing trend (i.e., 2013 concentrations ranged from about 20 to 40 g/L) that is
apparent at MAU monitor well M-10MA2 (located directly west from Area 12), is not
known. The PCs will continue to closely monitor trends at this well in 2014.
Figure 23 also shows MAU TCE concentration contours for October 2013
and the estimated extent of hydraulic capture associated with Area 12 MAU
extraction. MAU water level contours and the associated interpretation of MAU
42
hydraulic containment for the entire Site for October 2013 are shown on Figure 19.
Review of patterns of groundwater movement and the extent of hydraulic capture for
the vicinity of Area 12 indicates that a cone of depression occurs as a result of MAU
pumping at Area 12 extraction wells (MEX-1MA and SRP 23.6E,6N). Consistent
with the achievement measure, direction of groundwater movement from the general
vicinity of Hayden Road, and significantly further to the west, is to the east toward
this cone of depression. Accordingly, the NIBW PCs conclude that compliance with
the hydraulic capture component of the Area 12 remedy performance was achieved
in 2013.
Table 12 summarizes annual average TCE concentrations for the period
1994 through 2013 at the following MAU indicator wells located within the capture
zone specified in the GMEP for MAU extraction at the Area 12 GWETS: E-1MA,
M-4MA, M-5MA, M-6MA, M-7MA, M-9MA, M-15MA, and PA-21MA. Annual average
TCE concentrations at each of the specified Area 12 MAU monitor wells were
computed for the period 1994 through 2013. Next, the annual, individual monitoring
well average TCE concentrations were averaged to arrive at a combined Area 12
average for each year. Using the annual average TCE values computed in this
manner, the 5-year average was calculated to be 22 g/L for the period 2009
through 2013. This value is lower than the average of 23 g/L that was computed
for the previous three 5-year periods, as shown graphically on Figure 24.
As evidenced by data trends, some of which pre-date the hydrographs shown
on Figure 23, substantial declines in TCE concentrations have been observed over
time at monitor wells within the Area 12 zone of hydraulic containment
corresponding to implementation of the Area 12 groundwater remedy. These data
indicate that on-going groundwater extraction since 1999 has removed a substantial
amount of TCE mass that was present in MAU groundwater in the vicinity of
Area 12, and that the 5-year running average concentrations in the area
groundwater zone captured by the Area 12 extraction wells are generally asymptotic
with time (Figure 24). The results indicate achievement of the mass removal
component of the Area 12 remedy performance but also suggest that the mass
reduction may no longer be a meaningful performance measure for assessment of
the Area 12 remedy.
43
4.2.5 Evaluation of Northern LAU Hydraulic Capture
Assessment of hydraulic capture is predicated on a systematic process
established in the GMEP to methodically collect and track key groundwater
monitoring program data to ensure achievement of groundwater containment
performance standards. Performance standards for groundwater containment are
defined in the SOW and require that the remedial action provides sufficient hydraulic
control to prevent groundwater with TCE concentrations above clean-up standards
from impacting peripheral wells outside of the plume. Specific GMEP performance
criteria are intended to provide objective and protective indicators of containment
and enable appropriate response actions to maintain plume containment.
The assessment of remedy performance for the northern LAU program
involves demonstrating: 1) the consistent presence of a cone of depression in the
vicinity of the northern LAU extraction wells tied into treatment (MRTF extraction
wells and PCX-1); and 2) TCE concentrations at monitor wells PG-42LA and
PG-43LA, and at extraction well PV-14, that are less than or equal to 2 g/L.
Water level data obtained in October 2013 are shown with water level
contours, inferring patterns of groundwater movement, on Figure 20. The data
indicate that a cone of depression, generally centered on PV-14, occurs as a result
of focused LAU pumping at the MRTF extraction wells and PCX-1. A cone of
depression is also apparent from LAU pumping at CGTF extraction well COS-75A.
Consistent with the specified performance measure, these cones of depression
direct water from the LAU plume toward extraction wells tied into treatment.
Projected capture zones from the NIBW Model pumping scenario known as Plan A
are depicted on Figure 25. Plan A represents the NIBW groundwater remedy that is
to a large extent already in operation, and will be fully operational once the
replacement well for CGTF extraction well COS-71 (COS-71A) is brought on-line in
2014. Model simulated capture zones for Plan A provide additional support for the
conclusion that pumping of the MRTF, NGTF, and CGTF extraction wells results in
combined hydraulic capture that encompasses and extends well beyond the LAU
plume.
44
With regard to reported TCE levels, compliance with the second achievement
measure was not fully attained in 2013. As indicated in Tables 4 and 5, as well as
in Appendix C, TCE concentrations were above the 2 g/L performance metric at
monitor well PG-42LA in the quarterly sample obtained in January and at extraction
well PV-14 in monthly samples obtained in November and December.
When similar results were reported at wells PG-42LA and PV-14 in 2011,
contingency response actions included data acquisition and analyses to further
characterize LAU groundwater conditions. The overall findings from this nearly
year-long work effort indicated that the NIBW remedy was performing effectively to
contain the northern LAU plume. As indicated on Figure 25, TCE mass in the
vicinity of monitor well PG-42LA is effectively captured at extraction well PV-14 and
treated at the MRTF. In addition, TCE concentrations at PV-14 continue to be
relatively stable due to cooperative operation of the MRTF extraction wells and other
PV production wells consistent with the optimized pumping strategy. Plume
containment and capture of the leading edge of the northern LAU plume are
documented by multiple lines of evidence including evaluation of water quality data,
water level data, and groundwater modeling analyses. As indicated above,
contingency actions associated with northern LAU capture were temporarily
suspended in 2012 pending review and analysis by the NIBW Technical Committee
to reassess GMEP performance measures and, as appropriate, establish updated
metrics.
The effectiveness of the NIBW remedy in containing the LAU plume hinges
on the focused and consistent pumping of MRTF and NGTF extraction wells to
capture the leading edge of the plume and the combined actions of other remedy
components such as groundwater extraction at CGTF, Area 7, and Area 12 to limit
movement of TCE mass to the PV pumping center. In general, water quality trends
in LAU monitor and extraction wells substantiate the effectiveness of the remedy.
Declining TCE concentrations in CGTF extraction wells and monitor wells in the
southern portion of the LAU plume indicate decreasing TCE mass loading from the
southern to the northern LAU over time2. Monitoring of TCE mass removed over 2 Increasing TCE concentrations at S-2LA and PA-13LA are inconsistent with the wider trends of generally declining TCE levels throughout the NIBW Site. As previously noted, additional monitoring will be conducted at
45
time at MRTF extraction wells shows that PCX-1 is responsible for over 90 percent
of the TCE mass being captured in the northern LAU, preventing a large portion of
the LAU plume from reaching the PV wellfield.
Hydraulic capture of the northern LAU plume is strongly controlled by the
distribution of pumping between the various wells in the PV well field and
coordinated efforts to focus pumping at wells (PV-15 and PV-14) that are tied into
treatment. Figure 26 is a stacked bar chart showing total annual pumping volume
for PV wells and PCX-1 for the time period 1990 through 2013. Wells are stacked in
order of their position from south to north in the well field, such that annual pumpage
for well PCX-1, the southern-most extraction well, is on the bottom and annual
pumpage for well PV-17, the northern-most extraction well, is near the top of each
bar. At the very top of each bar, pumping from SRP well 22.6E,10N, which is
located southeast from PV-14, has been added. Although this well is completed
across both the MAU and LAU, it contributes to some LAU pumping in this region
when it is operated by SRP. Pumping volumes contributed by PCX-1 and the MRTF
extraction wells are shown in shades of red, whereas pumping volumes for wells
where treatment is not available are shown in shades of blue and green. Well SRP
well 22.6E,10N is shown in pink.
TCE concentrations observed at PG-42LA since 2008 and at PV-14 since
2010 correlate to changes in PV pumping patterns that occurred in the past 6 years.
From 1998 through 2006, pumping was focused more heavily on the southern
extraction wells (PCX-1, PV-14, and PV-15) that are tied into treatment at the MRTF.
As summarized below, during this period the MRTF extraction wells combined to
produce 61 percent of the total groundwater withdrawn in the PV pumping center. In
contrast, the combined pumping of peripheral production wells (PV-11, PV-12,
PV-16, PV-17 and SRP 22.6E,10N) averaged only 39 percent of the total pumping.
During the period 2007 through part of 2010, however, a decrease in the portion of
LAU pumping by MRTF extraction wells occurred. Focused pumping of MRTF
extraction wells was restored midway through 2010 and continued in 2011, 2012,
and most of 2013 (Figure 26 and Table 6). these wells in 2014 to more closely track and characterize changing water quality in this portion of the northern LAU.
46
1998 – 2006
Average 2007 2008 2009 2010 2011 2012 2013
Combined Production:
PCX-1 and MRTF
Extraction Wells
61% 52% 34% 41% 53% 64% 61% 57%
Combined Production:
Peripheral Production
Wells
39% 48% 66% 59% 47% 36% 39% 43%
Since July 2010 EPCOR has maintained prioritized pumping of wells tied into
treatment and is currently, to the extent feasible, carrying out a south to north
pumping strategy for wells north of PV-14, which has been shown through model
projections to optimize plume containment. As indicated in Figure 26, the
proportion of groundwater extracted at PV-15 and PV-14 in 2013 was slightly less
than in the previous 2 years due to limited operation of these wells in October
through December while a new control system was installed at the MRTF (Table 6).
Based on all available data and model projections notwithstanding the
performance measure issues at S-2LA, PG-42LA, and PV-14, the NIBW PCs
conclude that the northern LAU remedy is operating effectively through
implementation of a coordinated extraction and treatment strategy that optimizes
plume containment. The findings indicate the northern LAU remedy meets overall
groundwater containment performance standards defined in the ACD and SOW.
Discussion of more meaningful LAU performance measures that may be considered
during the GMEP re-evaluation process is on-going with the NIBW Technical
Committee.
4.2.6 Evaluation of Need for Modeling Analyses
The remedy for the NIBW Site established in the Amended ROD includes
periodic use of modeling analyses to "assess the accuracy over time of projections
in the Feasibility Study Addendum (FSA)". In the GMEP, the PCs presented, and
EPA and ADEQ approved, a detailed approach to determining when modeling
analyses would be conducted, what the scope of modeling analyses would
47
comprise, and how results of modeling analyses would be used. Based on the
approach described in the GMEP, modeling analyses would be conducted as part of
the Five-Year Review process for the Site. In addition, the need for modeling
analyses would be considered under the following circumstances: 1) if large-scale
changes in the magnitude or pattern of groundwater pumping are planned or have
occurred subsequent to the most recent modeling effort, and/or 2) if contingency
response actions are initiated due to a lack of compliance with specific achievement
measures for any component of the remedy.
During 2010 and 2011, the NIBW PCs, with oversight by EPA’s contractor,
conducted detailed modeling analyses to support evaluation of the NIBW Site
groundwater remedy performance as part of the on-going EPA Five-Year Review.
As part of this effort, the original Feasibility Study Addendum groundwater model
was updated, recalibrated, and used to project MAU/LAU hydraulic capture and
estimate groundwater cleanup times. The updated model still remains a useful tool
for specific purposes such as predicting patterns of groundwater movement and
hydraulic capture associated with groundwater pumping occurring at the Site or
changes to the pumping regime. In fact, the model was used in 2012 to support
decisions regarding pumping changes associated with COS end-use of PCX-1 water
and replacement of existing CGTF extraction well COS-71 with new extraction well
COS71A. In 2013, the model was used to determine locations for more optimal
MAU groundwater extraction to enhance the Area 7 MAU source control program.
Uses of the model of this kind will continue as warranted to evaluate any additional
proposed changes in the remedial pumping regime that might arise.
4.3 ASSESSMENT OF GROUNDWATER TREATMENT PERFORMANCE
STANDARDS
Performance of the NIBW groundwater treatment systems is evaluated based
on criteria established in the SOW and compliance with Groundwater Cleanup
Standards specified in the Amended ROD. The following sections summarize
monitoring data obtained during 2013 with respect to groundwater treatment
performance standards at the five treatment facilities.
48
4.3.1 Evaluation of the Central Groundwater Treatment Facility
Section III.C of the SOW requires that treated groundwater from the CGTF
meet cleanup standards for NIBW COCs, as set forth in Table 3 of the Amended
ROD. Cleanup standards defined in Table 3 are equivalent to MCLs adopted by
EPA pursuant to the Safe Drinking Water Act (42 U.S.C. §§ 300f-300j-11), as shown
in the following table.
Contaminants of Concern MCL
(g/L)
Trichloroethene (TCE) 5.0
Tetrachloroethene (PCE) 5.0
1,1-Dichloroethene (DCE) 7.0
1,1,1-Trichloroethane (TCA) 200
Chloroform (TCM) 6.0*
* Chloroform produced as a byproduct of municipal water supply disinfection is exempt from the treatment standard for chloroform identified in Table 3 of the Amended ROD.
Throughout 2013, samples of treated groundwater have been collected in the
common sump at the CGTF and analyzed for the NIBW COCs on at least a weekly
basis when the treatment facility was in operation. NIBW COC concentrations in all
common sump samples consistently achieved the cleanup standards set forth in
Table 3 of the Amended ROD. Compliance monitoring data indicate all common
sump samples were at or below the 0.50 g/L MRL for TCE and other NIBW COCs.
4.3.2 Evaluation of the Miller Road Treatment Facility
Section III.C of the SOW requires that treated groundwater from the MRTF
meet the cleanup standards set forth in Table 3 of the Amended ROD. Further,
treated groundwater from the MRTF that is discharged to SRP’s water supply
system at the Arizona Canal is required to meet AZPDES permit limits.
49
Treatment of groundwater from extraction well PCX-1 at MRTF continued
through August 6, 2013 pursuant to the EPA-approved IOP. The results of sampling
and analyses are summarized in Section 2.2 and the data included in Table 9 of this
SMR. As indicated, NIBW COC concentrations in all treated groundwater samples
from the PCX-1 Treatment Train, as well as treatment of EPCOR well PV-15,
consistently achieved the cleanup standards set forth in Table 3 of the Amended
ROD. Compliance monitoring data indicate all samples were at or below the
0.50 g/L MRL for TCE and other NIBW COCs.
Treated groundwater discharged to the SRP water supply system at the
Arizona Canal outfall was tested monthly for TCE and pH and quarterly for physical
and inorganic water quality parameters as required by the AZPDES permit. The
results of sampling and analyses were presented in monthly DMRs submitted to
ADEQ and document the discharge was within allowable limits for the AZPDES
permit throughout 2013.
4.3.3 Evaluation of the NIBW GAC Treatment Facility
EPA selected GAC treatment of groundwater at the NGTF as the long-term
solution for extraction well PCX-1 in the ESD dated March 2012. The ESD does not
change any of the Applicable or Relevant and Appropriate Requirements previously
identified by EPA and therefore requires that treated groundwater from the NGTF
meet the cleanup standards set forth in Table 3 of the Amended ROD. Further,
treated groundwater from the NGTF that is discharged to the SRP water supply
system at the Arizona Canal is required to meet AZPDES permit limits.
Extensive functional testing of GAC treatment was conducted at the NGTF
beginning in July 2013 under the EPA-approved Start-up and Commissioning
Monitoring Plan, followed by a 60-day commissioning test to demonstrate treatment
performance of NGTF. Results of weekly NGTF sampling and analysis are included
in Table 9. As evidenced from the data, all treated water samples from NGTF were
below the respective MCLs and consistently achieved the cleanup standards set
forth in Table 3 of the Amended ROD. In fact, performance monitoring data indicate
50
all treated water samples were at or below the 0.50 g/L MRL for TCE and other
NIBW COCs.
Treated groundwater discharged to the SRP water supply system at the
Arizona Canal outfall was tested monthly for TCE, PCE, and pH; quarterly for
inorganic water quality parameters; and semi-annually for 1,1-DCE, TCA, and
Chloroform as required by the AZPDES permit. The results of sampling and
analyses were presented in monthly DMRs submitted to ADEQ and document the
discharge was within allowable limits for the AZPDES permit throughout the 2013
operating period.
4.3.4 Evaluation of the Area 7 Groundwater Treatment System
Section III.C of the SOW requires that treated groundwater from the Area 7
GWETS meet cleanup standards set forth in Section XII.B.7.b of the Amended ROD.
Specifically, in the case of Area 7, treated water used to recharge the aquifer must
meet substantive requirements of the Underground Injection Control (UIC) Program.
Discharges of treated water to the aquifer via injection wells at Area 7 that are
subject to the UIC Program are regulated in Arizona by ADEQ under the Aquifer
Protection Permit (APP) Program. The APP Program requires that any discharges
to the aquifer must not cause or contribute to a violation of AWQS. In Arizona, all
groundwater is classified for drinking water protected use so AWQS are primary
drinking water standards by rule. If an AWQS is already exceeded at the point of
compliance in groundwater then the discharge must not cause further degradation of
the aquifer with respect to the parameter that exceeds the standard.
Throughout 2013, samples of treated groundwater have been collected from
air stripper effluent at the Area 7 GWETS and analyzed for NIBW COCs on at least
a monthly frequency while the system was in operation. The results of sampling and
analysis are included in Table 9. As evidenced from the data, the NIBW COC
concentrations in all treated water samples from the Area 7 GWETS were below the
respective MCLs; and therefore, the discharge meets Arizona AWQS for these
parameters.
51
Treated groundwater that is discharged to Area 7 injection wells recharges
the UAU groundwater system. Inorganic water quality in the UAU is typically of
lower quality than that of treated groundwater from the Area 7 GWETS, which is
mostly derived from the MAU. As discussed in Section 2.3.2 of this report and
evidenced by inorganic water quality data reported in the NIBW Supplemental Data
Submittal for October 2013 (issued concurrently with this SMR), injection of treated
water from the Area 7 GWETS does not contribute to further degradation of
inorganic water quality in UAU groundwater.
4.3.5 Evaluation of the Area 12 Groundwater Treatment System
Section III.C of the SOW requires that treated groundwater from the Area 12
GWETS meet cleanup standards set forth in Section XII.B.7.b of the Amended ROD.
Specifically, in the case of Area 12, treated water that is discharged to the SRP
water supply system must meet substantive requirements of the governing AZPDES
permit.
Throughout 2013, samples of treated groundwater have been collected from
air stripper effluent at the Area 12 GWETS and analyzed for NIBW COCs on at least
a monthly frequency while the system was in service. The results of sampling and
analysis are included in Table 9. As evidenced from the data, the NIBW COC
concentrations in all treated water samples from the Area 12 GWETS were below
the respective MCLs; and therefore, met the AZPDES permit limits for discharge of
VOCs to the SRP water supply system. Although groundwater at Area 12 is treated
to achieve MCLs, the receiving water is currently used for irrigation water supply in
the SRP Grand Canal. Additional sampling and analysis for physical and inorganic
water quality parameters is reported in monthly DMRs submitted to ADEQ and
confirm the discharge was within allowable limits for the AZPDES permit throughout
2013.
52
4.4 PROGRESS TOWARD ACHIEVEMENT OF REMEDIAL ACTION OBJECTIVES
EPA established seven (7) Remedial Action Objectives (RAOs) for the NIBW
Site in the September 2001 Amended ROD. The following is a qualitative
discussion of the progress achieved in satisfying RAOs, based on review of data
through 2013.
Remedial Action Objective #1:
Restore the Upper, Middle, and Lower Aquifers to drinking water quality by decreasing the concentrations of the contaminants of concern to below the cleanup standards.
Significant progress has been made towards the removal of NIBW COCs and
restoration of groundwater to drinking water quality with respect to these COCs. In
2013, the NIBW remedial actions resulted in the extraction and treatment of nearly
5 billion gallons of groundwater and removal of over 2,700 pounds of TCE, as shown
in Table 8. From the inception of the NIBW groundwater remedy in 1994, over
98 billion gallons of groundwater have been extracted to remove an estimated
82,000 pounds of TCE. Furthermore, soil remedial actions (as discussed in
RAO #6) have eliminated the threat to groundwater from historical sources of TCE at
EPA-identified source areas. As a consequence, TCE concentrations have
dramatically decreased in the UAU and significantly decreased in portions of the
MAU and LAU.
The data indicate that the most significant declines in TCE concentrations are
in UAU groundwater. According to UAU mass flux calculations, the estimated VOC
mass in the UAU has declined from more than 11,000 pounds in 1993 to
approximately 213 pounds in 2013, representing a decrease of around 98 percent in
the past 20 years (Figure 18). TCE concentrations in the UAU have decreased
correspondingly. Presently, only 3 UAU monitor wells exceed the MCL for TCE and
the highest TCE concentration in the UAU is 9.1 g/L at PG-22UA. Historically, TCE
concentrations in UAU groundwater have been two to three orders of magnitude
higher. The extent of VOC impact in the UAU has also been greatly reduced and,
53
as evident in Figure 10, only very localized TCE plumes remain. Based on the
widespread decrease of TCE in UAU groundwater throughout the NIBW Site, EPA
approved and the NIBW PCs conducted formal abandonment of 30 UAU monitor
wells in 2013. As noted in Section 4.2.1, the UAU groundwater data derived from
October 2013 achieved the performance criterion for the UAU mass flux metric
defined in the GMEP.
Stable to declining TCE concentrations are evident in most MAU and LAU
monitor and extraction wells (Appendix C). Within the MAU, water quality data
obtained at monitor and extraction wells generally show the impact of the significant
mass removal that has taken place since initiation of the MAU source control
programs. With the exception of increasing trends at a few wells as a result of
changing pumping patterns, TCE concentrations in groundwater in the MAU are
generally stable to declining. TCE concentrations at MAU monitor wells down-
gradient from the zones of capture associated with Area 7 (PA-12MA) and Area 12
(E-8MA) source control programs have generally declined since the onset of source
control pumping, demonstrating the effectiveness of MAU source control in limiting
TCE migration to the western margin (Figures 21 and 23).
Historical LAU water quality data demonstrate a clear trend of declining TCE
concentrations in most wells in the southern portion of the plume and progress
toward aquifer restoration. Consistent operation of CGTF extraction wells over the
past 18 years has captured and limited the migration of higher TCE concentrations
to the northern LAU extraction wells connected to the MRTF. With the exception of
wells S-2LA and PA-13LA3, TCE concentrations observed in the northern LAU are
for the most part stable and may show slightly increasing or slightly decreasing
trends (Figure 25 and Appendix C). While increases at some wells are anticipated
based on the remedy design for migration of LAU mass toward PCX-1 and the other
MRTF extraction wells, stabilizing trends at other wells indicate that mass migration
toward the northern LAU is being effectively controlled by extraction wells to the
south. Monitoring data reported on an on-going basis in Table 8 indicate pumping
3 Additional monitoring will be conducted at these wells in 2014 to more closely track changing water quality in this portion of the northern LAU and evaluate potential mechanisms associated with these data trends.
54
of well PCX-1 is responsible for capturing around 90 percent of the TCE mass
extracted and treated by northern LAU extraction wells.
Remedial Action Objective #2:
Protect human health and the environment by eliminating exposure to contaminated groundwater.
As discussed in Section 4.3, groundwater that is extracted as part of the
NIBW Site remedy has been treated to meet the groundwater cleanup standards
specified in the Amended ROD.
Remedial Action Objective #3:
Provide the City of Scottsdale with a water source that meets MCLs for NIBW contaminants of concern.
The CGTF was constructed to provide treatment of TCE-impacted
groundwater for COS beneficial use. Since the CGTF began operation under COS
in 1994, the CGTF has treated almost 57 billion gallons of groundwater to meet
MCLs for the NIBW COCs. The treated groundwater is used as a supply to the COS
potable water system.
Remedial Action Objective #4:
Achieve containment of the groundwater contamination plume by preventing any further lateral migration of contaminants in groundwater.
As discussed in Section 4.2, the combined groundwater extraction tied to
treatment at the CGTF, MRTF, NGTF, Area 7 GWETS, and Area 12 GWETS has
achieved hydraulic containment throughout the MAU/LAU plume. The most current
water level data continue to demonstrate that the direction of groundwater
movement within the MAU/LAU plume is generally toward the NIBW extraction
55
wells. Modeling analyses were conducted to evaluate remedy changes, such as
replacement of CGTF extraction well COS-71 or Area 7 extraction well 7EX-5MA.
These model simulations provide further validation that the current and planned
pumping strategy provides hydraulic containment of the MAU and LAU plumes.
TCE concentrations at monitor wells located near the edge or along the periphery of
the MAU/LAU plume show decreasing trends in many parts of the Site. In cases
where trends at specific wells are increasing (S-2LA and PA-13LA), the NIBW PCs
continue to work with the Technical Committee to conduct analyses and collect more
frequent monitoring data to ensure that the overall objectives of the LAU remedy are
maintained.
Remedial Action Objective #5:
Reuse of the water treated at the Site to the extent possible in accordance with Arizona’s Groundwater Management Act.
Treated water produced by all five NIBW GWETS is beneficially used. The
CGTF and NGTF provide treated groundwater as a supply to the COS potable water
system, or may alternately deliver treated water to SRP. The MRTF treats
groundwater for use by EPCOR. At Area 7, treated groundwater is delivered to
shallow injection wells that recharge the UAU aquifer. At Area 12, treated
groundwater is provided to the SRP water system for irrigation use. All NIBW end-
uses are consistent with beneficial use designations of the ADWR and in
accordance with the Groundwater Management Act. Furthermore, the NIBW
remedy has incorporated COS, SRP, and EPCOR as end users of treated
groundwater in lieu of groundwater pumping they have historically conducted and
would have otherwise relied upon in this area.
Remedial Action Objective #6:
Mitigate any soil contamination that continues to impact groundwater.
As described in Section 3.0, the NIBW PCs have implemented soil
remediation at four EPA-identified source areas, including Areas 6, 7, 8, and 12.
56
The collective soil remediation has resulted in the removal of over 10,000 pounds of
TCE from the unsaturated zone and eliminated these sources as an ongoing threat
for groundwater impacts. At the present time the soil remediation is complete at
Areas 6, 8, and 12. The Area 7 SVE system was pulsed from July 2008 to
December 2009 to remove the limited residual TCE that remained in recalcitrant soil
horizons. Soil vapor monitoring and modeling conducted in 2013 indicate that SVE
has effectively eliminated the threat to groundwater at Area 7. These findings are
documented in a technical memorandum that is currently being finalized by the PCs,
providing the basis for discussions with the Technical Committee regarding closure
and decommissioning of the Area 7 soil remedy. The overall effectiveness of NIBW
soil cleanup at all historical NIBW source areas is demonstrated by the significant
reduction of TCE concentrations and mass in UAU groundwater. In fact, TCE
concentrations in UAU groundwater down-gradient from Area 7 are all below the
5 g/L drinking water MCL and only three wells remain above the MCL down-
gradient from Area 12.
Remedial Action Objective #7:
Provide long-term management of contaminated groundwater to improve the regional aquifer’s suitability for potable use.
The NIBW PCs have closely coordinated the planning and implementation of
NIBW remedial actions with the key water providers, including COS, SRP, and
EPCOR. The efforts have strongly focused on defining mutually beneficial
objectives for all parties involved in the remedy. For example the NIBW remedy
requires consistent and reliable groundwater extraction in the areas most favorable
for capture and containment of the MAU/LAU plumes. The water providers have
considerable, but variable water demands in the NIBW Site area and a system of
existing wells and infrastructure available for groundwater production.
Through technical discussions and cooperation, the parties have taken a
number of steps to focus groundwater extraction and end uses for optimum water
resource management. For example, the NIBW PCs have installed and modified a
number of the water provider wells to improve groundwater plume capture and mass
57
removal. To assure the water providers can utilize the treated groundwater, the
NIBW PCs have upgraded treatment systems to assure acceptable water quality
and enhanced infrastructure and control systems for the water providers. The water
providers have cooperated by prioritizing pumping to meet water demands using
those wells most beneficial to the remedy.
The intensive, on-going deliberations that occurred during the planning
process for operation, treatment, and end-use of water extracted from well PCX-1
are indicative of the NIBW stakeholders’ extraordinary efforts to seek long-term
solutions beneficial to all parties’ use of the regional aquifer for future potable water
supply. Following over 3 years of discussions and consideration of 10 proposals for
long-term measures for PCX-1 treatment and end-use, all parties agreed to the
NIBW PCs proposal to construct the NGTF to provide liquid-phase granular
activated carbon treatment for PCX-1 at a new plant operated by COS in order to
supply PCX-1 treated water to the CWTP for COS end use. This approach
addresses EPA requirements for reliable, long-term treatment of well PCX-1, COS
concerns regarding local groundwater use and sustainability, and SRP interests in
serving stakeholder water for COS on-Project use. The NGTF was authorized by
ESD in March 2012 and became operational in 2013. In conjunction with the PCX-1
treated water from well PCX-1 for beneficial end use in its system, COS will take
steps to curtail pumping of CGTF extraction wells of diminishing importance to the
NIBW remedy (i.e. wells COS-31 and COS-72).
4.5 MANAGEMENT OF UNTREATED GROUNDWATER
Section VI.B.4.n of the SOW requires COS, SRP, and the NIBW PCs to
provide a report describing the creation and maintenance of records to document
compliance with Section VI.B.4.a through VI.B.4.m of the SOW. Section VI.B.4
specifies provisions for managing untreated groundwater extracted from NIBW wells
as part of the remedy and requires that groundwater be managed as if it were a
hazardous waste by following the requirements set forth in Sections VI.B.4.a through
VI.B.4.m. The NIBW PCs, SRP, and COS are submitting the following information
to fulfill the requirements for annual reporting of compliance with Section VI.B.4 of
58
the SOW. For ease of reference, information regarding COS, SRP, and the NIBW
PCs management practices pertaining to applicable requirements of Section VI.B.4
are referenced in the order listed in the SOW.
Section VI.B.4.a – normal operation, maintenance, and monitoring activities:
The NIBW PCs have specified procedures for management of untreated
groundwater associated with sampling activities at the MRTF, Area 7 GWETS, and
Area 12 GWETS and well equipment maintenance in O&M Plans that were
approved by EPA and ADEQ on June 8, 2006, and for NGTF on June 24, 2013.
SRP has developed and followed procedures for managing untreated groundwater
during monitor well sampling in the Phase I SAP. In accordance with the Phase I
SAP, untreated groundwater resulting from purging and sampling of NIBW monitor
wells was treated to MCLs using granular activated carbon during 2013. In 2013,
well access was restricted during well and well equipment maintenance activities
conducted at SRP NIBW extraction well facilities. There were no accidental
releases of untreated groundwater from COS-31 or the Granite Reef well during
2013. There was one release of untreated groundwater from the PCX-1 well
pipeline connected to the NGTF. On August 6, 2013, approximately 10,000 gallons
of untreated groundwater from the PCX-1 pipeline was accidentally released into the
Arizona Canal. One of the three pipeline air relief valves failed during start-up of the
NGTF. All necessary mitigation measures were taken to protect and notify
downstream water treatment plants. SRP worked with the NIBW Technical
Committee, ADEQ and EPA to ensure corrective actions are implemented to prevent
future occurrences.
SRP’s obligation to collect, analyze and report groundwater sampling and
water level data from specific NIBW monitor wells ended in March 2013. During the
April 2013 sampling event, SRP provided transition assistance.
COS has specified procedures for management of untreated groundwater
associated with sampling activities at the CGTF and well equipment maintenance in
an EPA-approved O&M Plan. In 2013, COS handled all untreated groundwater for
59
CGTF and its related pipelines and well sites in accordance with the O&M Plans and
this section of the SOW. COS conducts monthly routine safety inspections of the
facility and all equipment related to the facility such as the air fans, pumps, heaters,
well sites, raw water transmission lines, air relief valves, SCADA alarms, dialers and
pagers, and conducts maintenance on a scheduled routine basis and as needed.
Section VI.B.4.d – annual treatment facility inspections:
Each NIBW groundwater treatment facility is inspected on a routine basis, as
part of the normal operation and maintenance procedures, for equipment
malfunction and deterioration that could result in the release of untreated
groundwater.
As explained in Section 2 and Appendix D of this report, the NIBW PCs
coordinated inspections of Area 7 and Area 12 GWETS on December 3, 2013 and
MRTF, PCX-1, CGTF, and NGTF on December 4, 2013 in accordance with Section
VI.B.4.d of the SOW. The groundwater treatment and extraction systems were
inspected for malfunctions, deterioration, operator practices or errors, that could
result in a release of untreated groundwater. At each facility, the major system
components were identified and examined for operability, condition of operating
equipment, and management of untreated groundwater and residual materials.
Additionally, data related to routine operation, system startup and shutdown, routine
and non-routine maintenance, and sampling were reviewed.
The inspections indicate that the facilities appeared to be in good working
condition and are operated proficiently. Based on these findings, the NIBW PCs
conclude the facility operations comply with the Amended CD/SOW. No hazardous
waste is generated, handled, or stored at the NIBW groundwater treatment plants.
A summary report documenting the site inspection for each facility is provided in
Appendix D.
60
Section VI.B.4.e – training for responding to releases of untreated groundwater:
The NIBW PCs submitted a plan for health and safety training of GWETS
Operators and Emergency Coordinators to EPA as part of materials included in an
August 1, 2003, “Submittal of Information Required, Section VI of the Statement of
Work” provided to EPA and ADEQ. The plan specified steps to be conducted for
personnel at all GWETS to assure that they will have appropriate health and safety
training to respond to releases of untreated groundwater in a manner to protect
public health and the environment.
In 2013, COS provided on-line emergency response and incident
management training for an untreated groundwater release for CGTF, NGTF and
Area 7 raw water pipelines. The training sessions are performed on-line and the
training is tracked within the COS training management program.
The Contingency and Emergency Response Plan (CERP) for Accidental
Releases of Untreated Groundwater from SRP North Indian Bend Wash Site
Extraction Wells, prepared by SRP, dated January 2007, and updated September
2012, describes the training to be conducted for personnel responding to an
accidental release of untreated groundwater from an SRP facility.
Section VI.B.4.f and g – land disposal of untreated groundwater:
The NIBW PCs, SRP, and COS have not placed untreated groundwater in
any salt dome formation, salt bed formation, underground mine or cave, surface
impoundments, waste piles, land treatment units, incinerators, or landfills.
Section VI.B.4.h – emergency and contingency response plans:
The EPA approved Contingency and Emergency Response Plans (CERPs)
for the CGTF, MRTF, Area 7 GWETS, Area 12 GWETS, and SRP Extraction Wells
in 2007. The NIBW PCs prepared CERPs for the MRTF, Area 7 GWETS and
Area 12 GWETS; COS prepared the CGTF CERP (updated August 2012); and SRP
prepared the CERP (updated September 2012) for SRP extraction wells used in the
61
NIBW Site remedial actions. The NIBW PCs plan to submit a CERP for NGTF in
second quarter 2014 along with revisions to CERPs for MRTF, Area 7 GWETS, and
Area 12 GWETS.
Section VI.B.4.i – emergency coordinators:
The NIBW PCs, COS, and SRP list designated emergency response
coordinators for the five groundwater treatment facilities and the extraction well
network. Currently identified personnel responsible for emergency response at the
NIBW groundwater treatment facilities are listed in Appendix A.
Section VI.B.4.j – evidence of Holocene faults:
The NIBW PCs and SRP provided written verification in submittals dated
August 1, 2003 and September 3, 2003, respectively, to EPA and ADEQ indicating
the existing NIBW extraction wells and treatment systems are not located within
200 feet of a fault, which has exhibited displacement in Holocene time. There are
no recognized Holocene faults in the metropolitan Phoenix area. COS also provided
this verification in July 2003.
Section VI.B.4.k – floodplains:
COS, NIBW PCs, and SRP provided information in submittals dated July,
August, and September, 2003, respectively, to EPA and ADEQ to confirm that four
NIBW extraction wells are in locations that would be inundated by a 100-year flood.
The NIBW PCs described measures for operating the wells in the draft Groundwater
Extraction Well Network O&M Plan to insure that there will not be a release of
untreated groundwater during a 100-year storm.
62
Section VI.B.4.l – closure:
In 2013, the NIBW PCs abandoned 30 UAU groundwater monitoring wells at
the NIBW Site, 13 of which were owned by COS. SRP did not abandon any wells
associated with the NIBW project. There were no facility closure activities in 2013.
5.0 SUMMARY
As set forth herein and consistent with the conclusions reached by EPA in the
First Five-Year Review report that was issued in 2012, the NIBW Superfund Site
remedial actions continue to result in an effective groundwater remedy that is
operating as designed. The table below summarizes the estimated rates of
groundwater extracted and TCE mass removed in 2013 in the UAU, MAU, and LAU
at each of the extraction wells connected to treatment. The collective remediation
efforts through 2013 have achieved significant progress toward the long-term goal of
aquifer restoration while providing plume containment and beneficial use of vital
groundwater resources. Continued progress is anticipated through on-going
operation and monitoring of the NIBW remedial action program in 2014.
63
64
6.0 DOCUMENTS SUBMITTED IN 2013 During the period January through December 2013, the NIBW PCs and SRP provided the following documents to EPA and ADEQ. Additionally, Motorola Solutions, on behalf of the NIBW PCs, submitted payment for EPA 2011 NIBW Oversight Costs on April 25, 2013 and for ADEQ 2012 NIBW Oversight Costs on August 14, 2013. “Notification of On-Going Monitoring – January 2013 Groundwater Sampling of M-10MA2 Monitor Well Located at Lowe’s of South Scottsdale”, letter submitted by NIBW PCs on January 10, 2013. “Planned Annual Water Discharges to Salt River Project Water System”, letter submitted to SRP by NIBW PCs on January 18, 2013. “Recommendations for Upper Alluvial Unit Aquifer Long-Term Groundwater Monitoring Program, North Indian Bend Wash Superfund Site, Scottsdale, Arizona”, technical memorandum submitted by NIBW PC on January 31, 2013. “Request for Extension of Report Submittal Date”, letter submitted by NIBW PCs on February 6, 2013. “System Contingency Summary, Central Groundwater Treatment Facility”, draft report submitted by NIBW PCs on February 22, 2013. “2012 Site Monitoring Report, North Indian Bend Wash Superfund Site, Volume I: Text, Tables, and Illustrations”, technical report submitted by NIBW PCs on March 14, 2013. “2012 Site Monitoring Report, North Indian Bend Wash Superfund Site, Volume II: Appendix A-F”, technical report submitted by NIBW PCs on March 14, 2013. “Groundwater Monitoring Program Data, North Indian Bend Wash Superfund Site”, data submittal by NIBW PCs on March 14, 2013. “Groundwater Extraction and Treatment System Data, North Indian Bend Wash Superfund Site”, data submittal by NIBW PCs on March 14, 2013. “Supplemental Data Collection at the Area 7 GWETS During October 2012, NIBW Superfund Site”, data submittal by NIBW PCs on March 14, 2013. “MRTF PCX-1 Treatment Train Influent & Effluent Data Submittal, Fourth Quarter 2012”, data submittal by NIBW PCs on March 14, 2013.
65
“Summary of 2012 Air Sampling Data, North Indian Bend Wash Superfund Site”, data submittal by NIBW PCs on March 14, 2013. “2012 Water Quality Report for the Paradise Valley District of EPCOR Water”, consumer confidence report submitted by NIBW PCs on March 18, 2013. “Start-Up and Commissioning Monitoring Plan, NIBW Granular Activated Carbon Treatment Facility”, submitted by the NIBW PCs on May 21, 2013. “Operation and Maintenance Plan, NIBW Granular Activated Carbon Treatment Facility”, draft report submitted by NIBW PCs on April 2, 2013. “Notification of On-Going Monitoring – April 2013 Groundwater Sampling of M-10MA2 Monitor Well Located at Lowe’s of South Scottsdale”, electronic mail submitted by NIBW PCs on April 8, 2013. “Final Revised System Contingency Summary, Central Groundwater Treatment Facility”, submitted by the NIBW PCs on April 12, 2013. “Work Plan, Area 7 Middle Alluvial Unit Source Control, Proposed Actions in Response to Non-Conformance with Performance Measures”, submitted by NIBW PCs on April 12, 2013. “System Contingency Summary, Central Groundwater Treatment Facility”, submitted by NIBW PCs on April 26, 2013. “Start-Up and Commissioning Monitoring Plan, NIBW Granular Activated Carbon Treatment Facility”, submitted by the NIBW PCs on May 21, 2013. “Quarterly Report, January through March 2013, North Indian Bend Wash Superfund Site”, submitted by NIBW PCs on May 30, 2013. “MRTF PCX-1 Treatment Train Influent & Effluent Data Submittal, First Quarter 2013”, data submittal by NIBW PCs on May 30, 2013. “Demonstration of Financial Ability, North Indian Bend Wash Superfund Site”, submitted on compact disks by NIBW PCs on June 10, 2013. “Response to Comments, Draft Operation and Maintenance Plan, NIBW Granular Activated Carbon Treatment Facility”, submitted by NIBW PCs on June 19, 2013. “Operation and Maintenance Plan, NIBW Granular Activated Carbon Treatment Facility”, submitted by NIBW PCs on June 19, 2013.
66
“Notification of On-Going Monitoring – July 2013 Groundwater Sampling of M-10MA2 Monitor Well Located at Lowe’s of South Scottsdale”, electronic mail submitted by NIBW PCs on July 2, 2013. “PCX-1 Pipeline Valve Release of Untreated Groundwater to Arizona Canal on August 6, 2013, North Indian Bend Wash”, submitted by SRP on August 13, 2013. “North Indian Bend Wash – PCX-1 Pipeline Valve Release of Untreated Groundwater to Arizona Canal, August 6, 2013, Follow Up Report – Final Laboratory Reports”, submitted by SRP on August 22, 2013. “Quarterly Report, April through June 2013, North Indian Bend Wash Superfund Site”, submitted by NIBW PCs on August 28, 2013. “MRTF PCX-1 Treatment Train Influent & Effluent Data Submittal, Second Quarter 2013”, data submittal by NIBW PCs on August 28, 2013. “Certification of Completion for Area 7 Vadose Zone Work and UAU Groundwater Extraction, North Indian Bend Wash Superfund Site”, submitted by NIBW PCs on August 29, 2013. “North Indian Bend Wash – PCX-1 Pipeline Valve Release of Untreated Groundwater to Arizona Canal, August 6, 2013, Revised Report” submitted by SRP on September 30, 2013. “Notification of On-Going Monitoring – October 2013 Groundwater Sampling of M-10 Monitor Wells Located at Lowe’s of South Scottsdale”, electronic mail submitted by NIBW PCs on October 3, 2013. “Quarterly Report, July through September 2013, North Indian Bend Wash Superfund Site”, submitted by NIBW PCs on November 27, 2013. “MRTF PCX-1 Treatment Train Influent & Effluent Data Submittal, Third Quarter 2013”, submitted on compact disks by NIBW PCs on November 27, 2013.
TABLES
Page 1 of 4TABLE 1. SUMMARY OF GROUNDWATER LEVEL MEASUREMENTS TAKEN BYTERRANEXT, NORTH INDIAN BEND WASH AREA,SCOTTSDALE, ARIZONA, APRIL 2013
MONITOR WELL
IDENTIFIERMEASUREMENT
DATEDEPTH TO WATER
(ft, bls)
GROUNDWATERALTITUDE
(ft, msl)
B-1MA 4/23/2013 101.01 1,090.35B-1UAB-3UA
B-J
D-1UAD-2MA 4/4/2013 110.15 1,129.44
E-1LA 4/5/2013 142.19 1,072.15E-1MAE-1UAE-2UAE-3UAE-4UAE-5MA 4/4/2013 72.75 1,126.22E-5UAE-6UAE-7LA 4/5/2013 112.69 1,084.73E-7UAE-8MA 4/4/2013 91.15 1,101.54E-9UA
E-10MA 4/4/2013 137.85 1,104.87E-12UAE-13UAE-14LA 4/3/2013 164.89 1,088.67
M-1MA 4/11/2013 107.25 1,103.64M-2LA 4/4/2013 130.61 1,079.75M-2MA 4/4/2013 110.67 1,099.66M-2UAM-3MA 4/4/2013 102.25 1,103.42M-3UAM-4MA 4/4/2013 117.34 1,097.50M-4UAM-5LA 4/4/2013 144.09 1,073.80M-5MAM-5UAM-6MA 4/4/2013 121.14 1,097.51M-7MA 4/4/2013 117.79 1,095.20M-9LA 4/23/2013 156.96 1,062.91M-9MA 4/2/2013 110.09 1,109.61M-9UA
M-10LA2 4/2/2013 142.52 1,076.58M-10MA2 4/4/2013 117.91 1,101.89M-11MA 4/2/2013 104.62 1,106.21
Not measured due to change in monitoring programNot measured due to change in monitoring program
Recommended for Abandonment
Not measured due to change in monitoring program
Not measured due to change in monitoring program
Recommended for Abandonment
Recommended for Abandonment
Recommended for Abandonment
Recommended for Abandonment
Not measured due to change in monitoring programObstruction in sounding tube
Recommended for Abandonment
Not measured due to change in monitoring programRecommended for Abandonment
Not measured due to change in monitoring programNot measured due to change in monitoring program
Recommended for AbandonmentRecommended for Abandonment
Not measured due to change in monitoring program
Not measured due to change in monitoring program
Well buried
P:\366\2013 Annual Report\Table 1. NIBW Water Levels April 2013.xlsx
Page 2 of 4TABLE 1. SUMMARY OF GROUNDWATER LEVEL MEASUREMENTS TAKEN BYTERRANEXT, NORTH INDIAN BEND WASH AREA,SCOTTSDALE, ARIZONA, APRIL 2013
MONITOR WELL
IDENTIFIERMEASUREMENT
DATEDEPTH TO WATER
(ft, bls)
GROUNDWATERALTITUDE
(ft, msl)
M-11UAM-12MA2 4/4/2013 153.45 1,074.26M-14LA 4/2/2013 156.78 1,067.90M-14MA 4/2/2013 116.32 1,108.31M-15MA 4/5/2013 117.15 1,101.51M-15UAM-16LA 4/23/2013 167.94 1,059.75M-16MA 4/3/2013 116.89 1,110.78M-16UA
M-17MA/LA 4/5/2013 148.59 1,089.11
PA-1MA 4/2/2013 102.95 1,122.04PA-2LA 4/4/2013 266.19 987.16PA-3MA 4/5/2013 113.39 1,139.53PA-4MA 4/4/2013 99.93 1,130.48PA-5LA 4/4/2013 245.35 983.68PA-6LA 4/5/2013 270.51 982.11PA-7MA 4/5/2013 115.82 1,136.90PA-8LA2 4/4/2013 181.97 1,045.88PA-9LA 4/4/2013 187.95 1,048.58
PA-10MA 4/4/2013 135.61 1,100.78PA-11LA* 4/4/2013 155.55 1,068.27
PA-12MA** 4/4/2013 130.05 1,093.91PA-13LA 4/4/2013 257.85 990.85PA-14MA 4/4/2013 125.59 1,123.07PA-15LA 4/3/2013 105.17 1,098.78PA-16MA 4/5/2013 100.39 1,103.60PA-17MA 4/4/2013 108.02 1,130.26PA-18LA 4/4/2013 212.69 1,025.72PA-19LA 4/3/2013 129.05 1,091.49PA-20MA 4/3/2013 125.94 1,094.42PA-21MA 4/2/2013 112.97 1,111.87PA-22LA 4/3/2013 90.75 1,092.87PA-23MA 4/3/2013 78.55 1,105.49
PG-1LA 4/23/2013 275.96 973.34PG-2LA 4/23/2013 309.39 961.26PG-3UAPG-4MA 4/3/2013 130.79 1,096.32PG-4UAPG-5MA 4/3/2013 116.46 1,097.33PG-5UAPG-6MA 4/23/2013 101.91 1,110.54PG-6UA
Recommended for Abandonment
Not measured due to change in monitoring program
Not measured due to change in monitoring program
Not measured due to change in monitoring program
Recommended for Abandonment
Recommended for Abandonment
Not measured due to change in monitoring program
P:\366\2013 Annual Report\Table 1. NIBW Water Levels April 2013.xlsx
Page 3 of 4TABLE 1. SUMMARY OF GROUNDWATER LEVEL MEASUREMENTS TAKEN BYTERRANEXT, NORTH INDIAN BEND WASH AREA,SCOTTSDALE, ARIZONA, APRIL 2013
MONITOR WELL
IDENTIFIERMEASUREMENT
DATEDEPTH TO WATER
(ft, bls)
GROUNDWATERALTITUDE
(ft, msl)
PG-7MA 4/3/2013 91.81 1,105.44PG-7UAPG-8UAPG-9UA
PG-10UAPG-11UAPG-12UAPG-13UAPG-15UAPG-16UAPG-17UAPG-18UAPG-19UAPG-20UAPG-21UAPG-22UA
PG-23MA/LA 4/5/2013 118.75 1,103.29PG-23UAPG-24UAPG-25UAPG-26UAPG-27UAPG-28UAPG-29UAPG-30UAPG-31UAPG-32UAPG-33UAPG-34UAPG-36UAPG-37UA
PG-38MA/LA 4/3/2013 139.59 1,097.31PG-38UAPG-39LA 4/3/2013 105.89 1,126.35PG-39UAPG-40LA 4/23/2013 308.65 966.68PG-42LA 4/5/2013 323.39 968.92PG-43LA 4/5/2013 296.19 968.82PG-44LA 4/5/2013 327.25 970.34PG-47MA 4/4/2013 126.35 1,091.49PG-48MA 4/4/2013 121.78 1,096.16PG-50MA 4/4/2013 152.31 1,088.43
Recommended for Abandonment
Recommended for AbandonmentRecommended for AbandonmentRecommended for AbandonmentRecommended for Abandonment
Recommended for Abandonment
Recommended for Abandonment
Not measured due to change in monitoring program
Not measured due to change in monitoring programNot measured due to change in monitoring program
Not measured due to change in monitoring program
Recommended for Abandonment
Recommended for AbandonmentRecommended for Abandonment
Recommended for AbandonmentRecommended for Abandonment
Recommended for Abandonment
Recommended for Abandonment
Recommended for AbandonmentRecommended for Abandonment
Not measured due to change in monitoring program
Not measured due to change in monitoring programNot measured due to change in monitoring program
Not measured due to change in monitoring programNot measured due to change in monitoring program
Not measured due to change in monitoring programNot measured due to change in monitoring programNot measured due to change in monitoring program
Not measured due to change in monitoring programNot measured due to change in monitoring program
Not measured due to change in monitoring program
P:\366\2013 Annual Report\Table 1. NIBW Water Levels April 2013.xlsx
Page 4 of 4TABLE 1. SUMMARY OF GROUNDWATER LEVEL MEASUREMENTS TAKEN BYTERRANEXT, NORTH INDIAN BEND WASH AREA,SCOTTSDALE, ARIZONA, APRIL 2013
MONITOR WELL
IDENTIFIERMEASUREMENT
DATEDEPTH TO WATER
(ft, bls)
GROUNDWATERALTITUDE
(ft, msl)
PG-51MA 4/4/2013 148.92 1,091.79PG-57MA 4/2/2013 113.15 1,113.66
S-1LA 4/5/2013 248.72 1,010.89S-1MA 4/5/2013 136.59 1,122.80S-2LA 4/5/2013 269.91 989.46S-2MA 4/4/2013 140.75 1,119.23ST-1UA
W-1MA 4/23/2013 105.75 1,123.69W-2MA 4/5/2013 145.55 1,088.71W-3UA
Notes:ft, bls = feet below land surface
ft, msl = feet above mean sea level* =
** =
Recommended for Abandonment
Recommended for Abandonment
collected from LAU completed well at piezometer PA-11/12 located approximately 80 feet northwest of original well PA-11LA
collected from MAU completed well at piezometer PA-11/12 located approximately 70 feet northwest of original well PA-12MA
P:\366\2013 Annual Report\Table 1. NIBW Water Levels April 2013.xlsx
Page 1 of 4TABLE 2. SUMMARY OF GROUNDWATER LEVEL MEASUREMENTS TAKEN BYTERRANEXT, NORTH INDIAN BEND WASH AREA,SCOTTSDALE, ARIZONA, OCTOBER 2013
MONITOR WELL
IDENTIFIERMEASUREMENT
DATEDEPTH TO WATER
(ft, bls)
GROUNDWATERALTITUDE
(ft, msl)
B-1MA 9/30/2013 127.59 1,063.77B-1UA 9/30/2013 57.24 1,134.17B-3UA
B-J 9/30/2013 60.72 1,130.82
D-1UAD-2MA 10/1/2013 112.47 1,127.12
E-1LA 10/2/2013 153.95 1,060.39E-1MA 10/2/2013 127.89 1,085.78E-1UA 10/2/2013 74.13 1,140.59E-2UA 10/1/2013 87.42 1,137.02E-3UAE-4UAE-5MA 9/30/2013 106.32 1,092.65E-5UA 9/30/2013 67.35 1,131.65E-6UA 9/30/2013 93.02 1,127.95E-7LA 9/30/2013 125.28 1,072.14E-7UA 9/30/2013 68.39 1,128.99E-8MA 9/30/2013 154.87 1,037.82E-9UA
E-10MA 10/1/2013 142.53 1,100.19E-12UA 9/30/2013 68.34 1,135.04E-13UA 10/3/2013 72.67 1,135.40E-14LA 10/2/2013 173.45 1,080.11
M-1MA 10/2/2013 129.28 1,081.61M-2LA 10/2/2013 143.75 1,066.61M-2MA 10/2/2013 139.55 1,070.78M-2UA 10/2/2013 74.44 1,136.75M-3MA 10/2/2013 121.61 1,084.06M-3UAM-4MA 10/2/2013 135.64 1,079.20M-4UAM-5LA 10/8/2013 156.41 1,061.48M-5MA 10/2/2013 152.04 1,065.74M-5UAM-6MA 10/2/2013 134.44 1,084.21M-7MA 10/2/2013 128.01 1,084.98M-9LA 10/2/2013 165.81 1,054.06M-9MA 10/2/2013 124.22 1,095.48M-9UA
M-10LA2 9/30/2013 154.69 1,064.41M-10MA2 9/30/2013 148.08 1,071.72M-11MA 11/13/2013 110.63 1,100.20
Abandoned 1/9/2014
Abandoned 10/31/2013
Abandoned 10/10/2013
Abandoned 10/14/2013
Abandoned 10/10/2013
Abandoned 8/2/2013
Abandoned 9/5/2013Abandoned 8/29/2013
Abandoned 10/9/2013
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Page 2 of 4TABLE 2. SUMMARY OF GROUNDWATER LEVEL MEASUREMENTS TAKEN BYTERRANEXT, NORTH INDIAN BEND WASH AREA,SCOTTSDALE, ARIZONA, OCTOBER 2013
MONITOR WELL
IDENTIFIERMEASUREMENT
DATEDEPTH TO WATER
(ft, bls)
GROUNDWATERALTITUDE
(ft, msl)
M-11UAM-12MA2 10/3/2013 138.49 1,089.22M-14LA 10/1/2013 166.97 1,057.71M-14MA 10/1/2013 128.65 1,095.98M-15MA 10/2/2013 137.98 1,080.68M-15UAM-16LA 10/1/2013 175.64 1,052.05M-16MA 10/1/2013 122.28 1,105.39M-16UA
M-17MA/LA 9/30/2013 156.12 1,081.58
PA-1MA 9/30/2013 108.69 1,116.30PA-2LA 10/2/2013 286.72 966.63PA-3MA 10/2/2013 118.01 1,134.91PA-4MA 10/2/2013 103.66 1,126.75PA-5LA 10/17/2013 267.97 961.06PA-6LA 10/2/2013 292.23 960.39PA-7MA 10/2/2013 120.35 1,132.37PA-8LA2 10/2/2013 189.91 1,037.94PA-9LA 10/2/2013 198.86 1,037.67
PA-10MA 10/2/2013 140.95 1,095.44PA-11LA* 9/30/2013 161.19 1,062.63
PA-12MA** 9/30/2013 135.91 1,088.05PA-13LA 10/2/2013 274.81 973.89PA-14MA 10/2/2013 130.15 1,118.51PA-15LA 9/30/2013 120.73 1,083.22PA-16MA 9/30/2013 131.85 1,072.14PA-17MA 10/2/2013 101.89 1,136.39PA-18LA 10/2/2013 226.52 1,011.89PA-19LA 9/30/2013 143.15 1,077.39PA-20MA 9/30/2013 140.39 1,079.97PA-21MA 10/1/2013 121.19 1,103.65PA-22LA 9/30/2013 105.79 1,077.83PA-23MA 9/30/2013 122.43 1,061.61
PG-1LA 10/1/2013 296.62 952.68PG-2LA 10/1/2013 329.32 941.33PG-3UA 9/30/2013 79.01 1,124.89PG-4MA 9/30/2013 143.97 1,083.14PG-4UA 9/30/2013 109.21 1,118.10PG-5MA 9/30/2013 137.71 1,076.08PG-5UA 9/30/2013 90.68 1,123.18PG-6MA 9/30/2013 113.98 1,098.47PG-6UA 9/30/2013 93.38 1,119.20
Abandoned 10/17/2013
Abandoned 10/16/2013
Abandoned 10/18/2013
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Page 3 of 4TABLE 2. SUMMARY OF GROUNDWATER LEVEL MEASUREMENTS TAKEN BYTERRANEXT, NORTH INDIAN BEND WASH AREA,SCOTTSDALE, ARIZONA, OCTOBER 2013
MONITOR WELL
IDENTIFIERMEASUREMENT
DATEDEPTH TO WATER
(ft, bls)
GROUNDWATERALTITUDE
(ft, msl)
PG-7MA 9/30/2013 117.99 1,079.26PG-7UA 9/30/2013 73.82 1,123.21PG-8UA 9/30/2013 98.28 1,122.70PG-9UA
PG-10UA 10/3/2013 58.31 1,182.14PG-11UA 10/3/2013 95.45 1,134.48PG-12UAPG-13UAPG-15UAPG-16UA 10/1/2013 103.79 1,137.78PG-17UAPG-18UA 10/2/2013 77.33 1,124.34PG-19UA 10/3/2013 95.95 1,108.03PG-20UAPG-21UAPG-22UA 10/1/2013 76.67 1,133.24
PG-23MA/LA 10/2/2013 132.48 1,089.56PG-23UA 10/2/2013 104.74 1,117.82PG-24UA 10/2/2013 88.81 1,123.00PG-25UA 10/1/2013 77.37 1,128.63PG-26UAPG-27UAPG-28UA 10/1/2013 95.18 1,139.27PG-29UA 10/1/2013 91.75 1,140.65PG-30UA 10/1/2013 88.01 1,137.76PG-31UA 10/2/2013 98.46 1,136.64PG-32UAPG-33UAPG-34UAPG-36UAPG-37UA
PG-38MA/LA 10/2/2013 152.76 1,084.14PG-38UAPG-39LA 10/3/2013 150.87 1,081.37PG-39UAPG-40LA 10/1/2013 329.86 945.47PG-42LA 10/1/2013 348.44 943.87PG-43LA 10/1/2013 322.49 942.52PG-44LA 10/2/2013 360.67 936.92PG-47MA 10/2/2013 135.56 1,082.28PG-48MA 10/2/2013 136.69 1,081.25PG-50MA 10/1/2013 152.01 1,088.73
Abandoned 9/5/2013Abandoned 10/7/2013
Abandoned 8/30/2013
Abandoned 10/22/2013Abandoned 9/6/2013
Abandoned 10/15/2013
Abandoned 10/9/2013
Abandoned 10/8/2013Abandoned 9/4/2013
Abandoned 10/29/2013
Abandoned 10/29/2013
Abandoned 10/29/2013
Abandoned 9/4/2013Abandoned 9/3/2013
Abandoned 8/30/2013Abandoned 10/8/2013
P:\366\2013 Annual Report\Table 2. NIBW Water Levels October 2013.xlsx
Page 4 of 4TABLE 2. SUMMARY OF GROUNDWATER LEVEL MEASUREMENTS TAKEN BYTERRANEXT, NORTH INDIAN BEND WASH AREA,SCOTTSDALE, ARIZONA, OCTOBER 2013
MONITOR WELL
IDENTIFIERMEASUREMENT
DATEDEPTH TO WATER
(ft, bls)
GROUNDWATERALTITUDE
(ft, msl)
PG-51MA 10/1/2013 154.51 1,086.20PG-57MA 10/3/2013 119.88 1,106.93
S-1LA 10/2/2013 264.06 995.55S-1MA 10/3/2013 139.72 1,119.67S-2LA 10/2/2013 293.31 966.06S-2MA 10/2/2013 145.49 1,114.49ST-1UA
W-1MA 10/1/2013 107.02 1,122.42W-2MA 10/1/2013 147.07 1,087.19W-3UA
Notes:ft, bls = feet below land surface
ft, msl = feet above mean sea level* =
** =
collected from LAU completed well at piezometer PA-11/12 located approximately 80 feet northwest of original well PA-11LA
collected from MAU completed well at piezometer PA-11/12 located approximately 70 feet northwest of original well PA-12MA
Abandoned 10/22/2013
Abandoned 10/18/2013
P:\366\2013 Annual Report\Table 2. NIBW Water Levels October 2013.xlsx
TABLE 3. SUMMARY OF GROUNDWATER LEVEL DIFFERENCE BETWEEN OCTOBER 2012 AND OCTOBER 2013 NORTH INDIAN BEND WASH AREA, SCOTTSDALE, ARIZONA
Page 1 of 3
OCTOBER 2012 DEPTH TO OCTOBER 2013 DEPTH TO CHANGE IN DEPTH TOMONITOR WELL ALLUVIUM GROUNDWATER LEVEL GROUNDWATER LEVEL GROUNDWATER LEVEL
IDENTIFIER UNIT (ft, bls) (ft, bls) (feet)
PG-9 U 111.34 Abandoned ---PG-10 U 96.50 58.31 38.19PG-36 U 102.66 Abandoned ---PG-29 U 88.45 91.75 -3.30PG-16 U 101.60 103.79 -2.19PG-28 U 92.10 95.18 -3.08PG-31 U 95.79 98.46 -2.67E-4 U 77.53 Abandoned ---PG-30 U 84.68 88.01 -3.33W-3 U 84.58 Abandoned ---PG-17 U 71.35 Abandoned ---D-1 U 72.35 Abandoned ---PG-12 U 84.63 Abandoned ---PG-11 U 92.23 95.45 -3.22E-3 U 83.79 Abandoned ---PG-15 U 79.37 Abandoned ---PG-33 U 73.85 Abandoned ---PG-34 U 78.73 Abandoned ---PG-13 U 82.62 Abandoned ---M-16 U 82.10 Abandoned ---M-9 U 69.70 Abandoned ---E-2 U 81.00 87.42 -6.42PG-32 U 79.15 Abandoned ---M-11 U 71.00 Abandoned ---E-6 U 88.00 93.02 -5.02PG-39 U 106.15 Abandoned ---PG-21 U 69.71 Abandoned ---PG-37 U 123.51 Abandoned ---PG-20 U 83.36 Abandoned ---M-15 U 73.20 Abandoned ---E-1 U 67.50 74.13 -6.63PG-8 U 92.15 98.28 -6.13M-5 U Obstruction in sounder pipe Abandoned ---E-7 U 62.48 68.39 -5.91PG-22 U 70.63 76.67 -6.04E-9 U 77.78 Abandoned ---PG-38 U 122.80 Abandoned ---ST-1 U 66.10 Abandoned ---PG-4 U 103.33 109.21 -5.88M-4 U 72.20 Abandoned ---PG-25 U 70.10 77.37 -7.27PG-5 U 83.64 90.68 -7.04E-5 U 60.63 67.35 -6.72M-2 U 68.92 74.44 -5.52M-3 U 61.90 Abandoned ---PG-23 U 97.89 104.74 -6.85PG-19 U 69.48 95.95 -26.47E-13 U 65.89 72.67 -6.78PG-24 U 82.08 88.81 -6.73B-J U 53.74 60.72 -6.98PG-26 U 61.68 Abandoned ---E-12 U 61.55 68.34 -6.79PG-6 U 85.18 93.38 -8.20PG-18 U 66.60 77.33 -10.73PG-3 U 71.92 79.01 -7.09
P:\366\2013 Annual Report\Table 3. WL Difference 2012 to 2013.xlsx\Table 3
TABLE 3. SUMMARY OF GROUNDWATER LEVEL DIFFERENCE BETWEEN OCTOBER 2012 AND OCTOBER 2013 NORTH INDIAN BEND WASH AREA, SCOTTSDALE, ARIZONA
Page 2 of 3
OCTOBER 2012 DEPTH TO OCTOBER 2013 DEPTH TO CHANGE IN DEPTH TOMONITOR WELL ALLUVIUM GROUNDWATER LEVEL GROUNDWATER LEVEL GROUNDWATER LEVEL
IDENTIFIER UNIT (ft, bls) (ft, bls) (feet)
B-3 U 51.53 Abandoned ---B-1 U 49.90 57.24 -7.34PG-27 U 51.58 Abandoned ---PG-7 U 65.66 73.82 -8.16PA-7 M 116.96 120.35 -3.39PA-3 M 112.30 118.01 -5.71S-2 M 142.68 145.49 -2.81PA-4 M 99.23 103.66 -4.43PA-14 M 121.30 130.15 -8.85S-1 M 137.60 139.72 -2.12D-2 M 109.30 112.47 -3.17PG-50 M 140.81 152.01 -11.20PG-51 M 151.58 154.51 -2.93PA-17 M 106.31 101.89 4.42W-1 M 101.50 107.02 -5.52E-10 M 138.61 142.53 -3.92W-2 M 144.15 147.07 -2.92M-12MA2 M 135.53 138.49 -2.96PA-10 M 137.75 140.95 -3.20PA-1 M 98.92 108.69 -9.77PA-12MA2 M 130.04 135.91 -5.87M-16 M 111.35 122.28 -10.93PA-21 M 106.87 121.19 -14.32PG-57 M 108.20 119.88 -11.68M-9 M 107.60 124.22 -16.62M-14 M 113.65 128.65 -15.00M-11 M 102.90 110.63 -7.73M-15 M 114.55 137.98 -23.43M-10MA2 M 119.70 148.08 -28.38M-6 M 113.30 134.44 -21.14PG-47 M 119.31 135.56 -16.25PG-48 M 117.69 136.69 -19.00E-1 M 107.40 127.89 -20.49PA-20 M 128.44 140.39 -11.95M-5 M 128.19 152.04 -23.85M-7 M 104.90 128.01 -23.11PG-4 M 133.16 143.97 -10.81M-1 M 100.71 129.28 -28.57M-4 M 108.60 135.64 -27.04PG-5 M 118.30 137.71 -19.41E-5 M 69.50 106.32 -36.82M-2 M 105.05 139.55 -34.50M-3 M 94.35 121.61 -27.26E-8 M 90.85 154.87 -64.02PG-6 M 100.70 113.98 -13.28PA-16 M 101.29 131.85 -30.56B-1 M 84.11 127.59 -43.48PG-7 M 92.64 117.99 -25.35PA-23 M 77.18 122.43 -45.25PG-43 L 319.27 322.49 -3.22PG-42 L 347.27 348.44 -1.17PG-40 L 328.75 329.86 -1.11PG-44 L 350.55 360.67 -10.12PG-1 L 293.22 296.62 -3.40PG-2 L 325.55 329.32 -3.77PA-6 L 289.59 292.23 -2.64PA-2 L 283.21 286.72 -3.51
P:\366\2013 Annual Report\Table 3. WL Difference 2012 to 2013.xlsx\Table 3
TABLE 3. SUMMARY OF GROUNDWATER LEVEL DIFFERENCE BETWEEN OCTOBER 2012 AND OCTOBER 2013 NORTH INDIAN BEND WASH AREA, SCOTTSDALE, ARIZONA
Page 3 of 3
OCTOBER 2012 DEPTH TO OCTOBER 2013 DEPTH TO CHANGE IN DEPTH TOMONITOR WELL ALLUVIUM GROUNDWATER LEVEL GROUNDWATER LEVEL GROUNDWATER LEVEL
IDENTIFIER UNIT (ft, bls) (ft, bls) (feet)
S-2 L 291.32 293.31 -1.99PA-5 L 262.93 267.97 -5.04PA-13 L 273.22 274.81 -1.59S-1 L 261.60 264.06 -2.46PA-18 L 220.55 226.52 -5.97PA-8LA2 L 182.40 189.91 -7.51PA-9 L 193.78 198.86 -5.08E-14 L 168.83 173.45 -4.62M-17MA/LA L 151.70 156.12 -4.42PA-11LA2 L 158.40 161.19 -2.79M-16 L 169.80 175.64 -5.84M-9 L 157.38 165.81 -8.43M-14 L 160.40 166.97 -6.57M-10LA2 L 142.35 154.69 -12.34E-1 L 142.95 153.95 -11.00PA-19 L 131.86 143.15 -11.29M-5 L 146.14 156.41 -10.27E-7 L 114.71 125.28 -10.57PG-39 L 145.42 150.87 -5.45PG-38MA/LA L 142.74 152.76 -10.02M-2 L 132.60 143.75 -11.15PG-23MA/LA L 120.20 132.48 -12.28PA-15 L 106.44 120.73 -14.29PA-22 L 92.00 105.79 -13.79
Notes:ft, bls = feet below land surface
U = Upper Alluvium Unit monitor wellM = Middle Alluvium Unit monitor well L = Lower Alluvium Unit monitor well--- = No Data Available
P:\366\2013 Annual Report\Table 3. WL Difference 2012 to 2013.xlsx\Table 3
TABLE 4. 2013 LABORATORY RESULTS FOR GROUNDWATER MONITORING WELLSNORTH INDIAN BEND WASH SUPERFUND SITE, SCOTTSDALE, ARIZONA(results presented in micrograms per liter, µg/L)
WELLTYPE
SAMPLELOCATION
FIELD SAMPLE IDENTIFIER
SAMPLE DATE
SAMPLETYPE LAB TCA DCE TCM PCE TCE
Monitoring B-J B-J 10/10/2013 Original TA <0.50 <0.50 0.74 <0.50 2.8
Monitoring B-1MA B-1MA 11/13/2013 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Monitoring D-2MA D-2MA 1/8/2013 Original SRP <0.5 0.7 2.2 9.2 1,400
Monitoring D-2MA D-2MA 4/15/2013 Original TA <0.50 0.52 2.4 10 1,500
Monitoring D-2MA D-2MA 7/19/2013 Original TA <50 <50 <50 <50 1,800
Monitoring D-2MA D-2MA 10/18/2013 Original TA <0.50 <0.50 2.7 8.6 1,900
Monitoring E-1MA E-1MA 1/10/2013 Original SRP <0.5 1.2 4.5 3.6 87
Monitoring E-1MA Dup D 1/10/2013 Duplicate SRP <0.5 1.3 4.7 3.7 94
Monitoring E-1MA E-1MA 4/12/2013 Original TA <0.50 <0.50 1.6 1.1 36
Monitoring E-1MA E-1MA 8/23/2013 Original TA <0.50 0.55 3.0 1.9 64
Monitoring E-1MA E-1MA 10/23/2013 Original TA <0.50 <0.50 1.5 0.78 33
Monitoring E-1MA F 10/23/2013 Duplicate TA <0.50 <0.50 1.4 0.89 32
Monitoring E-5MA E-5MA 1/9/2013 Original SRP <0.5 0.7 1.9 1.5 42
Monitoring E-5MA E-5MA 4/11/2013 Original TA <0.50 <0.50 1.7 0.98 42
Monitoring E-5MA C 4/11/2013 Duplicate TA <0.50 <0.50 1.7 0.97 43
Monitoring E-5MA E-5MA 7/18/2013 Original TA <0.50 <0.50 1.9 1.1 41
Monitoring E-5MA L 7/18/2013 Duplicate TA <0.50 <0.50 1.9 1.1 41
Monitoring E-5MA E-5MA 10/11/2013 Original TA <0.50 <0.50 2.2 1.0 49
Monitoring E-5UA E-5UA 10/11/2013 Original TA <0.50 <0.50 0.65 0.66 3.6
Monitoring E-7LA E-7LA 11/13/2013 Original TA <0.50 <0.50 1.5 5.0 17
Monitoring E-7UA E-7UA 10/14/2013 Original TA <0.50 <0.50 <0.50 <0.50 1.0
Monitoring E-8MA E-8MA 10/10/2013 Original TA <0.50 <0.50 0.85 <0.50 21
Monitoring E-8MA X 10/10/2013 Duplicate TA <0.50 <0.50 0.88 <0.50 24
Monitoring E-10MA E-10MA 1/9/2013 Original SRP <0.5 0.5 0.8 4.0 5.0
Monitoring E-10MA E-10MA 4/17/2013 Original TA <0.50 <0.50 0.74 3.7 4.9
Monitoring E-10MA G 4/17/2013 Duplicate TA <0.50 <0.50 0.79 4.2 5.8
Monitoring E-10MA E-10MA 7/23/2013 Original TA <0.50 <0.50 0.76 3.2 4.7
Monitoring E-10MA O 7/23/2013 Duplicate TA <0.50 <0.50 0.72 2.9 4.8
Monitoring E-10MA E-10MA 10/18/2013 Original TA <0.50 <0.50 0.75 3.3 5.1
Monitoring E-10MA D 10/18/2013 Duplicate TA <0.50 <0.50 0.76 3.3 5.2
Monitoring E-12UA E-12UA 10/10/2013 Original TA <0.50 <0.50 0.79 <0.50 7.0
Monitoring E-13UA E-13UA 10/10/2013 Original TA <0.50 <0.50 0.65 <0.50 3.4
Monitoring M-2MA M-2MA 10/23/2013 Original TA <0.50 <0.50 <0.50 <0.50 2.1
Monitoring M-2UA M-2UA 10/23/2013 Original TA <0.50 <0.50 0.63 <0.50 1.8
Monitoring M-4MA M-4MA 1/10/2013 Original SRP <0.5 0.5 1.2 1.0 23
Monitoring M-4MA M-4MA 4/11/2013 Original TA <0.50 <0.50 0.99 0.68 20
Monitoring M-4MA M-4MA 7/16/2013 Original TA <0.50 <0.50 1.3 0.67 24
Monitoring M-4MA M-4MA 10/24/2013 Original TA <0.50 <0.50 1.1 0.64 24
Monitoring M-4MA G 10/24/2013 Duplicate TA <0.50 <0.50 1.3 0.77 26
Monitoring M-5LA M-5LA 10/28/2013 Original TA <0.50 <0.50 3.6 <0.50 <0.50
Monitoring M-5MA M-5MA 1/10/2013 Original SRP <0.5 0.7 1.6 1.5 34
Monitoring M-5MA M-5MA 5/28/2013 Original TA <0.50 0.66 2.2 1.8 52
Monitoring M-5MA M-5MA 7/16/2013 Original TA <0.50 <0.50 1.6 1.3 37
Monitoring M-5MA M-5MA 10/28/2013 Original TA <0.50 <0.50 <0.50 <0.50 11
Monitoring M-5MA H 10/28/2013 Duplicate TA <0.50 <0.50 0.50 <0.50 11
Monitoring M-6MA M-6MA 1/10/2013 Original SRP <0.5 0.7 4.3 3.1 85
Monitoring M-6MA M-6MA 4/11/2013 Original TA <0.50 <0.50 1.7 1.1 37
Monitoring M-6MA M-6MA 7/16/2013 Original TA <0.50 0.99 5.2 2.9 100
Monitoring M-6MA M-6MA 10/24/2013 Original TA <0.50 0.93 3.9 2.7 85
Monitoring M-7MA M-7MA 10/24/2013 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Monitoring M-9MA M-9MA 11/1/2013 Original TA <0.50 <0.50 <0.50 <0.50 5.2
Monitoring M-10LA2 M-10LA2 10/9/2013 Original TA <0.50 <0.50 <0.50 <0.50 10
Monitoring M-10MA2 M-10MA2 1/15/2013 Original SRP <0.5 0.6 0.7 <0.5 19
Monitoring M-10MA2 M-10MA2 4/11/2013 Original TA <0.50 <0.50 0.65 <0.50 28
Page 1 of 5
TABLE 4. 2013 LABORATORY RESULTS FOR GROUNDWATER MONITORING WELLSNORTH INDIAN BEND WASH SUPERFUND SITE, SCOTTSDALE, ARIZONA(results presented in micrograms per liter, µg/L)
WELLTYPE
SAMPLELOCATION
FIELD SAMPLE IDENTIFIER
SAMPLE DATE
SAMPLETYPE LAB TCA DCE TCM PCE TCE
Monitoring M-10MA2 M-10MA2 7/16/2013 Original TA <0.50 0.53 0.72 <0.50 28
Monitoring M-10MA2 K 7/16/2013 Duplicate TA <0.50 0.51 0.77 <0.50 26
Monitoring M-10MA2 M-10MA2 10/9/2013 Original TA <0.50 0.59 0.99 0.68 42
Monitoring M-10MA2 M-10MA2 11/13/2013 Resample TA <0.50 0.57 0.84 0.50 34
Monitoring M-11MA M-11MA 10/23/2013 Original TA <0.50 <0.50 0.56 <0.50 <0.50
Monitoring M-12MA2 M-12MA2 10/22/2013 Original TA <0.50 <0.50 <0.50 <0.50 21
Monitoring M-14LA M-14LA 10/16/2013 Original TA <0.50 <0.50 1.8 8.4 21
Monitoring M-15MA M-15MA 1/9/2013 Original SRP <0.5 0.5 0.5 0.5 9.4
Monitoring M-15MA Duplicate C 1/9/2013 Duplicate SRP <0.5 0.5 0.5 0.5 9.6
Monitoring M-15MA M-15MA 4/12/2013 Original TA <0.50 <0.50 <0.50 <0.50 7.8
Monitoring M-15MA M-15MA 7/18/2013 Original TA <0.50 <0.50 <0.50 <0.50 8.7
Monitoring M-15MA M-15MA 10/14/2013 Original TA <0.50 <0.50 <0.50 <0.50 9.1
Monitoring M-16LA M-16LA 10/16/2013 Original TA <0.50 <0.50 2.5 2.2 53
Monitoring M-16LA M-16LA 11/14/2013 Resample TA <0.50 <0.50 (1) 2.1 2.1 48
Monitoring M-16MA M-16MA 10/16/2013 Original TA <0.50 0.59 <0.50 1.0 18
Monitoring M-17MA/LA M-17MA/LA 1/9/2013 Original SRP <0.5 <0.5 0.6 0.5 3.8
Monitoring M-17MA/LA M-17MA/LA 4/11/2013 Original TA <0.50 <0.50 <0.50 <0.50 3.5
Monitoring M-17MA/LA M-17MA/LA 7/19/2013 Original TA <1.0 1.0 <1.0 1.1J 7.6J
Monitoring M-17MA/LA M 7/19/2013 Duplicate TA <0.50 <0.50 <0.50 0.69 4.2
Monitoring M-17MA/LA M-17MA/LA 10/4/2013 Original TA <0.50 <0.50 <0.50 <0.50 3.8
Monitoring PA-2LA PA-2LA 10/17/2013 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Monitoring PA-5LA PA-5LA 10/17/2013 Original TA <0.50 2.0 5.1 7.6 140
Monitoring PA-6LA PA-6LA 4/12/2013 Original TA <0.50 3.2 4.6 17 180
Monitoring PA-6LA PA-6LA 10/17/2013 Original TA <0.50 3.4 5.2 20 240
Monitoring PA-6LA C 10/17/2013 Duplicate TA <0.50 3.9 5.3 19 240
Monitoring PA-6LA PA-6LA 11/14/2013 Resample TA <0.50 5.6J 5.7 23 270
Monitoring PA-6LA K 11/14/2013 Duplicate TA <0.50 7.0 5.8 24 310
Monitoring PA-8LA2 PA-8LA2 10/22/2013 Original TA <0.50 <0.50 0.84 7.5 9.5
Monitoring PA-9LA PA-9LA 10/8/2013 Original TA <0.50 <0.50 2.6 0.61 16
Monitoring PA-9LA V 10/8/2013 Duplicate TA <0.50 <0.50 2.5 0.65 16
Monitoring PA-10MA PA-10MA 1/10/2013 Original SRP <0.5 <0.5 0.5 0.6 18
Monitoring PA-10MA PA-10MA 4/17/2013 Original TA <0.50 <0.50 <0.50 0.69 24
Monitoring PA-10MA PA-10MA 7/19/2013 Original TA <0.50 <0.50 <0.50 0.63 22
Monitoring PA-10MA PA-10MA 10/8/2013 Original TA <0.50 <0.50 <0.50 0.57 25
Monitoring PA-11LA PA-11LA 10/4/2013 Original TA <0.50 <0.50 1.7 0.79 0.57
Monitoring PA-12MA PA-12MA 1/15/2013 Original SRP <0.5 <0.5 0.7 4.2 310
Monitoring PA-12MA Duplicate E 1/15/2013 Duplicate SRP <0.5 0.6 0.7 4.2 310
Monitoring PA-12MA PA-12MA 4/16/2013 Original TA <0.50 <0.50 0.67 4.0 300
Monitoring PA-12MA PA-12MA2 7/19/2013 Original TA <0.50R <0.50R <0.50R <0.50R 19R
Monitoring PA-12MA PA-12MA2 8/14/2013 Original TA <0.50 <0.50 0.55 3.7 290
Monitoring PA-12MA Q 8/14/2013 Duplicate TA <0.50 <0.50 0.60 3.9 300
Monitoring PA-12MA PA-12MA 12/11/2013 Original TA <0.50 <0.50 0.62 4.1 310
Monitoring PA-13LA PA-13LA 4/15/2013 Original TA <0.50 <0.50 0.88 1.7 150
Monitoring PA-13LA PA-13LA 10/8/2013 Original TA <0.50 <0.50 1.0 1.5 180
Monitoring PA-14MA PA-14MA 10/3/2013 Original TA <0.50 <0.50 1.2 <0.50 <0.50
Monitoring PA-14MA S 10/3/2013 Duplicate TA <0.50 <0.50 1.2 <0.50 <0.50
Monitoring PA-15LA PA-15LA 10/11/2013 Original TA <0.50 <0.50 3.6 <0.50 <0.50
Monitoring PA-16MA PA-16MA 10/11/2013 Original TA <0.50 <0.50 1.3 1.1 25
Monitoring PA-16MA Y 10/11/2013 Duplicate TA <0.50 <0.50 1.3 0.95 23
Monitoring PA-18LA PA-18LA 10/18/2013 Original TA <0.50 <0.50 4.2 0.52 1.5
Monitoring PA-19LA PA-19LA 10/11/2013 Original TA <0.50 0.93 2.0 3.1 61
Monitoring PA-20MA PA-20MA 10/11/2013 Original TA <0.50 0.66 1.4 3.8 81
Monitoring PA-21MA PA-21MA 10/16/2013 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Monitoring PG-1LA PG-1LA 1/8/2013 Original SRP <0.5 <0.5 <0.5 <0.5 1.0
Monitoring PG-1LA PG-1LA 4/12/2013 Original TA <0.50 <0.50 <0.50 <0.50 0.83
Page 2 of 5
TABLE 4. 2013 LABORATORY RESULTS FOR GROUNDWATER MONITORING WELLSNORTH INDIAN BEND WASH SUPERFUND SITE, SCOTTSDALE, ARIZONA(results presented in micrograms per liter, µg/L)
WELLTYPE
SAMPLELOCATION
FIELD SAMPLE IDENTIFIER
SAMPLE DATE
SAMPLETYPE LAB TCA DCE TCM PCE TCE
Monitoring PG-1LA PG-1LA 8/14/2013 Original TA <0.50 <0.50 <0.50 <0.50 0.80
Monitoring PG-1LA PG-1LA 10/17/2013 Original TA <0.50 <0.50 <0.50 <0.50 1.1
Monitoring PG-2LA PG-2LA 4/12/2013 Original TA <0.50 0.78 1.0 3.5 55
Monitoring PG-2LA D 4/12/2013 Duplicate TA <0.50 0.69 1.0 3.3 53
Monitoring PG-2LA PG-2LA 10/22/2013 Original TA <0.50 0.93 1.1 3.8J 62
Monitoring PG-2LA E 10/22/2013 Duplicate TA <0.50 0.93 1.3 3.0 59
Monitoring PG-3UA PG-3UA 10/9/2013 Original TA <0.50 <0.50 1.0 <0.50 3.3
Monitoring PG-4MA PG-4MA 10/9/2013 Original TA <0.50 <0.50 0.95 0.88 3.1
Monitoring PG-4UA PG-4UA 11/25/2013 Original TA <0.50 <0.50 0.73 3.3 0.94
Monitoring PG-5MA PG-5MA 10/11/2013 Original TA <0.50 <0.50 1.4 0.80 32
Monitoring PG-5UA PG-5UA 10/11/2013 Original TA <0.50 <0.50 0.93 0.57 3.4
Monitoring PG-6MA PG-6MA 10/9/2013 Original TA <0.50 1.6 4.1 5.4 170
Monitoring PG-6MA W 10/9/2013 Duplicate TA <0.50 1.4 3.7 4.8 160
Monitoring PG-6MA PG-6MA 11/13/2013 Resample TA <0.50 1.9 3.8 5.2 150
Monitoring PG-6MA J 11/13/2013 Duplicate TA <0.50 1.8 3.8 4.8 150
Monitoring PG-6UA PG-6UA 10/9/2013 Original TA <0.50 <0.50 1.0 <0.50 2.3
Monitoring PG-7MA PG-7MA 10/9/2013 Original TA <0.50 <0.50 1.0 <0.50 6.1
Monitoring PG-8UA PG-8UA 10/11/2013 Original TA <0.50 <0.50 0.90 <0.50 <0.50
Monitoring PG-10UA PG-10UA 10/3/2013 Original TA <0.50 <0.50 1.6 <0.50 1.3
Monitoring PG-11UA PG-11UA 10/30/2013 Original TA <0.50 <0.50 1.3 <0.50 <0.50
Monitoring PG-16UA PG-16UA 10/3/2013 Original TA <0.50 <0.50 <0.50 <0.50 1.5
Monitoring PG-18UA PG-18UA 10/10/2013 Original TA <0.50 <0.50 0.99 <0.50 3.5
Monitoring PG-19UA PG-19UA 12/2/2013 Original TA <0.50 <0.50 0.72 <0.50 1.9
Monitoring PG-22UA PG-22UA 10/14/2013 Original TA <0.50 0.59 0.65 2.7 9.1
Monitoring PG-22UA Z 10/14/2013 Duplicate TA <0.50 0.69 0.77 2.6 9.1
Monitoring PG-23MA/LA PG-23MA/LA 10/10/2013 Original TA <0.50 <0.50 1.8 1.7 20
Monitoring PG-23UA PG-23UA 10/10/2013 Original TA <0.50 <0.50 1.1 <0.50 2.4
Monitoring PG-24UA PG-24UA 10/10/2013 Original TA <0.50 <0.50 1.1 <0.50 7.8
Monitoring PG-25UA PG-25UA 10/14/2013 Original TA <0.50 <0.50 0.56 0.67 3.0
Monitoring PG-28UA PG-28UA 10/3/2013 Original TA <0.50 <0.50 1.6 <0.50 1.2
Monitoring PG-29UA PG-29UA 10/4/2013 Original TA <0.50 <0.50 0.75 <0.50 2.5
Monitoring PG-29UA T 10/4/2013 Duplicate TA <0.50 <0.50 0.75 <0.50 2.5
Monitoring PG-31UA PG-31UA 10/22/2013 Original TA <0.50 <0.50 2.2 <0.50 3.7
Monitoring PG-38MA/LA PG-38MA/LA 10/14/2013 Original TA <0.50 <0.50 1.0 4.3 1.4
Monitoring PG-39LA PG-39LA 10/16/2013 Original TA <0.50 0.64 1.4 3.6 6.4
Monitoring PG-40LA PG-40LA 1/17/2013 Original SRP <0.5 <0.5 0.6 <0.5 23
Monitoring PG-40LA Duplicate F 1/17/2013 Duplicate SRP <0.5 <0.5 0.6 <0.5 21
Monitoring PG-40LA PG-40LA 4/10/2013 Original TA <0.50 <0.50 <0.50 <0.50 21
Monitoring PG-40LA B 4/10/2013 Duplicate TA <0.50 <0.50 0.52 <0.50 20
Monitoring PG-40LA PG-40LA 7/22/2013 Original TA <0.50 0.55 0.62 0.64 20
Monitoring PG-40LA N 7/22/2013 Duplicate TA <0.50 <0.50 0.52 <0.50 19
Monitoring PG-40LA PG-40LA 10/15/2013 Original TA <0.50 <0.50 <0.50 <0.50 23
Monitoring PG-40LA A 10/15/2013 Duplicate TA <0.50 <0.50 <0.50 <0.50 23
Monitoring PG-42LA PG-42LA 1/17/2013 Original SRP <0.5 <0.5 0.8 <0.5 2.5
Monitoring PG-42LA PG-42LA 4/10/2013 Original TA <0.50 <0.50 <0.50 <0.50 0.93
Monitoring PG-42LA PG-42LA 7/22/2013 Original TA <0.50 <0.50 <0.50 <0.50 1.3
Monitoring PG-42LA PG-42LA 10/15/2013 Original TA <0.50 <0.50 <0.50 <0.50 1.4
Monitoring PG-43LA PG-43LA 1/17/2013 Original SRP <0.5 <0.5 <0.5 <0.5 <0.5
Monitoring PG-43LA PG-43LA 4/10/2013 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Monitoring PG-43LA PG-43LA 7/22/2013 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Monitoring PG-43LA PG-43LA 10/15/2013 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Monitoring PG-44LA PG-44LA 1/17/2013 Original SRP <0.5 <0.5 1.5 0.6 3.5
Monitoring PG-44LA PG-44LA 4/10/2013 Original TA <0.50 <0.50 2.2 <0.50 0.52
Monitoring PG-44LA PG-44LA 7/22/2013 Original TA <0.50 <0.50 2.3 <0.50 0.71
Page 3 of 5
TABLE 4. 2013 LABORATORY RESULTS FOR GROUNDWATER MONITORING WELLSNORTH INDIAN BEND WASH SUPERFUND SITE, SCOTTSDALE, ARIZONA(results presented in micrograms per liter, µg/L)
WELLTYPE
SAMPLELOCATION
FIELD SAMPLE IDENTIFIER
SAMPLE DATE
SAMPLETYPE LAB TCA DCE TCM PCE TCE
Monitoring PG-44LA PG-44LA 10/15/2013 Original TA <0.50 <0.50 2.7 <0.50 <0.50
Monitoring PG-48MA PG-48MA 1/10/2013 Original SRP <0.5 1.5 5.2 4.0 110
Monitoring PG-48MA PG-48MA 4/11/2013 Original TA <0.50 0.83 3.8 2.5 88
Monitoring PG-48MA PG-48MA 7/16/2013 Original TA <0.50 1.0 5.3 3.2 110
Monitoring PG-48MA PG-48MA 10/24/2013 Original TA <0.50 0.62 2.8 1.7 61
Monitoring PG-49MA PG-49MA 10/23/2013 Original TA <0.50 <0.50 0.69 <0.50 <0.50
Monitoring PG-50MA PG-50MA 10/18/2013 Original TA <0.50 <0.50 <0.50 <0.50 5.1
Monitoring PG-54MA PG-54MA 10/16/2013 Original TA <0.50 <0.50 1.4 0.84 32
Monitoring PG-54MA B 10/16/2013 Duplicate TA <0.50 <0.50 1.3 0.89 30
Monitoring PG-55MA PG-55MA 10/22/2013 Original TA <0.50 <0.50 <0.50 <0.50 3.2
Monitoring PG-56MA PG-56MA 10/18/2013 Original TA <0.50 <0.50 0.85 <0.50 4.0
Monitoring S-1LA S-1LA 10/4/2013 Original TA <0.50 <0.50 0.73 6.8 <0.50
Monitoring S-1MA S-1MA 10/4/2013 Original TA <0.50 <0.50 1.1 3.8 <0.50
Monitoring S-2LA S-2LA 1/8/2013 Original TA <0.50 <0.50 0.51 <0.50 21
Monitoring S-2LA S-2LA 4/15/2013 Original TA <0.50 <0.50 0.55 <0.50 24
Monitoring S-2LA E 4/15/2013 Duplicate TA <0.50 <0.50 0.58 <0.50 25
Monitoring S-2LA S-2LA 7/23/2013 Original TA <0.50 <0.50 0.68 <0.50 25
Monitoring S-2LA S-2LA 10/8/2013 Original TA <0.50 <0.50 0.67 <0.50 29
Monitoring S-2MA S-2MA 10/3/2013 Original TA <0.50 <0.50 1.3 <0.50 <0.50
Monitoring W-1MA W-1MA 1/8/2013 Original SRP <0.5 <0.5 0.9 1.6 300
Monitoring W-1MA Dup B 1/8/2013 Duplicate SRP <0.5 <0.5 0.9 1.7 280
Monitoring W-1MA W-1MA 4/17/2013 Original TA <0.50 <0.50 0.90 1.5 380(2)
Monitoring W-1MA W-1MA 10/18/2013 Original TA <0.50 <0.50 0.97 2.2 480
Monitoring W-2MA W-2MA 1/8/2013 Original SRP <0.5 1.0 <0.5 13 3,500
Monitoring W-2MA W-2MA 4/16/2013 Original TA <0.50 0.82 1.3 13 3,100
Monitoring W-2MA W-2MA 7/19/2013 Original TA <50 <50 <50 <50 3,700
Monitoring W-2MA W-2MA (3) 10/22/2013 Original TA <10 <10 <10 15 4,000
QC Trip Blank 1/8/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC Trip Blank 1/9/2013 TB SRP <0.5 <0.5 <0.5 <0.5 <0.5
QC Trip Blank 1/10/2013 TB SRP <0.5 <0.5 <0.5 <0.5 <0.5
QC Trip Blank 1/15/2013 TB SRP <0.5 <0.5 <0.5 <0.5 <0.5
QC Trip Blank 1/17/2013 TB SRP <0.5 <0.5 <0.5 <0.5 <0.5
QC FRB 4/10/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB 4/11/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB 4/12/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB 4/15/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB 4/16/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB 4/17/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB 5/28/2013 TB TA <0.50 <0.50(4) <0.50 <0.50 <0.50
QC FRB(Trip) 7/16/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 7/18/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 7/19/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 7/22/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) (2) 7/23/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 8/14/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 8/23/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 10/3/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 10/4/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 10/8/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 10/9/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 10/10/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 10/11/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 10/14/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
Page 4 of 5
TABLE 4. 2013 LABORATORY RESULTS FOR GROUNDWATER MONITORING WELLSNORTH INDIAN BEND WASH SUPERFUND SITE, SCOTTSDALE, ARIZONA(results presented in micrograms per liter, µg/L)
WELLTYPE
SAMPLELOCATION
FIELD SAMPLE IDENTIFIER
SAMPLE DATE
SAMPLETYPE LAB TCA DCE TCM PCE TCE
QC FRB(Trip) 10/15/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 10/16/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 10/17/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 10/18/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 10/22/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 10/23/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 10/24/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 10/28/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 10/30/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 11/1/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 11/13/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 11/14/2013 TB TA <0.50 <0.50 (1) <0.50 <0.50 <0.50
QC FRB(Trip) 11/25/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 12/2/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 12/11/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
EXPLANATION:
TCA = 1,1,1-Trichloroethane SRP = Salt River Project Environmental Laboratory
DCE = 1,1-Dichloroethene TA = TestAmerica, Inc.
TCM = Chloroform <0.50 = Analytical result is less than laboratory detection limit
PCE = Tetrachloroethene QC = Quality Control
TCE = Trichloroethene TB = Trip Blank
J =
R =
(1) L5 Flag: The associated blank spike recovery was above laboratory/method acceptance limits. This analyte was not detected in the sample.
(2) H1 Flag: Sample analysis was performed past the holding time. The result is estimated.
(3) D1 Flag: Sample required dilution due to matrix.(4)
The analyte was positively identified; the associated numerical value is the approximate concentration of the analyte in the sample. The relative percent difference (RPD) acceptance criteria of 20% for the field duplicate (as indicated in the Phase 1 Sampling & Analysis Plan) was exceeded.
R6 Flag: Laboratory Control Sample / Laboratory Control Sample Duplicate (LCS / LCSD) RPD exceeded laboratory acceptance limits for the analyte. However, the LCS recovery met acceptance criteria. Data are considered valid and acceptable
Sample was inadvertently collected at a different monitoring well. Data is rejected.
Page 5 of 5
TABLE 5. 2013 LABORATORY RESULTS FOR GROUNDWATER EXTRACTION WELLSNORTH INDIAN BEND WASH SUPERFUND SITE, SCOTTSDALE, ARIZONA(results presented in micrograms per liter, µg/L)
WELLTYPE
SAMPLELOCATION
FIELD SAMPLE IDENTIFIER
SAMPLE DATE
SAMPLETYPE LAB TCA DCE TCM PCE TCE
Extraction 7EX-3aMA 7EX-3aMA 1/7/2013 Original TA <0.50 <0.50(1) 0.68 2.8 720
Extraction 7EX-3aMA 7EX-3aMA 4/1/2013 Original TA <0.50 <0.50 0.80 1.8 320
Extraction 7EX-3aMA 7EX-3aMA 10/7/2013 Original TA <0.50 <0.50 0.79 2.9 440
Extraction 7EX-4MA 7EX-4MA 1/7/2013 Original TA <0.50 <0.50(1) 0.52 3.7 1,300
Extraction 7EX-4MA 7EX-4MA 4/2/2013 Original TA <0.50 <0.50 0.53 3.2 1,100
Extraction 7EX-4MA 7EX-4MA 7/1/2013 Original TA <0.50 <0.50 0.65 4.2 1,200
Extraction 7EX-4MA 7EX-4MA 10/7/2013 Original TA <0.50 <0.50 0.66 4.3 1,300
Extraction COS-31 COS-31 5/3/2013 Original TA <0.50(1,3,4) <0.50(1,2,4) 0.87 0.56 12
Extraction COS-31 COS-31 7/1/2013 Original TA <0.50 <0.50 0.79 <0.50 13
Extraction COS-71 COS-71 1/7/2013 Original TA <0.50 <0.50 0.92 1.1 85
Extraction COS-71 Duplicate A 1/7/2013 Duplicate TA <0.50 <0.50 0.87 1.1 85
Extraction COS-71 COS-71 2/4/2013 Original TA <0.50 <0.50 0.87 1.0 66
Extraction COS-71 COS-71 3/4/2013 Original TA <0.50 <0.50 1.0 1.2 75
Extraction COS-71 COS-71 4/1/2013 Original TA <0.50 <0.50 0.93 1.1 67
Extraction COS-71 COS-71 5/3/2013 Original TA <0.50(1,3,4) <0.50(1,2,4) 1.0 1.1 73
Extraction COS-71 H 5/3/2013 Duplicate TA <0.50 <0.50(3,4) 1.1 1.2 74
Extraction COS-71 COS-71 9/3/2013 Original TA <0.50 <0.50 1.0 0.99 82
Extraction COS-71 COS-71 11/4/2013 Original TA <0.50 <0.50 1.2 1.2 76
Extraction COS-71 COS-71 12/2/2013 Original TA <0.50 <0.50 1.1 1.1 100
Extraction COS-72 COS-72 4/1/2013 Original TA <0.50 <0.50 0.70 6.9 11
Extraction COS-72 COS-72 11/4/2013 Original TA <0.50 <0.50 0.58 <0.50 8.0
Extraction COS-72 COS-72 12/2/2013 Original TA <0.50 <0.50 0.68 2.3 10
Extraction COS-75A COS-75A 1/7/2013 Original TA <0.50 1.4 2.8 9.4 71
Extraction COS-75A COS-75A 2/4/2013 Original TA <0.50 1.1 2.6 8.2 64
Extraction COS-75A Duplicate A 2/4/2013 Duplicate TA <0.50 1.3 2.7 8.0 65
Extraction COS-75A COS-75A 3/4/2013 Original TA <0.50 1.4 2.8 8.6 74
Extraction COS-75A Duplicate A 3/4/2013 Duplicate TA <0.50 1.3 2.9 8.4 74
Extraction COS-75A COS-75A 5/3/2013 Original TA <0.50(1,3,4) 1.6 2.9 9.4 71
Extraction COS-75A COS-75A 7/1/2013 Original TA <0.50 1.8 3.6 12 89
Extraction COS-75A COS-75A 8/5/2013 Original TA <0.50R <0.50R 1.1R 0.79R 12R
Extraction COS-75A COS-75A 9/3/2013 Original TA <0.50 1.3 3.0 9.1 77
Extraction COS-75A COS-75A 10/7/2013 Original TA <0.50 1.4 3.4 9.6 81
Extraction COS-75A COS-75A 11/4/2013 Original TA <0.50 1.8 3.8 11 90
Extraction COS-75A COS-75A 12/2/2013 Original TA <0.50 1.9 3.4 10 86
Extraction MEX-1MA MEX-1-1A-02182013 2/18/2013 Original TA <0.50 2.4 2.4 4.4 67
Extraction MEX-1MA MEX-1-1A-03042013 3/4/2013 Original TA <0.50 1.9 1.9 3.3 56
Extraction MEX-1MA MEX-1MA 4/8/2013 Original TA <0.50 2.1 2.0 4.4 56
Extraction MEX-1MA MEX-1-1A-05062013 5/6/2013 Original TA <0.50 2.0 1.8 3.2 47
Extraction MEX-1MA MEX-1-1B-05062013 5/6/2013 Duplicate TA <0.50 1.8 1.7 3.2 49
Extraction MEX-1MA MEX-1-1A-06032013 6/3/2013 Original TA <0.50 1.7 1.9 3.5 52
Extraction MEX-1MA MEX-1-1A-07012013 7/1/2013 Original TA <0.50 2.0 2.0 3.7 54
Extraction MEX-1MA MEX-1MA 7/1/2013 Original TA <0.50 2.0 2.1 4.0 56
Extraction MEX-1MA MEX-1-1A-080513 8/5/2013 Original TA <0.50R <0.50R 0.71R 0.68R 12R
Extraction MEX-1MA MEX-1-1A-09022013 9/2/2013 Original TA <0.50 1.9 2.2 3.1 56
Extraction MEX-1MA MEX-1-1A-100613 10/6/2013 Original TA <0.50 1.4 1.9 2.9 50
Extraction MEX-1MA MEX-1MA 10/7/2013 Original TA <0.50 3.8 2.1 8.1 78
Extraction MEX-1MA MEX-1-1A-11042013 11/4/2013 Original TA <0.50 1.8 1.7 3.0 50
Extraction MEX-1MA MEX-1-1A-12022013 12/2/2013 Original TA <0.50 1.7 2.0 3.0 52
Extraction MEX-1MA MEX-1-1B-12022013 12/2/2013 Duplicate TA <0.50 1.5 2.1 3.3 56
Page 1 of 3
TABLE 5. 2013 LABORATORY RESULTS FOR GROUNDWATER EXTRACTION WELLSNORTH INDIAN BEND WASH SUPERFUND SITE, SCOTTSDALE, ARIZONA(results presented in micrograms per liter, µg/L)
WELLTYPE
SAMPLELOCATION
FIELD SAMPLE IDENTIFIER
SAMPLE DATE
SAMPLETYPE LAB TCA DCE TCM PCE TCE
Extraction PCX-1 PCX-1 3/4/2013 Original TA <0.50 1.1 1.7 5.0 77
Extraction PCX-1 PCX-1 4/1/2013 Original TA <0.50 1.2 1.4 4.7 66
Extraction PCX-1 PCX-1 5/3/2013 Original TA <0.50 1.1 1.6 4.8 69
Extraction PCX-1 PCX-1 6/3/2013 Original TA <0.50(3,4) 0.92 1.6 5.3 74
Extraction PCX-1 PCX-1 7/1/2013 Original TA <0.50 0.70 1.8 5.1 77
Extraction PCX-1 PCX-1 8/5/2013 Original TA <0.50R <0.50R 0.60R <0.50R 11R
Extraction PCX-1 PCX-1 9/3/2013 Original TA <0.50 0.90 1.7 4.5 71
Extraction PCX-1 PCX-1 10/7/2013 Original TA <0.50 1.0 1.7 4.8 77
Extraction PCX-1 PCX-1 11/4/2013 Original TA <0.50 1.1 1.8 5.4 77
Extraction PCX-1 I 11/4/2013 Duplicate TA <0.50 1.1 1.8 4.5 72
Extraction PCX-1 PCX-1 12/2/2013 Original TA <0.50 1.0J 1.7 4.8 74
Extraction PCX-1 L 12/2/2013 Duplicate TA <0.50 1.3 1.9 5.2 78
Extraction PV-14 PV-14 3/4/2013 Original TA <0.50 <0.50 <0.50 <0.50 1.1
Extraction PV-14 PV-14 4/1/2013 Original TA <0.50 <0.50 <0.50 <0.50 1.1
Extraction PV-14 PV-14 5/3/2013 Original TA <0.50 <0.50(2,4) <0.50 <0.50 1.0
Extraction PV-14 PV-14 6/3/2013 Original TA <0.50(3,4) <0.50(3,4) <0.50 <0.50 1.3
Extraction PV-14 PV-14 7/1/2013 Original TA <0.50 <0.50 <0.50 <0.50 1.7
Extraction PV-14 PV-14 8/5/2013 Original TA <0.50 <0.50 <0.50(3,4) <0.50 1.1
Extraction PV-14 PV-14 9/3/2013 Original TA <0.50 <0.50 <0.50 <0.50 1.1
Extraction PV-14 Well 14 9/6/2013 Original TA <0.50 <0.50 <0.50 <0.50 1.2
Extraction PV-14 Well 14 10/14/2013 Original TA <0.50 <0.50 <0.50 <0.50 1.7
Extraction PV-14 PV-14 11/4/2013 Original TA <0.50 <0.50 <0.50 <0.50 3.3
Extraction PV-14 Well 14 11/4/2013 Original TA <0.50 <0.50 <0.50 <0.50 3.3
Extraction PV-14 PV-14 12/2/2013 Original TA <0.50 <0.50 <0.50 <0.50 2.2
Extraction PV-15 PV-15 1/7/2013 Original TA <0.50 <0.50(1) <0.50 <0.50 5.4
Extraction PV-15 PV-15 2/4/2013 Original TA <0.50 <0.50 <0.50 <0.50 5.8
Extraction PV-15 PV-15 3/4/2013 Original TA <0.50 <0.50 <0.50 <0.50 5.7
Extraction PV-15 PV-15 4/1/2013 Original TA <0.50 <0.50 <0.50 <0.50 5.2
Extraction PV-15 A 4/1/2013 Duplicate TA <0.50 <0.50 <0.50 <0.50 5.1
Extraction PV-15 PV-15 5/3/2013 Original TA <0.50 <0.50(2,4) <0.50 <0.50 5.7
Extraction PV-15 PV-15 6/3/2013 Original TA <0.50(3,4) <0.50(3,4) <0.50 <0.50 6.2
Extraction PV-15 I 6/3/2013 Duplicate TA <0.50(3,4) <0.50(3,4) <0.50 <0.50 6.5
Extraction PV-15 PV-15 7/1/2013 Original TA <0.50 <0.50 <0.50 <0.50 6.7
Extraction PV-15 J 7/1/2013 Duplicate TA <0.50 <0.50 <0.50 <0.50 7.0
Extraction PV-15 PV-15 8/5/2013 Original TA <0.50 <0.50 <0.50(3,4) <0.50 5.6
Extraction PV-15 PV-15 9/3/2013 Original TA <0.50 <0.50 <0.50 <0.50 6.3
Extraction PV-15 R 9/3/2013 Duplicate TA <0.50 <0.50 <0.50 <0.50 6.4
Extraction PV-15 Well 15 9/6/2013 Original TA <0.50 <0.50 <0.50 <0.50 6.6
Extraction PV-15 Well 15 10/14/2013 Original TA <0.50 <0.50 <0.50 <0.50 7.0
Extraction PV-15 PV-15 11/4/2013 Original TA <0.50 <0.50 <0.50 <0.50 5.5
Extraction PV-15 Well 15 11/4/2013 Original TA <0.50 <0.50 <0.50 <0.50 5.7
Extraction PV-15 PV-15 12/16/2013 Original TA <0.50 <0.50 <0.50 <0.50 4.1
Extraction SRP23.6E6N GR-1-1A-04012013 4/1/2013 Original TA <0.50 1.2 5.0 2.6 110
Extraction SRP23.6E6N SRP23.6E6N 4/1/2013 Original TA <0.50 1.0 5.0 2.4 110
Extraction SRP23.6E6N SRP23.6E6N 7/1/2013 Original TA <0.50 <0.50 1.7 1.1 38
Extraction SRP23.6E6N GR-1-1A-08042013 8/4/2013 Original TA <0.50R 0.88R 4.3R 1.8R 96R
Extraction SRP23.6E6N GR-1-1B-08042013 8/4/2013 Duplicate TA <0.50 0.94 5.0 1.6 92
Extraction SRP23.6E6N GR-1-1A-100613 10/6/2013 Original TA <0.50 <0.50 1.5 0.83 30
Extraction SRP23.6E6N SRP23.6E6N 10/7/2013 Original TA <0.50 <0.50 2.0 1.2 49
Extraction SRP23.6E6N U 10/7/2013 Duplicate TA <0.50 <0.50 2.2 1.2 49
Extraction SRP23.6E6N GR-1-1A-103113 10/31/2013 Original TA <0.50 0.75 3.3 2.3 78
Page 2 of 3
TABLE 5. 2013 LABORATORY RESULTS FOR GROUNDWATER EXTRACTION WELLSNORTH INDIAN BEND WASH SUPERFUND SITE, SCOTTSDALE, ARIZONA(results presented in micrograms per liter, µg/L)
WELLTYPE
SAMPLELOCATION
FIELD SAMPLE IDENTIFIER
SAMPLE DATE
SAMPLETYPE LAB TCA DCE TCM PCE TCE
QC FRB 1/7/2013 TB TA <0.50 <0.50(1) <0.50 <0.50 <0.50
QC Trip Blank 2/4/2013 TB SRP <0.5 <0.5 <0.5 <0.5 <0.5
QC FB-1-1A-02182013 2/18/2013 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC TB 2/18/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FB-1-1A-03042013 3/4/2013 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC TB 3/4/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB 3/4/2013 TB SRP <0.5 <0.5 <0.5 <0.5 <0.5
QC FB-1-1A-04012013 4/1/2013 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC TB 4/1/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 4/1/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB 4/2/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB 4/8/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 5/3/2013 TB TA <0.50(1,3,4) <0.50(1,2,4) <0.50 <0.50 <0.50
QC FB-1-1A-05062013 5/6/2013 FB TA <0.50 <0.50(2,4) <0.50 <0.50 <0.50
QC TB 5/6/2013 TB TA <0.50 <0.50(2,4) <0.50 <0.50 <0.50
QC FRB(Trip) 6/3/2013 TB TA <0.50(3,4) <0.50(3,4) <0.50 <0.50 <0.50
QC FRB(Trip) 7/1/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC TB 7/1/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC TB 8/4/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 8/5/2013 TB TA <0.50 <0.50 <0.50(3,4) <0.50 <0.50
QC FRB(Trip) 9/3/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC TB 9/3/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC Trip Blank 9/6/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC TB 10/6/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FB-1-1A-100713 10/7/2013 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 10/7/2013 TB TA <0.50 <0.50 <0.50 <0.50 0.56
QC Trip Blank (5) 10/14/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC TB 10/31/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 11/4/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC TB 11/4/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC TB 11/4/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FB-1-1A-11042013 11/4/2013 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 12/2/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC TB 12/2/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FB-1-1A-12022013 12/2/2013 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC FRB(Trip) 12/16/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
EXPLANATION:TCA = 1,1,1-Trichloroethane SRP = Salt River Project Environmental Laboratory
DCE = 1,1-Dichloroethene TA = TestAmerica, Inc.
TCM = Chloroform <0.50 = Analytical result is less than laboratory detection limit
PCE = Tetrachloroethene QC = Quality Control
TCE = Trichloroethene TB = Trip Blank
J =
R =(1)
(2) L3 Flag: The associated blank spike recovery was above method acceptance limits.
(3) L5 Flag: The associated blank spike recovery was above laboratory/method acceptance limits. This analyte was not detected in the sample.
(4)
(5) S7 Flag: Surrogate recovery was below laboratory acceptance limits and method acceptance limits. Unable to confirm matrix effect.
The analyte was positively identified; the associated numerical value is the approximate concentration of the analyte in the sample. The relative percent difference (RPD) acceptance criteria of 20% for the field duplicate (as indicated in the Phase 1 Sampling & Analysis Plan) was exceeded.
R6 Flag: Laboratory Control Sample / Laboratory Control Sample Duplicate (LCS / LCSD) RPD exceeded laboratory acceptance limits for the analyte. However, the LCS recovery met acceptance criteria. Data are considered valid and acceptable.
V1 Flag: Continuing Calibration Verification (CCV) recovery was above method acceptance limits. This target analyte was not detected in the sample.
Data rejected due to laboratory QC issues.
Page 3 of 3
TABLE 6. SUMMARY OF 2013 MONTHLY GROUNDWATER PRODUCTION NORTH INDIAN BEND WASH AREA, SCOTTSDALE, ARIZONA
Page 1 of 3
Jan Feb March Apr May June July Aug Sept Oct Nov Dec Total
7EX-1UA 0 0 0 0 0 0 0 0 0 0 0 0 0 0.0
7EX-3aMA 8,059 4,719 6,017 7,964 7,661 5,152 5,381 7,320 7,704 7,604 7,561 7,794 82,936 254.5
7EX-4MA 5,175 3,103 3,918 5,186 4,856 3,209 3,184 4,487 4,640 4,495 4,531 4,664 51,448 157.9
7EX-5MA 0 0 0 0 0 0 0 0 0 0 0 0 0 0.0
PV-11 75,073 50,780 50,835 75,209 78,471 73,784 70,300 71,269 63,819 71,845 75,076 66,604 823,065 2,525.9
PV-12 0 0 0 0 0 0 0 0 0 0 0 0 0 0.0
PV-12Ba 21,149 16,194 8,600 19,094 80,472 112,288 88,641 88,244 79,397 107,773 104,420 43,346 769,618 2,361.9
PV-14 0 19,008 61,495 87,996 91,599 88,288 91,956 90,456 46,996 34,467 19,363 64,561 696,185 2,136.5
PV-15 91,376 73,306 91,991 87,168 89,270 84,762 86,186 85,068 81,525 40,666 8,668 11,118 831,104 2,550.6
PV-16 76 0 0 0 0 15,066 36,635 27,032 26,647 53,489 24,725 839 184,509 566.2
PV-17 6 0 0 0 0 5,010 553 1,013 34 25,578 3,199 120 35,513 109.0
AVI ** 4,276 4,276 4,276 4,276 4,276 4,276 4,276 4,276 4,276 4,276 4,276 4,276 51,308 157.5
AWC 7A 16,406 12,929 13,641 13,519 17,696 26,793 20,922 28,376 30,786 24,135 14,883 9,035 229,121 703.1
AWC 8 6,470 13,260 22,941 29,209 22,605 7,986 22,933 19,125 8,108 654 0 0 153,290 470.4
AWC 8A 341 3,611 19,746 28,133 24,667 20,060 908 10,377 0 0 5,229 0 113,073 347.0
AWC 9A 33,910 522 16,407 2,957 31,941 36,074 39,924 27,269 37,462 39,785 23,662 18,602 308,515 946.8
AWC 12A 12,925 20,011 33,051 35,515 22,194 27,374 41,219 43,152 43,385 31,454 12,822 14,410 337,512 1,035.8
COS 3 N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. 0 0.0
COS 4 N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. 0 0.0
COS 14 N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. 0 0.0
COS 25 * 59 40 287 1,532 1,562 2,223 1,804 1,892 1,398 766 153 51 11,768 36.1
COS 70 N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. 0 0.0
COS 71 47,953 46,637 47,335 39,896 27,869 8,315 4,489 35,226 27,872 34,611 24,542 25,663 370,408 1,136.7
COS 72 0 0 60,018 36,338 0 3,493 0 0 0 31,507 17,289 20,371 169,017 518.7
COS 73 N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. 0 0.0
COS 74 931 70 4,968 12,995 33,947 65,010 11,629 11,610 2,726 9,819 0 2,166 155,871 478.4
COS 75A 107,117 96,593 104,608 100,266 66,117 42,515 103,368 102,641 93,051 102,239 84,555 105,233 1,108,302 3,401.3
COS 76 N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. 0 0.0
COT 6 0 0 837 21,933 7,553 98,502 125,120 68,921 57,096 126,391 0 0 506,354 1,553.94
IBGC NA NA NA NA NA NA NA NA NA NA NA NA 0 0.0
LAIRD 2 0 32 32 45 52 144 51 102 17 70 14 0 558 1.7
MDWC 1,255 0 2,086 4,199 4,512 4,482 4,887 4,412 3,496 3,666 2,227 2,205 37,426 114.9
MEX-1MA 0 18,210 12,320 32,210 38,180 37,540 31,310 29,370 24,580 31,230 27,650 36,140 318,740 978.2
QRIA 0 0 0 1,181 1,810 1,870 1,564 1,987 1,850 1,384 81 0 11,727 36.0
SRIR SCC 2,304 2,909 3,365 7,045 8,998 10,275 1,842 2,679 5,312 5,927 3,704 2,402 56,762 174.2
SRIR 4 N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. 0 0.0
SRIR 10 N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. 0 0.0
ProductionWell ID
Gallons (x1000) Total In Acre-Feet
P:\366\2013 Annual Report\Tables\Table 6. Monthly Well Production 2013.xlsx
TABLE 6. SUMMARY OF 2013 MONTHLY GROUNDWATER PRODUCTION NORTH INDIAN BEND WASH AREA, SCOTTSDALE, ARIZONA
Page 2 of 3
Jan Feb March Apr May June July Aug Sept Oct Nov Dec Total
ProductionWell ID
Gallons (x1000) Total In Acre-Feet
SRP21.5E,8N
0 16,328 22,207 0 0 0 10,343 21,431 22,060 23,748 0 0 116,117 356.4
SRP22.1E,8.5N
0 0 0 0 0 0 0 0 0 0 0 0 0 0.0
SRP22.3E,7N
0 0 0 0 0 0 0 0 0 0 0 0 0 0.0
SRP 22.4E,9N
N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. 0 0.0
SRP22.5E,5.5N
0 0 0 0 0 0 0 0 16,560 47,542 0 0 64,101 196.7
SRP22.5E,6N
N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. 0 0.0
SRP 22.5E,9.3N(PCX 1)
5,116 76,681 98,533 94,362 96,318 90,757 105,644 83,547 83,879 91,902 80,975 93,188 1,000,902 3,071.7
SRP22.6E,10N
0 0 0 0 0 0 0 0 28,186 40,112 156 0 68,455 210.1
SRP
22.9E,10.8Nb 0 24,722 33,885 0 0 785 12,259 31,907 33,028 36,912 0 0 173,499 532.5
SRP 23E,10.8N(COS5W)
AB AB AB AB AB AB AB AB AB AB AB AB 0 0.0
SRP 23.3E,7.3N (COS 31)
2,999 0 1,210 61,589 60,888 32,611 81,523 16,276 0 0 312 0 257,409 790.0
SRP 23.3E,7.5N(COS 6)
0 0 0 0 0 0 0 0 0 0 0 0 0 0.0
SRP 23.4E,10.6N(COS5E)
AB AB AB AB AB AB AB AB AB AB AB AB 0 0.0
SRP23.5E,5.3N
0 0 0 0 0 0 0 0 0 0 0 0 0 0.0
SRP23.5E,8.8N
0 0 0 0 0 0 0 0 531 0 0 0 531 1.6
SRP23.5E,9.5N
0 0 0 0 0 0 0 0 0 15,022 33 0 15,054 46.2
SRP
23.5E,10.6Nc 0 19,453 26,176 0 0 29,496 38,467 26,775 26,107 24,713 29 0 191,216 586.8
SRP 23.6E,6N(Granite Reef)
0 0 28,310 6,630 0 0 5,890 6,340 11,820 10,070 8,350 0 77,410 237.6
SRP24E,10.5N
8,961 37,144 38,473 0 26 51,615 64,522 44,078 38,076 40,363 0 0 323,257 992.0
Total Monthly Discharge
(Gallons x 1,000)451,937 560,540 817,566 816,446 823,538 989,756 1,117,728 996,659 912,424 1,124,214 558,485 532,788 9,702,082
Total Monthly Discharge(Acre-Feet)
1,387 1,720 2,509 2,506 2,527 3,037 3,430 3,059 2,800 3,450 1,714 1,635 29,775 29,775
ABBREVIATIONS: 7EX = Area 7 Extraction Wells IBGC = Indian Bend (Rio Salado) Golf Course PV = Paradise Valley
AB = Well Abandoned LAIRD = Tempe School District No. 3 QRIA = Quail Run Irrigation Association AVI = Arcadia Vista Improvement MDWC = McDowell Water Company SRIR = Salt River Indian Reservation
AWC = Arcadia Water Company MEX = Motorola Extraction Well SRP = Salt River Project COS = City of Scottsdale NA = Not Available SCC = Scottsdale Community College
COT = City of Tempe N.I.S. = Not in Service
P:\366\2013 Annual Report\Tables\Table 6. Monthly Well Production 2013.xlsx
TABLE 6. SUMMARY OF 2013 MONTHLY GROUNDWATER PRODUCTION NORTH INDIAN BEND WASH AREA, SCOTTSDALE, ARIZONA
Page 3 of 3
Jan Feb March Apr May June July Aug Sept Oct Nov Dec Total
ProductionWell ID
Gallons (x1000) Total In Acre-Feet
NOTES:
* All water from Well 25 goes directly to McKellips Park irrigation and does not go to City of Scottsdale's water delivery system.
** Monthly values are based on an average of the annual total.a Replacement well for PV-12b Replacement well for SRP 23E,10.8Nc Replacement well for SRP 23.4E,10.6N
P:\366\2013 Annual Report\Tables\Table 6. Monthly Well Production 2013.xlsx
TABLE 7. SUMMARY OF ANNUAL GROUNDWATER PRODUCTION FROM 1991 THROUGH 2013 NORTH INDIAN BEND WASH AREA, SCOTTSDALE, ARIZONA
Page 1 of 2
1991 1992 1993 1994 1995 1996 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
7EX-1UA (1) --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- 13,514 13,654 14,585 12,966 12,627 0
7EX-3aMA (2) --- --- --- --- --- --- --- --- 13,170 87,375 76,401 64,048 77,690 83,654 72,475 73,094 74,020 64,062 70,290 73,227 68,454 89,646 82,936
7EX-4MA (2) --- --- --- --- --- --- --- --- 12,498 57,645 50,958 29,736 35,822 27,685 19,076 22,205 12,790 12,225 19,259 24,851 30,447 46,901 51,448
7EX-5MA (3) --- --- --- --- --- --- --- --- --- --- --- 42,094 96,280 85,914 102,191 95,534 103,234 78,932 88,997 72,160 69,657 19,315 0
PV-11 141,681 10,008 6,048 49,440 147,437 191,702 314,834 234,419 477,245 308,005 541,897 479,842 272,363 317,251 234,580 388,303 237,616 525,273 353,453 108,631 584,592 769,961 823,065
PV-12 78,760 161,849 160,265 197,764 442,311 766,800 302,222 224,958 317,991 242,826 292,758 269,215 255,925 181,905 190,159 235,528 177,350 415,980 478,840 182,527 416,242 72,486 0
PV-12Ba --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- 464,884 769,618
PV-14 697,184 578,435 747,760 670,253 556,129 387,737 203,056 584,633 575,456 512,210 487,780 593,518 632,011 677,341 771,890 387,497 632,798 232,191 149,512 451,695 854,265 930,498 696,185
PV-15 607,810 653,910 616,805 404,378 204,347 289,088 629,291 950,086 1,066,526 996,539 811,431 913,461 1,017,488 1,082,598 1,059,244 1,066,791 281,022 418,495 890,424 997,698 1,053,100 1,022,323 831,104
PV-16 1,170,129 1,019,287 1,131,036 1,048,376 981,234 1,067,411 1,051,729 583,415 423,634 541,894 699,049 475,143 414,571 319,872 341,430 246,221 567,698 831,067 704,898 842,941 314,954 253,545 184,509
PV-17 --- --- 7,080 715,206 711,787 711,787 906,660 568,588 358,059 54,352 105,121 57,730 128,252 102,762 38,113 173,522 451,742 1,015,459 1,297,930 1,005,540 221,181 10,293 35,513
AVI 78,763 79,074 89,128 95,840 91,608 88,372 93,030 79,825 84,295 75,740 79,388 76,049 70,533 78,501 68,605 62,650 54,663 67,011 57,627 60,168 60,117 54,030 51,308
AWC 7A 77,412 338,402 401,431 424,251 374,819 340,712 190,891 223,939 298,585 305,173 276,139 220,294 229,397 170,813 176,534 45,049 40,934 51,903 63,065 39,431 155,622 263,542 229,121
AWC 8 363,078 418,945 410,874 417,285 233,147 341,332 270,555 370,570 319,651 292,498 138,800 279,501 212,209 321,431 293,885 254,674 365,994 353,379 326,794 313,928 311,522 317,644 153,290
AWC 8A 0 0 0 215,398 394,624 265,618 271,981 266,446 271,888 184,594 136,050 226,063 257,184 245,347 156,650 195,585 3,353 112,147 117,745 196,227 34,277 55,067 113,073
AWC 9A 434,580 128,063 97,615 136,891 210,374 226,053 236,429 180,337 166,739 214,811 323,119 213,268 168,569 159,197 133,705 278,127 403,515 221,656 259,969 304,614 280,265 284,404 308,515
AWC 12A 242,769 182,413 171,403 174,068 329,099 241,366 331,889 272,153 232,164 309,621 329,926 295,895 321,098 312,606 370,420 406,087 405,590 426,091 349,362 366,436 391,746 229,546 337,512
COS 2 250,311 366,789 246,573 32,587 0 0 0 0 0 0 0 0 0 0 0 0 0 AB AB AB AB AB AB
COS 3 226,940 237,611 371,887 410,270 406,218 322,974 386,618 363,730 260,750 91,100 156,906 142,948 129,909 95,897 162,641 2,062 0 N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S.
COS 4 42,215 39,244 47,984 95,807 56,487 28,646 84,058 146,211 159,421 328,716 411,993 310,812 347,167 308,158 445,980 17,765 0 N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S.
COS 14 116,505 71,871 214,611 317,726 343,300 265,520 238,930 229,608 306,935 396,650 91,174 0 0 0 0 0 0 N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S.
COS 25 260,701 199,541 48,721 484,574 551,724 242,256 25,618 8,730 0 0 6,482 15,627 14,628 15,460 9,442 25,372 15,728 14,472 12,850 10,148 14,398 14,801 11,768
COS 69 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 AB AB AB AB AB AB
COS 70 133,678 2,553 43,066 390,067 110,774 55,201 93,123 2,709 0 0 0 0 0 0 0 0 0 N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S.
COS 71 0 0 6,480 502,719 234,943 1,126,972 958,101 946,903 631,967 787,926 1,013,550 432,044 764,771 638,982 387,740 826,102 492,646 697,198 725,001 557,523 371,970 475,775 370,408
COS 72 0 0 4,991 394,796 299,685 699,937 662,468 779,085 953,964 763,436 556,347 821,780 560,773 1,028,060 1,016,259 927,729 460,529 327,703 1,087,912 820,643 1,022,055 82,907 169,017
COS 73 3,271 649,298 1,007,101 3,252 795 9,743 3,157 527 0 0 0 0 0 0 0 0 0 N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S.
COS 74 42,763 38,042 635,564 733,867 825,076 460,914 396,669 790,408 918,226 1,092,783 1,165,908 1,003,371 955,818 1,098,504 1,172,087 424,447 325,721 318,930 426,465 469,534 139,478 382,838 155,871
COS 75A 0 0 0 0 452,657 796,408 892,870 951,517 830,739 896,406 979,506 836,006 933,512 926,306 936,472 929,487 559,788 821,026 878,726 841,481 848,597 917,870 1,108,302
COS 76 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S.
COS 77 0 3,088 1,103 0 0 0 0 0 0 0 0 0 0 0 0 0 0 AB AB AB AB AB AB
COS 78 999,204 328 1,029 650 0 0 3,099 0 0 0 0 0 0 0 0 0 0 AB AB AB AB AB AB
COT 6 150 1,668 2,777 10,122 3,441 160,308 4,197 0 0 446,480 734,304 221,080 26,831 0 22,571 390 0 153 1,666 389,936 355,018 9 506,354
IBGC 69,987 59,242 65,845 66,839 61,266 79,697 75,740 68,887 344 28,365 64,996 69,982 62,855 65,938 59,087 63,778 63,778 69,938 59,199 60,546 56,053 37,910 NA
LAIRD 2 8,178 1,453 1,827 964 1,655 1,655 4,650 1,573 8,432 9,857 0 0 0 0 0 3,853 3,853 322 530 357 285 365 558
MDWC 27,289 27,835 53,587 62,535 58,707 66,855 62,060 59,829 67,278 72,475 59,485 53,208 51,864 45,985 1,352 50,081 50,046 54,355 46,873 48,614 42,379 43,956 37,426
MEX-1MA (4) --- --- --- --- --- --- --- --- 34,348 256,586 361,409 227,273 119,380 315,708 309,919 311,978 332,752 405,260 394,010 407,090 398,980 273,270 318,740
QRIA 17,503 16,001 13,437 12,768 13,407 14,166 17,274 16,544 19,832 8,863 16,435 15,212 14,628 13,541 12,883 15,665 14,333 14,718 12,962 10,837 12,140 10,965 11,727
SRIR SCC 86,231 86,231 78,736 91,777 79,599 84,063 77,791 36,374 69,629 78,217 76,349 76,153 65,411 68,046 76,319 82,780 61,274 68,592 74,861 42,721 67,924 74,567 56,762
SRIR 4 60,580 7,771 0 31,631 3 0 248 38 0 0 0 0 0 0 0 0 0 N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S.
SRIR 10 47,583 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. N.I.S.
ProductionWell ID
Gallons (x1000)
P:\366\2013 Annual Report\Table 7. Annual Well Production 2013.xlsx
TABLE 7. SUMMARY OF ANNUAL GROUNDWATER PRODUCTION FROM 1991 THROUGH 2013 NORTH INDIAN BEND WASH AREA, SCOTTSDALE, ARIZONA
Page 2 of 2
1991 1992 1993 1994 1995 1996 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
ProductionWell ID
Gallons (x1000)
SRP21.5E,8N
74,479 2,829 5,090 59,887 17,536 19,600 0 1,302 213,170 454,442 247,362 160,470 166,324 254,063 28,797 0 0 0 3,397 5,321 13,803 114,214 116,117
SRP22.1E,8.5N
147,778 103,488 14,221 78,782 3,189 21,219 25 1,051 8 488,285 214,764 3,126 0 7,299 0 0 0 0 0 0 0 0 0
SRP22.3E,7N
0 0 0 0 756 22 0 0 0 0 0 0 0 0 0 0 0 N.I.S. 0 0 0 0 0
SRP 22.4E,9N
0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 N.I.S. N.I.S. N.I.S. N.I.S. N.I.S. 0
SRP22.5E,5.5N
0 0 0 0 0 0 0 0 0 0 123,673 264,377 0 0 0 0 0 0 0 0 0 0 64,101
SRP22.5E,6N
0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 N.I.S. 0 N.I.S. N.I.S. N.I.S. 0
SRP 22.5E,9.3N(PCX 1)
--- --- --- --- --- --- 744,308 1,169,490 928,957 1,094,148 709,461 1,080,881 1,032,519 1,002,262 1,003,406 1,109,259 983,481 856,322 1,012,745 1,008,500 891,933 971,762 1,000,902
SRP22.6E,10N
195,626 9,773 4,636 184,709 22,836 99,731 0 85 261,217 613,096 583,486 699,074 935,270 828,047 97,937 103,237 289,257 79,268 62,767 30,503 66,444 290,043 68,455
SRP
22.9E,10.8Nb --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- 128,034 173,499
SRP 23E,10.8N(COS5W)
137,618 60,933 6,744 33,979 115,096 7,607 15,747 5,701 154,864 350,263 337,880 148,376 447,267 174,920 14,322 21,004 120,014 N.I.S. AB AB AB AB AB
SRP 23.3E,7.3N (COS 31)
0 1,305 21,834 1,007,196 15,974 1,222,373 973,894 493,236 916,864 748,167 983,356 1,091,407 1,019,344 516,934 826,859 560,651 309,239 655,172 5,133 118,375 454,664 713,491 257,409
SRP 23.3E,7.5N(COS 6)
156,795 24,127 -3 35,527 47,921 192,207 168,263 246,769 101,318 62,194 102,249 80,341 138,380 88,935 1,638 1,769 175,013 0 0 0 0 0 0
SRP 23.4E,10.6N(COS5E)
507,724 565,069 578,233 658,438 663,544 757,582 723,706 779,598 832,331 566,682 392,775 278,701 470,274 576,706 30,001 0 0 N.I.S. AB AB AB AB AB
SRP23.5E,5.3N
122,870 3,077 4,077 3,271 4,920 2,856 0 34,473 111,366 144,215 126,690 226,058 128,631 255,259 3,348 0 78,673 0 2,941 0 0 0 0
SRP23.5E,8.8N
66,487 1,775 557 2,556 7,176 52 49 685 1,499 132,274 70,905 21,050 213,020 241,944 1,505 2,922 134,579 0 1,551 0 965 0 531
SRP23.5E,9.5N
0 0 0 0 0 0 0 85 502 117,592 131 99,548 30,042 256,542 2,051 1,988 163,479 0 2,021 0 1,303 33 15,054
SRP
23.5E,10.6Nc --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- 83,907 191,216
SRP 23.6E,6N(Granite Reef)
0 0 0 0 0 0 0 0 104,439 287,660 174,199 319,110 180,870 42,938 58,781 173,699 44,516 99,160 79,599 70,470 79,880 70,110 77,410
SRP24E,10.5N
113,065 3,151 578,233 113,496 16,493 122,709 2,124 2,397 381,364 470,577 408,894 616,127 528,528 428,180 31,260 45,701 188,758 11,621 9,319 0 411 204,488 323,257
Total Discharge (Gallons x1000)
7,807,696 6,154,481 7,898,386 10,369,940 9,092,091 11,779,250 11,417,355 11,676,917 12,887,663 14,970,743 14,519,488 13,549,998 13,527,407 13,461,492 10,741,611 9,632,587 8,679,775 9,333,593 10,142,344 9,947,259 9,698,087 9,788,023 9,702,082
Total Discharge (Acre-Feet)
23,961 18,887 24,239 31,824 27,903 36,149 35,039 35,835 39,551 45,943 44,559 41,583 41,514 41,312 32,965 29,561 26,637 28,644 31,126 30,527 29,762 30,038 29,775
ABBREVIATIONS: NOTES: 7EX = Area 7 Extraction Wells MEX = Motorola Extraction Well (1) Extraction well 7EX-1UA went into service in 2008.
AB = Well Abandoned NA = Not available (2) Extraction wells 7EX-3MA and 7EX-4MA went into service in September 1999.
AVI = Arcadia Vista Improvement N.I.S. = Not in Service (3) Extraction well 7EX-5MA went into service in February 2002.
AWC = Arcadia Water Company PV = Paradise Valley (4) Well MEX-1MA went into service in October 1999.
COS = City of Scottsdale QRIA = Quail Run Irrigation Association (5) Well 22.5E,9.3N (PCX-1) went into service in April 1997.
COT = City of Tempe SRIR = Salt River Indian Reservation a Replacement well for PV-12
IBGC = Indian Bend (Rio Salado) Golf Course SRP = Salt River Project b Replacement well for SRP 23E,10.8N
LAIRD = Tempe School District No. 3 --- = No Data c Replacement well for SRP 23.4E,10.6NMDWC = McDowell Water Company
P:\366\2013 Annual Report\Table 7. Annual Well Production 2013.xlsx
TABLE 8. SUMMARY OF 2013 EXTRACTION WELL PUMPAGE AND ESTIMATED TCE MASS REMOVED NORTH INDIAN BEND WASH AREA, SCOTTSDALE, ARIZONA
Jan-13 Feb-13 Mar-13 Apr-13 May-13 Jun-13 Jul-13 Aug-13 Sep-13 Oct-13 Nov-13 Dec-13 TOTALS
ANNUAL PUMPAGE
(in acre-feet)
ANNUAL PUMPAGE(in gpm)
pumpage 2,999 0 1,210 61,589 60,888 32,611 81,523 16,276 0 0 312 0 257,408 790 490
[TCE] 12 12 12 12 12.5 13 13 13 12 -- --
est TCE mass 0.3 0 0.1 6.2 6.1 3.4 8.8 1.8 0 0 0.03 0 27 -- --
pumpage 47,953 46,637 47,335 39,896 27,869 8,315 4,489 35,226 27,872 34,611 24,542 25,663 370,408 1,137 705
[TCE] 85 66 75 67 73.5 73.5 77.8 82 82 79 76 100 78 -- --
est TCE mass 34 26 30 22 17 5.1 2.9 24 19 23 16 21 240 -- --
pumpage 0 0 60,018 36,338 0 3,493 0 0 0 31,507 17,289 20,371 169,016 519 322
[TCE] 11 11 11 8.0 8.0 10 9.8 -- --
est TCE mass 0 0 5.5 3.3 0 0.3 0 0 0 2.1 1.2 1.7 14 -- --
pumpage 107,117 96,593 104,608 100,266 66,117 42,515 103,368 102,641 93,051 102,239 84,555 105,233 1,108,303 3,401 2,109
[TCE] 71 64 74 73 71 80 89 83 77 81 90 86 78 -- --est TCE mass 63 52 65 61 39 28 77 71 60 69 64 76 724 -- --
pumpage 158,069 143,230 213,171 238,089 154,874 86,934 189,380 154,143 120,923 168,357 126,698 151,267 1,905,135 5,847 3,625 est TCE mass 98 77 100 92 62 37 89 97 79 94 80 99 1,004 -- --
TOTAL
COS-31
COS-71
COS-72
COS-75A
CG
TF
,
pumpage 5,116 76,681 98,533 94,362 96,318 90,757 97,968 16,598 0 0 0 0 576,333 1,769 1,097
[TCE] 74 77 77 66 69 74 77 74 74 -- --
est TCE mass 3.2 49 63 52 55 56 63 10 0 0 0 0 352.42 -- --
pumpage 0 19,008 61,495 87,996 91,599 88,288 91,956 90,456 46,996 34,467 19,363 64,561 696,185 2,137 1,325
[TCE] 1.1 1.1 1.1 1.0 1.3 1.7 1.1 1.15 1.7 3.3 2.2 1.5 -- --
est TCE mass 0 0.2 0.6 0.8 0.8 1.0 1.3 0.8 0.5 0.5 0.5 1.2 8.1 -- --
pumpage 91,376 73,306 91,991 87,168 89,270 84,762 86,186 85,068 81,525 40,666 8,668 11,118 831,104 2,551 1,581
[TCE] 5.4 5.8 5.7 5.15 5.7 6.35 6.85 5.6 6.43 7.0 5.6 4.1 5.8 -- --
est TCE mass 4.1 3.5 4.4 3.7 4.2 4.5 4.9 4.0 4.4 2.4 0.4 0.4 41.0 -- --
pumpage 96,492 168,995 252,019 269,526 277,187 263,807 276,110 192,122 128,521 75,133 28,031 75,679 2,103,622 6,456 4,002
est TCE mass 7.3 53 68 57 60 61 69 15 4.8 2.9 0.9 1.6 401 -- --
pumpage 0 0 0 0 0 0 7,676 66,949 83,879 91,902 80,975 93,188 424,569 1,303 808
[TCE] 77 74 71 77 74.5 76 75 -- --
est TCE mass 0 0 0 0 0 0 4.9 41 50 59 50 59 264 -- --
pumpage 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
[TCE] -- --
est TCE mass 0 0 0 0 0 0 0 0 0 0 0 0 0 -- --
NG
TF
PCX-1
PV-14
TOTAL
MR
TF
PV-15
PCX-1
7EX-1UAest TCE mass 0 0 0 0 0 0 0 0 0 0 0 0 0
pumpage 8,059 4,719 6,017 7,964 7,661 5,152 5,381 7,320 7,704 7,604 7,561 7,794 82,935 255 158
[TCE] 720 720 720 320 320 320 380 380 380 440 440 440 465 -- --
est TCE mass 48 28 36 21 20 14 17 23 24 28 28 29 317 -- --
pumpage 5,175 3,103 3,918 5,186 4,856 3,209 3,184 4,487 4,640 4,495 4,531 4,664 51,448 158 98
[TCE] 1,300 1,300 1,300 1,100 1,100 1,100 1,200 1,200 1,200 1,300 1,300 1,300 1,225 -- --
est TCE mass 56 34 43 48 45 29 32 45 46 49 49 51 526 -- --
pumpage 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0
[TCE] -- --
est TCE mass 0 0 0 0 0 0 0 0 0 0 0 0 0 -- --
pumpage 13,234 7,823 9,935 13,149 12,517 8,361 8,564 11,808 12,345 12,099 12,091 12,458 134,383 412 256
est TCE mass 105 62 79 69 65 43 49 68 71 77 77 79 843 -- --
pumpage 0 18,210 12,320 32,210 38,180 37,540 31,310 29,370 24,580 31,230 27,650 36,140 318,740 978 606
[TCE] 67 56 56 48 52 55 56 56 64 50 54 56 -- --
est TCE mass 0 10 5.8 15 15 16 14 14 11 17 12 16 147 -- --
pumpage 0 0 28,310 6,630 0 0 5,890 6,340 11,820 10,070 8350 0 77,410 238 147
[TCE] 110 110 38 92 51.5 51.5 52 72 -- --
est TCE mass 0 0 26 6 1 0 0 1 9 4 9 5 1 4 3 3 6 0 52 -- --
7EX-4MA
7EX-5MA
MEX-1MA
SRP 23.6E-06.0N
EA
12
GW
ET
S
TOTAL
7EX-3aMA
AR
EA
7 G
WE
TS
est TCE mass 0 0 26 6.1 0 0 1.9 4.9 5.1 4.3 3.6 0 52
pumpage 0 18,210 40,630 38,840 38,180 37,540 37,200 35,710 36,400 41,300 36,000 36,140 396,150 1,216 754
est TCE mass 0 10 32 21 15 16 16 19 17 21 15 16 198 -- --
Total Pumping (in million gallons): 4,964 -- --
EXPLANATION: Total Pumping (in acre-feet): -- 15,234 --
1) [TCE] = Concentration of trichloroethene. TCE Mass Removal (in pounds): 2,712 -- --
2) Pumpage reported in thousands of gallons (x1000). Total Pumping (in gpm): -- -- 9,444
3)4)
5) TCE mass is reported in pounds (estimated).6) gpm = gallons per minute
AR
E
[TCE] reported as micrograms per liter (μg/L) by TestAmerica. Where multiple samples were collected on the same day, the value shown is the average of those results. Where samples were not able to be collected (e.g., extraction well was offline during scheduled sampling date), but well operated some other time/duration of the month, TCE results assumed as results (or average results) of recent samples collected during other/adjacent months.
Quarterly samples collected for Area 7 GWETS extraction wells assumed as average TCE concentration for entire quarter.
TOTAL
TABLE 9. 2013 LABORATORY RESULTS FOR TREATMENT SYSTEM SAMPLESNORTH INDIAN BEND WASH SUPERFUND SITE, SCOTTSDALE, ARIZONA(results presented in micrograms per liter, µg/L)
SAMPLE LOCATION FIELD SAMPLE ID
SAMPLE DATE
SAMPLE TYPE LAB TCA DCE TCM PCE TCE
SP-102 SP-102 1/7/13 Original TA <0.50 <0.50 0.59 3.0 900
SP-102 SP-102 2/4/13 Original TA <0.50 <0.50 0.71 3.4 970
SP-102 SP-102 3/4/13 Original TA <0.50 <0.50 0.76 3.0 820
SP-102 SP-102 4/1/13 Original TA <0.50 <0.50 0.69 2.8 720
SP-102 SP-102 5/6/13 Original TA <0.50 <0.50 0.61 3.2 710
SP-102 SP-102 6/4/13 Original TA <5.0 <5.0(1) <5.0(1) <5.0 530
SP-102 SP-102 7/2/13 Original TA <0.50 <0.50 0.85 4.1 710
SP-102 SP-102 8/6/13 Original TA <0.50(2) <0.50(2) 0.71(2) 2.9(2) 790(2)
SP-102 SP-102 9/9/13 Original TA <0.50 <0.50 0.68 3.5 850
SP-102 SP-102 10/7/13 Original TA <0.50 <0.50 0.78 3.2 1,000
SP-102 SP-102 11/4/13 Original TA <0.50 <0.50 0.84 3.6 930
SP-102 SP-102 12/2/13 Original TA <0.50 <0.50 0.78 3.1 850
SP-103 SP-103 1/7/13 Original TA <0.50 <0.50 0.64 1.2 170
SP-103 SP-103 2/4/13 Original TA <0.50 <0.50 0.66 1.3 250
SP-103 SP-103 3/4/13 Original TA <0.50 <0.50 0.71 1.1 250
SP-103 SP-103 4/1/13 Original TA <0.50 <0.50 0.60 1.0 150
SP-103 SP-103 5/6/13 Original TA <0.50 <0.50 0.56 1.1 160
SP-103 SP-103 6/4/13 Original TA <0.50 1.8 0.63 1.7 430
SP-103 SP-103 7/2/13 Original TA <0.50 1.1 0.80 1.4 160
SP-103 SP-103 8/6/13 Original TA <0.50(2) <0.50(2) 0.81(2) 0.77(2) 100(2)
SP-103 SP-103 9/9/13 Original TA <0.50 <0.50 0.65 0.98 160
SP-103 SP-103 10/7/13 Original TA <0.50 0.79 0.71 0.92 140
SP-103 SP-103 11/4/13 Original TA <0.50 <0.50 0.84 1.0 150
SP-103 SP-103 12/2/13 Original TA <0.50 <0.50 0.71 0.95 120
SP-105 SP-105 1/7/13 Original TA <0.50 <0.50(1) <0.50 <0.50 <0.50
SP-105 SP-105 2/4/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
SP-105 SP-105 3/4/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
SP-105 SP-105 4/1/13 Original TA <0.50(3) <0.50 <0.50 <0.50 <0.50
SP-105 SP-105 5/6/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
SP-105 SP-105 6/4/13 Original TA <0.50 <0.50(1) <0.50(1) <0.50 <0.50
SP-105 SP-105 7/2/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
SP-105 SP-105 8/6/13 Original TA <0.50(2) <0.50(2) <0.50(2) <0.50(2) <0.50(2)
SP-105 SP-105 9/9/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
SP-105 SP-105 10/7/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
SP-105 SP-105 11/4/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
SP-105 SP-105 12/2/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
WSP-1 WSP-1-1A-02182013 2/18/13 Original TA <0.50 2.5 2.3 5.0 68
WSP-1 WSP-1-1A-03042013 3/4/13 Original TA <0.50 2.2 2.0 3.5 59
WSP-1 WSP-1-1A-04012013 4/1/13 Original TA <0.50 0.86 4.3 2.1 92
WSP-1 WSP-1-1A-05062013 5/6/13 Original TA <0.50 2.4 1.7 3.3 48
AREA 7 GWETS
AREA 12 GWETS
Page 1 of 7
TABLE 9. 2013 LABORATORY RESULTS FOR TREATMENT SYSTEM SAMPLESNORTH INDIAN BEND WASH SUPERFUND SITE, SCOTTSDALE, ARIZONA(results presented in micrograms per liter, µg/L)
SAMPLE LOCATION FIELD SAMPLE ID
SAMPLE DATE
SAMPLE TYPE LAB TCA DCE TCM PCE TCE
WSP-1 WSP-1-1A-06032013 6/3/13 Original TA <0.50 1.8 1.8 3.1 49
WSP-1 WSP-1-1A-07012013 7/1/13 Original TA <0.50 2.1 1.9 3.8 56
WSP-1 WSP-1-1A-08042013 8/4/13 Original TA <0.50 1.0 4.3 1.7 96
WSP-1 WSP-1-1A-09022013 9/2/13 Original TA <0.50 2.2 1.9 3.0 54
WSP-1 WSP-1-1A-100613 10/6/13 Original TA <0.50 1.5 1.9 3.1 53
WSP-1 WSP-1-1A-11042013 11/4/13 Original TA <0.50 1.9 1.9 3.2 50
WSP-1 WSP-1-1A-12022013 12/2/13 Original TA <0.50 1.6 1.9 2.9 54
WSP-2 WSP-2-1A-02182013 2/18/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
WSP-2 WSP-2-1B-02182013 2/18/13 Duplicate TA <0.50 <0.50 <0.50 <0.50 <0.50
WSP-2 WSP-2-1A-03042013 3/4/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
WSP-2 WSP-2-1A-04012013 4/1/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
WSP-2 WSP-2-1A-05062013 5/6/13 Original TA <0.50 <0.50(3,5) <0.50 <0.50 <0.50
WSP-2 WSP-2-1A-06032013 6/3/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
WSP-2 WSP-2-1A-07012013 7/1/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
WSP-2 WSP-2-1A-08042013 8/4/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
WSP-2 WSP-2-1A-09022013 9/2/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
WSP-2 WSP-2-1A-100613 10/6/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
WSP-2 WSP-2-1A-11042013 11/4/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
WSP-2 WSP-2-1A-12022013 12/2/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Tower 2 Effluent Tower 2 Effluent 2/11/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Tower 2 Effluent Tower 2 Effluent 2/18/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Tower 2 Effluent Tower 2 Effluent 2/25/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Tower 2 Effluent Tower 2 Effluent 3/4/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Tower 2 Effluent Tower 2 Effluent 3/11/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Tower 2 Effluent Tower 2 Effluent 3/18/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Tower 2 Effluent Tower 2 Effluent 3/25/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Tower 2 Effluent Tower 2 Effluent 4/1/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Tower 2 Effluent Tower 2 Effluent 4/8/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Tower 2 Effluent Tower 2 Effluent 4/15/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Tower 2 Effluent Tower 2 Effluent 4/22/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Tower 2 Effluent Tower 2 Effluent 4/29/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Tower 2 Effluent Tower 2 Effluent 5/6/13 Original TA <0.50 <0.50(4,5) <0.50 <0.50 <0.50
Tower 2 Effluent Tower 2 Effluent 5/13/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Tower 2 Effluent Tower 2 Effluent 5/20/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Tower 2 Effluent Tower 2 Effluent 5/27/13 Original TA <0.50 <0.50(1) <0.50 <0.50 <0.50
Tower 2 Effluent Tower 2 Effluent 6/3/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Tower 2 Effluent Tower 2 Effluent 6/10/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Tower 2 Effluent Tower 2 Effluent 6/17/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Tower 2 Effluent Tower 2 Effluent 6/24/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Tower 2 Effluent Tower 2 Effluent 7/1/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Tower 2 Effluent Tower 2 Effluent 7/8/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
MRTF (PCX-1 Treatment Train)
Page 2 of 7
TABLE 9. 2013 LABORATORY RESULTS FOR TREATMENT SYSTEM SAMPLESNORTH INDIAN BEND WASH SUPERFUND SITE, SCOTTSDALE, ARIZONA(results presented in micrograms per liter, µg/L)
SAMPLE LOCATION FIELD SAMPLE ID
SAMPLE DATE
SAMPLE TYPE LAB TCA DCE TCM PCE TCE
Tower 2 Effluent Tower 2 Effluent 7/15/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Tower 2 Effluent Tower 2 Effluent 7/22/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Tower 2 Effluent Tower 2 Effluent 7/29/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Tower 2 Effluent Tower 2 Effluent 8/5/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
NGTF Influent NGTF Influent 7/12/13 Original TA <0.50 0.96 1.9 5.0 75
NGTF Influent NGTF Influent 7/15/13 Original TA <0.50 1.1 1.9 5.0 75
NGTF Influent NGTF Influent 7/22/13 Original TA <0.50 1.0 1.7 4.5 70
NGTF Influent NGTF Influent 7/29/13 Original TA <0.50 0.78 1.5 4.1 64
NGTF Influent NGTF Influent 8/5/13 Original TA <0.50 1.1 1.7 3.3 65
NGTF Influent NGTF - INF 8/14/13 Original TA <0.50 0.92 1.6 4.9 72
NGTF Influent NGTF - INF 8/19/13 Original TA <0.50 1.0 1.7 5.0 75
NGTF Influent NGTF - INF 8/26/13 Original TA <0.50 0.96 1.8 4.6 68
NGTF Influent NGTF - INF 9/3/13 Original TA <0.50 0.98 2.0 4.6 72
NGTF Influent NGTF - INF 9/9/13 Original TA <0.50 0.86 1.6 5.0 71
NGTF Influent NGTF - INF 9/16/13 Original TA <0.50 0.89 1.6 3.7 66
NGTF Influent NGTF - INF 9/25/13 Original TA <0.50(2) 0.86(2) 1.7(2) 4.4(2) 64(2)
NGTF Influent NGTF - INF 9/30/13 Original TA <0.50(2) 0.85(2) 1.8(2) 4.4(2) 68(2)
NGTF Influent NGTF - INF 10/7/13 Original TA <0.50 0.90 1.7 4.7 73
NGTF Influent NGTF - INF 10/14/13 Original TA <0.50 0.96 1.6 4.8 73
NGTF Influent NGTF - INF 10/21/13 Original TA <0.50 1.0 2.0 4.8 74
NGTF Influent NGTF - INF 10/28/13 Original TA <0.50 1.3 2.0 5.9 86
NGTF Influent NGTF - INF 11/4/13 Original TA <0.50 1.0 1.6 4.6 69
NGTF Influent NGTF - INF 11/11/13 Original TA <0.50 1.6(3) 2.1 5.6 / 5.3 91 / 79
NGTF Influent NGTF - INF 11/18/13 Original TA <0.50 1.6 1.9 4.9 77
NGTF Influent NGTF - INF 11/26/13 Original TA <0.50 1.0 1.7 4.5 75
NGTF Influent NGTF - INF 12/2/13 Original TA <0.50 0.86 1.5 4.3 69
NGTF Influent NGTF - INF 12/9/13 Original TA <0.50 1.1 1.7 4.7 70
NGTF Influent NGTF - INF 12/16/13 Original TA <0.50 0.88 1.7 5.2 73
NGTF Influent NGTF - INF 12/23/13 Original TA <0.50 0.88 1.6 5.5 71
NGTF Influent NGTF - INF 12/30/13 Original TA <0.50 1.0 1.9 6.2 81
Outfall 001 NGTF-CP 7/12/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Outfall 001 Outfall 001 7/15/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Outfall 001 Outfall 001 7/22/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50(6)
Outfall 001 Outfall 001 7/29/13 Original TA <0.50 <0.50 <1.0 <0.50 <0.50
Outfall 001 Outfall 001 8/5/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Outfall 001 AZCO 8/14/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Outfall 001 AZCO 8/19/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Outfall 001 AZCO 8/26/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Outfall 001 AZCO 9/3/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Outfall 001 AZCO 9/9/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Outfall 001 AZCO 9/16/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
NGTF
Page 3 of 7
TABLE 9. 2013 LABORATORY RESULTS FOR TREATMENT SYSTEM SAMPLESNORTH INDIAN BEND WASH SUPERFUND SITE, SCOTTSDALE, ARIZONA(results presented in micrograms per liter, µg/L)
SAMPLE LOCATION FIELD SAMPLE ID
SAMPLE DATE
SAMPLE TYPE LAB TCA DCE TCM PCE TCE
Outfall 001 AZCO 9/25/13 Original TA <0.50(2) <0.50(2) <0.50(2) <0.50(2) <0.50(2)
Outfall 001 AZCO 9/30/13 Original TA <0.50(2) <0.50(2) <0.50(2) <0.50(2) <0.50(2)
Outfall 001 AZCO 10/7/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Outfall 001 AZCO 10/14/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Outfall 001 AZCO 10/21/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Outfall 001 AZCO 10/28/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Outfall 001 AZCO 11/4/13 Original TA <0.50 <0.50 <0.50 <0.50(1) <0.50
Outfall 001 AZCO 11/11/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Outfall 001 AZCO 11/18/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Outfall 001 AZCO 11/26/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Outfall 001 AZCO 12/2/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Outfall 001 AZCO 12/9/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Outfall 001 AZCO 12/16/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Outfall 001 AZCO 12/23/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
Outfall 001 AZCO 12/30/13 Original TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 7 Field Blank 1/7/2013 FB TA <0.50 <0.50(1) <0.50 <0.50 <0.50
QC - Area 7 Trip Blank 1/7/2013 TB TA <0.50 <0.50(1) <0.50 <0.50 <0.50
QC - Area 7 Field Blank 2/4/2013 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 7 Trip Blank 2/4/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 7 Field Blank 3/4/2013 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 7 Trip Blank 3/4/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 7 Field Blank 4/1/2013 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 7 Trip Blank 4/1/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 7 Field Blank 5/6/2013 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 7 Field Blank 6/4/2013 FB TA <0.50(4,5) <0.50(4,5) <0.50 <0.50 <0.50
QC - Area 7 Field Blank 7/2/2013 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 7 Trip Blank 7/2/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 7 Field Blank 8/6/2013 FB TA <0.50(2) <0.50(2) <0.50(2) <0.50(2) <0.50(2)
QC - Area 7 Trip Blank 8/6/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 7 Field Blank 9/9/2013 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 7 Trip Blank 9/9/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 7 Field Blank 10/7/2013 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 7 Trip Blank 10/7/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 7 Field Blank 11/4/2013 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 7 Trip Blank 11/4/2013 TB TA <0.50 <0.50 <0.50 <0.50 0.99
QC - Area 7 Field Blank 12/2/2013 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 7 Trip Blank 12/2/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 12 FB-1-1A-02182013 2/18/2013 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 12 TB 2/18/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 12 FB-1-1A-03042013 3/4/2013 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 12 TB 3/4/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
Trip/Field Blanks
Page 4 of 7
TABLE 9. 2013 LABORATORY RESULTS FOR TREATMENT SYSTEM SAMPLESNORTH INDIAN BEND WASH SUPERFUND SITE, SCOTTSDALE, ARIZONA(results presented in micrograms per liter, µg/L)
SAMPLE LOCATION FIELD SAMPLE ID
SAMPLE DATE
SAMPLE TYPE LAB TCA DCE TCM PCE TCE
QC - Area 12 FB-1-1A-04012013 4/1/2013 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 12 TB 4/1/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 12 FB-1-1A-05062013 5/6/2013 FB TA <0.50 <0.50(3,5) <0.50 <0.50 <0.50
QC - Area 12 TB 5/6/2013 TB TA <0.50 <0.50(3,5) <0.50 <0.50 <0.50
QC - Area 12 FB-1-1A-06032013 6/3/2013 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 12 TB 6/3/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 12 FB-1-1A-07012013 7/1/2013 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 12 TB 7/1/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 12 FB-1-1A-08042013 8/4/2013 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 12 TB 8/4/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 12 FB-1-1A-09022013 9/2/2013 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 12 TB 9/2/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 12 TB 10/6/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 12 FB-1-1A-100713 10/7/2013 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 12 FB-1-1A-11042013 11/4/2013 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 12 TB 11/4/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 12 FB-1-1A-12022013 12/2/2013 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - Area 12 TB 12/2/2013 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Field Blank-Effluent 2/11/13 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Trip Blank-Effluent 2/11/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Field Blank-Effluent 2/18/13 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Trip Blank-Effluent 2/18/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Field Blank-Effluent 2/25/13 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Trip Blank-Effluent 2/25/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Field Blank-Effluent 3/4/13 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Trip Blank-Effluent 3/4/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Field Blank-Effluent 3/11/13 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Trip Blank-Effluent 3/11/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Field Blank-Effluent 3/18/13 FB TA
QC - MRTF Trip Blank-Effluent 3/18/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Field Blank-Effluent 3/25/13 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Trip Blank-Effluent 3/25/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Trip Blank-Effluent 4/1/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Field Blank 4/8/13 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Trip Blank 4/8/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Field Blank 4/15/13 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Trip Blank 4/15/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Field Blank 4/22/13 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Trip Blank 4/22/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Field Blank 4/29/13 FB TA <0.50(7) <0.50(1,7) <0.50(7) <0.50(7) <0.50(7)
QC - MRTF Trip Blank 4/29/13 TB TA <0.50(7) <0.50(1,7) <0.50(7) <0.50(7) <0.50(7)
QC - MRTF Field Blank-Effluent 5/6/13 FB TA <0.50 <0.50(4,5) <0.50 <0.50 <0.50
data could not be reported due to autosampler error
Page 5 of 7
TABLE 9. 2013 LABORATORY RESULTS FOR TREATMENT SYSTEM SAMPLESNORTH INDIAN BEND WASH SUPERFUND SITE, SCOTTSDALE, ARIZONA(results presented in micrograms per liter, µg/L)
SAMPLE LOCATION FIELD SAMPLE ID
SAMPLE DATE
SAMPLE TYPE LAB TCA DCE TCM PCE TCE
QC - MRTF Trip Blank-Effluent 5/6/13 TB TA <0.50 <0.50(4,5) <0.50 <0.50 <0.50
QC - MRTF Field Blank(8) 5/13/13 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Trip Blank 5/13/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Field Blank-Effluent 5/20/13 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Trip Blank-Effluent 5/20/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Field Blank-Effluent 5/27/13 FB TA <0.50 <0.50(1) <0.50 <0.50 <0.50
QC - MRTF Trip Blank-Effluent 5/27/13 TB TA <0.50 <0.50(1) <0.50 <0.50 <0.50
QC - MRTF Field Blank-Effluent 6/3/13 FB TA <0.50(4,5) <0.50(4,5) <0.50 <0.50 <0.50
QC - MRTF Trip Blank-Effluent 6/3/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Field Blank-Effluent 6/10/13 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Field Blank-Effluent 6/17/13 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Trip Blank-Effluent 6/17/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Field Blank-Effluent 6/24/13 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Field Blank-Effluent 7/1/13 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Field Blank-Effluent 7/8/13 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Field Blank-Effluent 7/15/13 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Field Blank-Effluent 7/22/13 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Field Blank-Effluent 7/29/13 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - MRTF Field Blank-Effluent 8/5/13 FB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - NGTF Trip Blank 7/12/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - NGTF Trip Blank 7/15/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - NGTF Trip Blank 7/22/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - NGTF Trip Blank 7/29/13 TB TA <0.50 <0.50 <1.0 <0.50 <0.50
QC - NGTF Trip Blank 8/5/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - NGTF Trip Blank 8/14/13 TB TA
QC - NGTF TB 8/19/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - NGTF TB 8/26/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - NGTF TB 9/3/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - NGTF TB 9/9/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - NGTF TB 9/16/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - NGTF TB 9/25/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - NGTF TB 9/30/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - NGTF TB 10/7/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - NGTF TB 10/14/13 TB TA
QC - NGTF TB 10/21/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - NGTF TB 10/28/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - NGTF TB 11/4/13 TB TA <0.50 <0.50 <0.50 <0.50(1) <0.50
QC - NGTF TB 11/11/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - NGTF TB 11/18/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - NGTF TB 11/26/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - NGTF TB 12/2/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - NGTF TB 12/9/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
due to an analyst error, sample data was not available
No data due to laboratory QC issues.
Page 6 of 7
TABLE 9. 2013 LABORATORY RESULTS FOR TREATMENT SYSTEM SAMPLESNORTH INDIAN BEND WASH SUPERFUND SITE, SCOTTSDALE, ARIZONA(results presented in micrograms per liter, µg/L)
SAMPLE LOCATION FIELD SAMPLE ID
SAMPLE DATE
SAMPLE TYPE LAB TCA DCE TCM PCE TCE
QC - NGTF TB 12/16/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - NGTF TB 12/23/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
QC - NGTF TB 12/30/13 TB TA <0.50 <0.50 <0.50 <0.50 <0.50
EXPLANATION:TCA = 1,1,1-Trichloroethane <0.50 = Analytical result is less than laboratory detection limit
DCE = 1,1-Dichloroethene QC = Quality Control
TCM = Chloroform NA = Analyte not requested for analysis
PCE = Tetrachloroethene TB = Trip Blank
TCE = Trichloroethene FB = Field Blank
TA = TestAmerica, Inc.
(1)
(2)
(3)(4)
(5)
(6)
(7) E6 Flag: Concentration estimated. Internal standard recoveries did not meet method acceptance criteria.(8) Sample analyzed without proper QC; data is presented for information purposes only. There was insufficient sample
volume to reanalyze.
R6 Flag: Laboratory Control Sample / Laboratory Control Sample Duplicate (LCS / LCSD) Relative Percent Difference (RPD) exceeded laboratory acceptance limits for the analyte. However, the LCS recovery met acceptance criteria. Data are considered valid and acceptable.Q4 Flag: Sample received with improper chemical preservation.
H1 Flag: Analysis performed past holding time; N1 Flag: CCV recovered above upper control limit, but since the result was non-detect it was reported; R6 Flag: LCS/LCSD RPD exceeded laboratory acceptance limits for the analyte, but the LCS did meet acceptance criteria. Considering these flags, data are not considered valid.
L3 Flag: The associated blank spike recovery was above method acceptance limits.
V1 Flag: Continuing Calibration Verification (CCV) recovery was above method acceptance limits. This target analyte was not detected in the sample.
L5 Flag: The associated blank spike recovery was above laboratory/method acceptance limits. This analyte was not detected in the sample.
Page 7 of 7
TABLE 10. SUMMARY OF VOC MASS ESTIMATES IN UAU GROUNDWATER FOR OCTOBER 2013 NORTH INDIAN BEND WASH SITE, SCOTTSDALE, ARIZONA
POLYGON (WELL NAME)
TOTAL VOCs
(micrograms per liter)a
ELEVATION BASE OF UAU
(feet, MSL)b
ELEVATION UAU WATER TABLE
(feet, MSL)b
SATURATED THICKNESS
(feet)
POLYGON AREA
(square feet)
SATURATED POLYGON VOLUME
(cubic feet)
SATURATED PORE VOLUME
(liters)VOC MASS
(gallons)VOC MASS (pounds)
B-J 3.54 1,065 1,130.82 66 1,312,017 86,355,647 733,651,670 0.48 5.73
B-3UA
D-1UA
E-2UA 0 1,069 1,137.02 68 2,567,322 174,634,377 1,483,641,277 0.00 0.00
E-3UA
E-4UA
E-5UA 4.91 1,067 1,131.65 65 1,563,483 101,079,176 858,738,355 0.78 9.30
E-6UA 0 1,043 1,127.95 85 2,854,410 242,484,984 2,060,079,678 0.00 0.00
E-7UA 1 1,079 1,128.99 50 2,135,156 106,734,313 906,782,705 0.17 2.00
E-9UA
E-12UA 7.79 1,075 1,135.04 60 1,868,432 112,176,920 953,021,463 1.37 16.37
E-13UA 4.05 1,080 1,135.40 55 851,113 47,149,107 400,564,667 0.30 3.58
M-2UA 2.43 1,081 1,136.75 56 1,081,841 60,307,227 512,352,105 0.23 2.75
M-3UA
M-4UA
M-5UAc
M-11UA
M-15UA
M-16UA
PG-3UA 4.3 1,046 1,124.89 79 1,523,224 120,165,618 1,020,891,042 0.81 9.68
PG-4UA 4.97 1,055 1,118.10 63 2,867,709 180,963,909 1,537,415,079 1.41 16.85
PG-5UA 4.9 1,036 1,123.18 87 1,729,659 150,798,590 1,281,139,583 1.15 13.84
PG-6UA 3.3 1,043 1,119.20 76 2,363,199 180,063,948 1,529,769,281 0.93 11.13
PG-7UA 0 1,041 1,123.21 82 2,461,634 202,370,931 1,719,282,720 0.00 0.00
PG-8UA 0.9 1,060 1,122.70 63 1,631,115 102,262,755 868,793,687 0.14 1.72
7EX-1UAc
2.9 1,092 1,182.14 90 775,509 69,903,606 593,880,063 0.32 3.80
PG-10UA 2.9 1,089 1,182.14 93 693,947 64,633,530 549,107,078 0.29 3.51
PG-11UA 1.3 1,076 1,134.48 58 2,167,731 126,764,573 1,076,953,786 0.26 3.09
PG-12UA
PG-13UA
PG-15UA
PG-16UA 1.5 1,079 1,137.78 59 1,327,719 78,038,012 662,987,538 0.18 2.19
PG-17UA
PG-18UA 4.49 1,045 1,124.34 79 1,953,438 154,976,004 1,316,629,635 1.09 13.04
PG-19UA 2.62 1,049 1,108.03 59 1,407,810 83,100,209 705,994,443 0.34 4.08
PG-20UA
PG-21UA
PG-22UA 13.04 1,067 1,133.24 66 1,764,305 116,858,742 992,796,812 2.38 28.55
PG-23UA 3.5 1,055 1,117.82 63 1,753,035 110,122,153 935,564,772 0.60 7.22
PG-24UA 8.9 1,054 1,123.00 69 1,535,896 105,969,145 900,282,061 1.47 17.67
PG-25UA 4.23 1,056 1,128.63 73 1,538,241 111,714,753 949,095,024 0.74 8.85
PG-26UA
PG-27UA
PG-28UA 2.8 1,061 1,139.27 78 1,669,714 130,693,524 1,110,332,971 0.57 6.86
PG-29UA 3.25 1,080 1,140.65 61 1,345,997 81,630,680 693,509,769 0.41 4.97
PG-30UA 0 1,074 1,137.76 64 2,013,301 128,358,005 1,090,491,105 0.00 0.00
PG-31UA 5.9 1,081 1,136.64 56 2,706,853 150,598,474 1,279,439,451 1.39 16.64
PG-32UA
PG-33UA
PG-34UA
PG-36UA
PG-39UA
ST-1UA
W-3UA
TOTALS 28,723,187,821 17.80 213.40
detection limit, the well was dry, or the well is no longer included in the NIBW Monitoring Program due to long-term ND levels of VOCs. b Feet Above Mean Sea Level
c Well was not sampled during October 2013 monitoring; water level and water quality estimated based on PG-10UA .
a Includes total concentration of TCE, PCE, 1,1,1-TCA, DCE, and Chloroform from October 2013 water quality data set. "0" indicates either that concentrations of all VOCs were below the
Abandoned
Abandoned
Abandoned
Abandoned
Abandoned
Abandoned
Abandoned
Abandoned
Abandoned
Abandoned
Abandoned
Abandoned
Abandoned
Abandoned
Abandoned
Abandoned
Abandoned
Abandoned
Abandoned
Abandoned
Abandoned
Abandoned
Abandoned
Abandoned
Abandoned
Abandoned
P:\366\2013 Annual Report\Tables\Table 10. VOC Mass 2013.xlsx
TABLE 11. AVERAGE TCE CONCENTRATIONS FOR MONITOR WELLS WITHIN ZONE OF HYDRAULIC CAPTURE, MIDDLE ALLUVIUM UNIT, AREA 7
1995 1996 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
D-2MA --- 5,600 4,650 3,500 2,200 2,369 2,533 2,180 2,200 1,650 1,650 1,145 828 1,015 1,550 1,675 1,825 1,725 1,650
E-10MA 6 6 6 11 15 15 15 14 10 8 7 6 5 6 5 5 6 5 5
PA-10MA 12 15 26 68 96 68 39 39 46 39 41 36 35 41 34 31 36 24 22
PA-12MA 190 135 175 360 760 608 586 581 580 483 483 400 407 360 400 370 343 348 303
W-1MA 2,800 1,045 560 200 497 1,432 707 389 495 270 335 151 129 95 88 44 70 195 387
W-2MA 3,000 1,950 2,050 1,950 2,900 3,844 3,875 4,490 4,875 4,725 5,275 4,325 4,225 4,900 4,325 4,100 3,925 4,450 3,575
ANNUAL AVERAGE 1,202 1,458 1,245 1,015 1,078 1,390 1,292 1,282 1,368 1,196 1,298 1,010 938 1,069 1,067 1,038 1,034 1,124 990
1995-1999 1,199 Start-Up of 7EX-3MA and 7EX-4MA Extraction Wells1996-2000 1,2371997-2001 1,2041998-2002 1,211 Start-Up of 7EX-5MA Extraction Well1999-2003 1,282 Area 7 GWETS Fully Operational2000-2004 1,305 First computed 5-year running average2001-2005 1,2872002-2006 1,2312003-2007 1,1622004-2008 1,1022005-2009 1,0772006-2010 1,0242007-2011 1,0292008-2012 1,0662009-2013 1,051
Five-Year Average TCE Concentrations (micrograms per liter)
AVERAGE TCE CONCENTRATIONS (micrograms per liter)
366\2013 Annual Report\Tables\Table 11. 2013 Area 7-5YrTCE.xlsx
TABLE 12. AVERAGE TCE CONCENTRATIONS FOR MONITOR WELLS WITHIN ZONE OF HYDRAULIC CAPTURE, MIDDLE ALLUVIUM UNIT, AREA 12
1994 1995 1996 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
E-1MA 367 440 490 370 350 370 18 3 130 3 56 73 42 22 63 21 34 37 27 55
M-4MA 29 20 32 31 32 28 27 20 24 21 25 26 20 21 20 19 20 23 23 23
M-5MA 377 365 295 120 43 65 79 115 105 45 53 54 68 65 50 65 58 48 33 34
M-6MA 333 315 180 113 120 125 22 7 55 2 40 69 43 49 68 38 63 52 60 77
M-7MA 11 7 6 8 9 3 0 1 2 1 1 1 1 1 1 1 1 1 1 0
M-9MA 150 113 72 52 24 15 10 8 5 6 7 7 4 4 5 5 4 4 5 5
M-15MA 105 14 115 83 40 75 40 25 19 14 13 11 12 12 12 12 11 10 10 9
PA-21MA 44 14 8 7 3 2 2 1 0.3 0 0 1 0 0 0 0 0 0 0 0
ANNUAL AVERAGE 177 161 150 98 78 85 24 22 42 12 24 30 24 22 27 20 24 22 20 25
1994-1998 133
Five-Year Average TCE Concentrations (micrograms per liter)
AVERAGE TCE CONCENTRATIONS (micrograms per liter)
1994 1998 1331995-1999 114 Start-Up of MEX-1 and SRP Granite Reef Extraction1996-2000 87 Area 12 GWETS Fully Operational1997-2001 621998-2002 501999-2003 372000-2004 25 First Computed 5-Year Running Average2001-2005 262002-2006 262003-2007 222004-2008 252005-2009 252006-2010 232007-2011 232008-2012 232009-2013 22
366\2013 Annual Report\Tables\Table 12. 2013 Area 12-5YrTCE.xlsx
FIGURES
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Extent of UpperAlluvium UnitSaturation
ARIZO
NACR
OSS
CUT
CANA
L
INDIAN
BEND
WASH
SALTRIVER
SRP22.9E,10.8N
SRP23.5E,10.6N
PV-12B
Scott
sdale
Roa
d
Thomas Road
McDonald Drive
Pima R
oad
Hayd
en R
oad
McDowell Road
McKellips Road
Chaparral Road
Indian School Road
Inverg
ordon
Roa
d
Indian Bend Road
AVI
AWC8
MDWC
QRIA
PCX-1
COS 3
COS 4
COS 2
COT 6
AWC9A
COS 6
COS 31
COS 69
COS 70
COS 14
COS 78COS 77
COS 74
COS 72COS 71
COS 25
COS 11
AWC-8A
SRIR-4
COS 76
COS 73
MEX-1MA
Laird 2
SRIR-10
COS 75A
AWC-12A
PV-17
PV-16
PV-15
PV-14
PV-12
PV-11
7EX-5MA
7EX-4MA
7EX-1UA
SRIR-SCC
7EX-3aMA
M-3UAM-3MAB-J
E-8MA
SRP23.6E,6N
SRP22.4E,9N
SRP22.3E,7N
SRP21.5E,8N
SRP22.5E,6N
PG-13UA
PG-11UA
E-7UAE-7LA
E-6UA
E-4UA
SRP24E,10.5N
W-3UA
ST-1UAM-1MA
M-9UAM-9MAM-9LA
M-5UAM-5MAM-5LA
M-4UAM-4MAM-2UA
M-2LA
M-16UAM-16MAM-16LA
M-11UAM-11MA
E-9UA
E-5UAE-5MA
E-3UA
E-2UAM-14MAM-14LA
E-13UA
B-3UA B-1UAB-1MA
SRP22.5E,5.5N
PG-37UA
SRP23.5E,8.8N
SRP23.5E,9.5N
SRP23.5E,5.3N
SRP22.1E,8.5N
PG-9UA
PG-8UAPA-19LA
PG-7MAPG-7UA
PG-6UAPG-6MA
PG-5UAPG-5MA
PG-4UAPG-4MA
PG-3UA
PG-21UA
PG-15UA
PG-10UA
M-15UAM-15MA
M-13UA[abandoned8/2/10]PG-38UA
PG-36UA
PG-34UA
PG-32UAPG-53MAPG-54MA
PG-31UA
PG-27UA
PG-26UAPG-24UA
PG-20UA
PG-17UAPG-12UA
SRP23E,10.8N[COS5W]
11abb[Scottsdale Raddison]
SRP23.4E,10.6N[COS5E]
IBGC
AWC-7A
SRP22.6E,10N
PG-47MAPG-48MA
M-6MA
E-12UA
D-1UA
PG-39UAPG-39LA
PG-29UA
PG-19UA
PG-33UA
PG-30UA
PG-28UA
PG-25UA
PG-23UA
PG-22UA
PG-18UA
PG-16UA
PG-42LA
PG-43LA
PG-40LAPG-41LA
PG-44LAPG-2LA PG-1LA
PA-2LAPA-3MA
PA-7MAPA-6LAPG-52MA
S-2LAS-2MA
PA-14MAPA-13LA PG-46MA PG-45MA
PA-5LAPA-4MA
PA-18LAPA-17MA
D-2MA PG-50MAPG-51MA
E-10MAW-2MA
PG-56MAW-1MA
M-12MA2PA-8LA2PG-55MA
PA-1MA
PA-21MAPG-57MA
PG-14UAM-17MA/LA
E-14LA PA-12MAPA-11LAPG-35UA
PA-20MAPG-38MA/LA
PG-23MA/LA
M-10LAM-10LA2
M-10MA2
E-1UAE-1MAE-1LA
M-7MA
PA-16MAPA-15LA
PA-23MAPA-22LA
S-1MA S-1LA
PA-9LAPA-10MA
M-8UA
11
11
06
31
18
07
30
18
0710
19
06
34
1415
131415
03
12
03
10
23
35
01
22
02
27
01
26
36
12
25
13
02
24
T. 1 N.
T. 2 N.
R. 4 E.
R. 4 E.
R. 5 E.
R. 5 E.
T. 1 N.
T. 2 N.
GIS-TUC\366.1402\ALL_WELLS_2013_Locmap\20Feb2014
0 3,000
Feet
NORTH INDIAN BEND WASH AREAMARICOPA COUNTY, ARIZONA
WELL LOCATION MAP
FIGURE 1
EXPLANATION
? Extraction Water Well Location and IdentifierPA-15LACOS75A
COS74SRP22.4E, 9N
!( Monitor Well Location and Identifier
Production Water Well Location and Identifier
COS69 ( Abandoned Production Water Well orMonitor Well Location and Identifier
!.
= Inactive Production or Monitor Water Well Location and Identifier
!
!.
!=
!=
!
!
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Estimated Extent ofMiddle and LowerAlluvium Units
ARIZO
NACR
OSS
CUT
CANA
L
INDIAN
BEND
WASH
SALTRIVER
PV-12B
1,095
1,105
1,110
1,100
1,110
1,115
1,1251,120
1,115
1,105
1,0951,1051,100
1,0901,095
1,100
1,105
1,110
1,0901,080
1,0751,080
1,085
1,115
1,1301,1351,120
Scott
sdale
Roa
d
Thomas Road
McDonald Drive
Pima R
oad
Hayd
en R
oad
McDowell Road
McKellips Road
Chaparral Road
Indian School Road
Inverg
ordon
Roa
d
Indian Bend Road
AVI
AWC8
MDWC
QRIA
IBGC
PCX-1
COS 3
COS 4
COS 2
COT 6
AWC9A
M-5MA
COS 6
COS 31
COS 69
COS 70
COS 14
COS 78COS 77
COS 74
COS 72COS 71
COS 25
COS 11
AWC-8AAWC-7A
SRIR-4
COS 76
COS 73
Laird 2
SRIR-10
COS 75A
AWC-12A
7EX-5MA
7EX-4MA
7EX-1UAPG-56MA*
PG-55MA*
PG-54MA*PG-53MA*
PG-52MA*
PG-49MA
PG-46MA*PG-45MA*
SRIR-SCC
SRP23.6E,6N
SRP22.4E,9N
SRP22.3E,7N
SRP21.5E,8N
SRP22.5E,6N
SRP22.6E,10N
SRP24E,10.5N
SRP22.5E,5.5N
SRP23.5E,8.8N
SRP23.5E,9.5N
SRP23.5E,5.3N
SRP23.5E,10.6N
SRP22.9E,10.8N
PV-17PV-16
PV-15
PV-14PV-11
11abb[Scottsdale Raddison]
E-1MA
MEX-1MA
7EX-3aMA
SRP22.1E,8.5N
SRP23E,10.8N[COS5W]
PV-12
SRP23.4E,10.6N[COS5E]
PA-1MA1,122.0
W-2MA1,088.7
S-2MA1,119.2
S-1MA1,122.8
M-9MA1,109.6
M-4MA1,097.5
M-3MA1,103.4
M-2MA1,099.7
E-8MA1,101.5
B-1MA1,090.4PG-7MA
1,105.4
PG-6MA1,110.5
PG-5MA1,097.3
PG-4MA1,096.3
PA-3MA1,139.5
M-16MA1,110.8
M-15MA1,101.5
M-14MA1,108.3M-11MA
1,106.2
E-10MA1,104.9
M-12MA21,074.3
PG-57MA1,113.7
PA-23MA1,105.5
PA-21MA1,111.9
PA-20MA1,094.4
PA-17MA1,130.3
PA-14MA1,123.1
PA-10MA1,100.8
PA-12MA1,093.9
M-17MA/LA1,089.1
W-1MA1,123.7
M-7MA1,095.2
M-6MA1,097.5
M-1MA1,103.6
E-5MA1,126.2
D-2MA1,129.4
PA-7MA1,136.9
PA-4MA1,130.5
M-10MA21,101.9
PG-51MA*[1,091.8]
PG-50MA*[1,088.4]
PG-48MA*[1,096.2]
PG-47MA*[1,091.5]
PA-16MA1,103.6
PG-38MA/LA1,097.3
PG-23MA/LA1,103.3
T. 1 N.
T. 2 N.
R. 4 E.
R. 4 E.
R. 5 E.
R. 5 E.
T. 1 N.
T. 2 N.
GIS-TUC\366.1402\WaterLevel\2013\MAU_WLApr2013\27Feb2014
0 3,000
Feet
NORTH INDIAN BEND WASH AREAMARICOPA COUNTY, ARIZONA
GROUNDWATER LEVEL CONTOURSMIDDLE ALLUVIUM UNIT WELLS
APRIL 2013
FIGURE 2
EXPLANATION
Groundwater Level Altitude, in feet above mean sea level Indicates Data Not Used for Contouring
PG-7MA
COS75A
COS74
SRP22.5E, 6N
!( Middle Alluvium Monitor Well Location and Identifier* Denotes the Well is a Lower MAU Well
Production Water Well Location and Identifier
COS69 ( Abandoned Production Water Well or Monitor Well Location and Identifier
? Extraction Water Well Location and Identifier!.
1,105.4
Groundwater Level Altitude Contour, in feet above mean sea level1,090
= Inactive Production Water Well Location and Identifier
[ ]
NOTE: Water level collected from MAU completed well at piezometer PA-11/12 located approximately 70 feet northwest of original well PA-12MA
!.
!=
!=
!
!!
!
!
!
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!
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!.
!.
!.
!.
!=
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!.
!.
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!=
!.
!.
!=
!=
!.
!(
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!(
!=
!.
!=
!.
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!.
!.
!.
!.
!.
Estimated Extent ofMiddle and LowerAlluvium Units
ARIZO
NACR
OSS
CUT
CANA
L
INDIAN
BEND
WASH
SALTRIVER
965
Scott
sdale
Roa
d
Thomas Road
McDonald Drive
Pima R
oad
Hayd
en R
oad
McDowell Road
McKellips Road
Chaparral Road
Indian School Road
Inverg
ordon
Roa
d
Indian Bend Road
1,0851,080
980975
995
985
1,090
1,070
1,075
1,065
1,060
1,040
1,055
1,050
970
1,0351,030
1,020
1,025
1,0151,0051,095
965
1,100
990
1,045
1,0101,000
AVI
AWC8
MDWC
QRIA
IBGC
PCX-1
COS 3
COS 4
COS 2
COT 6
AWC9A
COS 6
PV-12B
COS 31
COS 69
COS 70
COS 14
COS 78
COS 72COS 71
COS 25
COS 11
AWC-8A
AWC-7A
SRIR-4
COS 76
COS 73
MEX-1MA
Laird 2
SRIR-10
COS 75A
AWC-12A
7EX-5MA
7EX-4MA
7EX-1UA
PG-41LA
SRIR-SCC
7EX-3aMA
SRP23.6E,6N
SRP22.4E,9N
SRP22.3E,7N
SRP21.5E,8N
SRP22.5E,6N
SRP22.6E,10N
SRP24E,10.5N
SRP22.5E,5.5N
SRP23.5E,8.8N
SRP23.5E,9.5N
SRP23.5E,5.3N
SRP23.5E,10.6N
SRP22.9E,10.8N
PV-17PV-16
PV-15
PV-14
11abb[Scottsdale Raddison]
COS 77
COS 74
SRP22.1E,8.5N
SRP23E,10.8N[COS5W]
PV-12
PV-11
SRP23.4E,10.6N[COS5E]
S-2LA989.5
PG-2LA961.3 PG-1LA
973.3
PA-6LA982.1
PA-5LA983.7
S-1LA1,010.9
PG-44LA970.3
PG-42LA968.9
PG-40LA966.7
PA-13LA990.9
M-9LA1,062.9
M-5LA1,073.8
M-2LA1,079.8
E-7LA1,084.7
PA-9LA1,048.6
M-16LA1,059.8
M-14LA1,067.9
E-14LA1,088.7
PA-8LA21,045.9
M-10LA21,076.6
PG-39LA[1,126.4]
PA-19LA1,091.5
PA-18LA1,025.7
PA-15LA1,098.8
PA-11LA1,068.3
M-17MA/LA1,089.1
PG-38MA/LA1,097.3
PG-23MA/LA1,103.3
PA-2LA987.2
PG-43LA968.8
E-1LA1,072.2
PA-22LA1,092.9
T. 1 N.
T. 2 N.
R. 4 E.
R. 4 E.
R. 5 E.
R. 5 E.
T. 1 N.
T. 2 N.
GIS-TUC\366.1402\WL\2013\LAU_WLApr2013\27Feb2014
0 3,000
Feet
NORTH INDIAN BEND WASH AREAMARICOPA COUNTY, ARIZONA
GROUNDWATER LEVEL CONTOURSLOWER ALLUVIUM UNIT WELLS
APRIL 2013
FIGURE 3
EXPLANATION
= Inactive Production Water Well Location and Identifier
Groundwater Level Altitude, in feet above mean sea level Indicates Data Not Used for Contouring
PA-15LA
COS75A
COS74
SRP22.5E, 6N
!( Lower Alluvium Monitor Well Location and Identifier
Production Water Well Location and Identifier
COS69 ( Abandoned Production Water Well orMonitor Well Location and Identifier
? Extraction Water Well Location and Identifier!.
1,098.8
Groundwater Level Altitude Contour, in feet above mean sea level1,090
[ ]
NOTE: Water level collected from LAU completed well at piezometer PA-11/12 located approximately 80 feet northwest of original well PA-11LA
!
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!(
!(
!(
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!(
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!.
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!=
!.
!.
!.
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Estimated Extent ofUpper Alluvium UnitSaturation
ARIZO
NACR
OSS
CUT
CANA
L
INDI
ANBE
NDWA
SH
SALTRIVER
Scott
sdale
Roa
d
Thomas Road
McDonald Drive
Pima R
oad
Hayd
en R
oad
McDowell Road
McKellips Road
Chaparral Road
Indian School Road
Inverg
ordon
Roa
d
Indian Bend Road
AVI
AWC8
MDWC
QRIA
IBGC
PCX-1
COS 3
COS 4
COS 2
COT 6
AWC9A
W-3UA
M-9UA
M-5UA
M-4UAM-3UA
E-9UA
E-4UA
E-3UA
D-1UA
COS 6
B-3UA
COS 31
COS 69
COS 70
COS 14
COS 78COS 77
COS 74
COS 72COS 71
COS 25
COS 11
AWC-8A
AWC-7A
SRIR-4
PG-9UA
M-16UA
M-15UA
M-13UA
M-11UA
COS 76
COS 73
PG-38UA
PG-37UA
Laird 2
SRIR-10
COS 75A
AWC-12A
7EX-5MA
7EX-4MA
7EX-1UA
PG-39UA
PG-36UA
PG-34UA
PG-33UA
PG-32UA
PG-27UA
PG-26UA
PG-21UAPG-20UA
PG-17UA
PG-15UAPG-13UA
PG-12UA
SRIR-SCC
SRP23.6E,6N
SRP22.4E,9N
SRP22.3E,7N
SRP21.5E,8N
SRP22.5E,6N
SRP22.6E,10N
SRP24E,10.5N
SRP22.5E,5.5N
SRP23.5E,8.8N
SRP23.5E,9.5N
SRP23.5E,5.3N
SRP23.5E,10.6N
SRP22.9E,10.8N
SRP23E,10.8N[COS5W]PV-17
PV-16
PV-15
PV-14
PV-12
PV-11
11abb[Scottsdale Raddison]
ST-1UAMEX-1MA
7EX-3aMA
SRP22.1E,8.5N
SRP23.4E,10.6N[COS5E]
E-2UA1,137.0
B-J1,130.8
PG-24UA1,123.0
PG-19UA[1,108.0]
M-2UA1,136.8
E-6UA1,128.0
E-1UA1,140.6
B-1UA1,134.2
PG-8UA1,122.7
PG-7UA1,123.2
PG-6UA1,119.2
PG-5UA1,123.2PG-4UA
1,118.1
PG-31UA1,136.6
PG-28UA1,139.3
PG-23UA1,117.8
PG-16UA1,137.8
PG-11UA1,134.5
E-7UA1,129.0
E-12UA1,135.0
E-5UA1,131.7
PG-3UA1,124.9
E-13UA1,135.4
PG-30UA1,137.8
PG-29UA1,140.7
PG-25UA1,128.6
PG-22UA1,133.2
PG-18UA1,124.3
PG-10UA[1,182.1]
PV-12B
1,130
1,140
1,135
1,125
1,120
T. 1 N.
T. 2 N.
R. 4 E.
R. 4 E.
R. 5 E.
R. 5 E.
T. 1 N.
T. 2 N.
GIS-TUC\366.1402\WL\2012\UAU_WLOct2013\12Feb2014
0 3,000
Feet
NORTH INDIAN BEND WASH AREAMARICOPA COUNTY, ARIZONA
GROUNDWATER LEVEL CONTOURSUPPER ALLUVIUM UNIT WELLS
OCTOBER 2013
FIGURE 4
EXPLANATION
Groundwater Level Altitude, in feet above mean sea levelPG-7UA
COS75A
COS74
SRP22.5E, 6N
!( Upper Alluvium Monitor Well Location and Identifier
Production Water Well Location and Identifier
COS69 ( Abandoned Production Water Well orMonitor Well Location and Identifier
? Extraction Water Well Location and Identifier!.
1,123.2
Groundwater Level Altitude Contour, in feet above mean sea level1,120
= Inactive Production Water Well Location and Identifier
Indicates data not used in contouring[ ]
!
!.
!=
!=
!
!
!
!
!
! !
!
!
!
! !
!
! !
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!!
!!
!
!
!!
!
!!
!
!
!
!
!
!
!
!
!.
!
!
!?
!?
!?
!?
!.
!(
!?
!?
!.
!.
!.
!.
!.
!=
!.
!? !?
!.
!?
!
!=
!.
!.
!.
!.
!.
!=
!.
!.
!=
!=
!.
!(
!( !(
!(
!(
!=
!.
!=
!.
!.
!.
!.
!=
!(
!.
!?
!?
!.
!=
!.
!?
!?
!
!
!.
!.
!.
!.
!.
Estimated Extent ofMiddle and LowerAlluvium Units
ARIZO
NACR
OSS
CUT
CANA
L
INDIAN
BEND
WASH
SALTRIVER
PV-12B
1,085
1,0751,070
1,0701,080
Scott
sdale
Roa
d
Thomas Road
McDonald Drive
Pima R
oad
Hayd
en R
oad
McDowell Road
McKellips Road
Chaparral Road
Indian School Road
Inverg
ordon
Roa
d
Indian Bend Road
AVI
AWC8
MDWC
QRIA
IBGC
PCX-1
COS 3
COS 4
COS 2
COT 6
AWC9A
PV-17PV-16
PV-15
PV-14
PV-12
PV-11
COS 6
COS 31
COS 69
COS 70
COS 14
COS 78COS 77
COS 74
COS 72COS 71
COS 25
COS 11
AWC-8AAWC-7A
SRIR-4
COS 76
COS 73
MEX-1MA
Laird 2
SRIR-10
COS 75A
AWC-12A
7EX-5MA
7EX-4MA
7EX-1UAPG-56MA*
PG-55MA*
PG-54MA*PG-53MA*
PG-52MA*
PG-49MA
PG-46MA*PG-45MA*
SRIR-SCC
SRP23.6E,6N
SRP22.4E,9N
SRP22.3E,7N
SRP21.5E,8N
SRP22.5E,6N
SRP24E,10.5N
SRP22.5E,5.5N
SRP23.5E,8.8N
SRP23.5E,9.5N
SRP23.5E,5.3N
SRP23.5E,10.6N
SRP22.9E,10.8NSRP23E,10.8N[COS5W]
SRP23.4E,10.6N[COS5E]
11abb[Scottsdale Raddison]
7EX-3aMA
SRP22.6E,10N
SRP22.1E,8.5N
M-14MA1,096
W-2MA1,087.2
S-2MA1,114.5
S-1MA1,119.7
PA-20MA1,080.0
M-9MA1,095.5
M-4MA1,079.2M-3MA1,084.1
M-2MA1,070.8
E-8MA1,037.8
E-5MA1,092.7
B-1MA1,063.8
PG-7MA1,095.1+
PG-6MA1,098.5
PG-5MA1,086.9+
PG-4MA1,083.1
PA-7MA1,132.4
PA-3MA1,134.9
PA-1MA1,116.3
M-16MA1,105.4
M-15MA1,080.7
M-11MA1,100.2
E-10MA1,100.2
M-12MA21,089.2
PG-57MA1,106.9
PA-23MA1,061.6
PA-21MA1,103.7
PA-17MA1,136.4
PA-14MA1,118.5
PA-10MA1,095.4
PA-12MA1,088.1
M-17MA/LA1,081.6
PG-38MA/LA1,084.1
M-7MA1,085.0
W-1MA1,122.4
M-6MA1,084.2
M-5MA1,065.7
M-1MA1,081.6
E-1MA1,085.8
D-2MA1,127.1
PA-4MA1,126.8
M-10MA21,071.7
PG-51MA*[1,086.2]
PG-50MA*[1,088.7]
PG-48MA*[1,081.3]
PG-47MA*[1,082.3]
PA-16MA1,072.1
PG-23MA/LA1,089.6
1,100
1,120
1,0951,125
1,125
1,105
1,1101,115
1,1151,085
1,120
1,090
1,090
1,130
1,135
1,080
1,060
1,080
1,0501,040
1,100
T. 1 N.
T. 2 N.
R. 4 E.
R. 4 E.
R. 5 E.
R. 5 E.
T. 1 N.
T. 2 N.
GIS-TUC\366.1402\WL\2013\MAU_WLOct2013\27Feb2014
0 3,000
Feet
NORTH INDIAN BEND WASH AREAMARICOPA COUNTY, ARIZONA
GROUNDWATER LEVEL CONTOURSMIDDLE ALLUVIUM UNIT WELLS
OCTOBER 2013
FIGURE 5
EXPLANATION
Groundwater Level Altitude, in feet above mean sea levelPG-7MA
COS75A
COS74
SRP22.5E, 6N
!( Middle Alluvium Monitor Well Location and Identifier* Denotes the Well is a Lower MAU Well
Production Water Well Location and Identifier
COS69 ( Abandoned Production Water Well or Monitor Well Location and Identifier
? Extraction Water Well Location and Identifier!.
1,105.4
Groundwater Level Altitude Contour, in feet above mean sea level1,090
= Inactive Production Water Well Location and Identifier
[ ] Indicates Data Not Used for ContouringIndicates Data From November 2013 was used for contouring+
NOTE: Water level collected from MAU completed well at piezometer PA-11/12 located approximately 70 feet northwest of original well PA-12MA
!.
!=
!=
!
!!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!!
!!
!
!
!
!.
!?
!?
!?
!?
!.
!(
!?
!?
!.
!.
!.
!.
!.
!=
!.
!? !?
!.
!?
!
!=
!.
!.
!.
!.
!.
!=
!.
!.
!=
!=
!.
!(
!( !(
!(
!(
!=
!.
!=
!.
!.
!.
!.
!=
!(
!.
!?
!?
!.
!=
!.
!?
!?
!
!
!.
!.
!.
!.
!.
Estimated Extent ofMiddle and LowerAlluvium Units
ARIZO
NACR
OSS
CUT
CANA
L
INDIAN
BEND
WASH
SALTRIVER
940
96095
595094
594
0945
Scott
sdale
Roa
d
Thomas Road
McDonald Drive
Pima R
oad
Hayd
en R
oad
McDowell Road
McKellips Road
Chaparral Road
Indian School Road
Inverg
ordon
Roa
d
Indian Bend Road
995990
1,065
980970
1,075
1,080
1,070
1,060
1,055
1,0501,045
1,0401,035
1,0251,020
1,0051,085
985
975965
1,030
1,015
1,000
1,010
AVI
AWC8
MDWC
QRIA
IBGC
PCX-1
COS 3
COS 4
COS 2
COT 6
AWC9A
COS 6
PV-12B
COS 31
COS 69
COS 70
COS 14
COS 78
COS 74
COS 72COS 71
COS 25
COS 11
AWC-8AAWC-7A
SRIR-4
COS 76
COS 73
MEX-1MA
Laird 2
SRIR-10
COS 75A
AWC-12A
7EX-5MA
7EX-4MA
7EX-1UA
PG-41LA
SRIR-SCC
7EX-3aMA
SRP23.6E,6N
SRP22.4E,9N
SRP22.3E,7N
SRP21.5E,8N
SRP22.5E,6N
SRP22.6E,10N
SRP24E,10.5N
SRP22.5E,5.5N
SRP23.5E,8.8N
SRP23.5E,9.5N
SRP23.5E,5.3N
SRP23.5E,10.6N
SRP22.9E,10.8N
PV-17
PV-16
PV-15
PV-14PV-11
11abb[Scottsdale Raddison]
COS 77
SRP22.1E,8.5N
SRP23E,10.8N[COS5W]
PV-12
SRP23.4E,10.6N[COS5E]
S-2LA966.1
S-1LA995.6
PG-2LA941.3
PG-1LA952.7
PA-6LA960.4
PA-5LA961.1
PA-13LA973.9
M-9LA1,054.1
M-5LA1,061.5
M-2LA1,066.6
E-7LA1,072.1
PA-9LA1,037.7
M-16LA1,052.1
M-14LA1,057.7
E-14LA1,080.1
PA-8LA21,037.9
M-10LA21,064.4
PG-39LA1,081.4
PA-19LA1,077.4
PA-18LA1,011.9
PA-15LA1,083.2
PA-11LA1,062.6
M-17MA/LA1,081.6
PG-38MA/LA1,084.1
PG-23MA/LA1,089.6
PA-2LA966.6
PG-44LA945.4+
PG-43LA942.5
PG-42LA943.9
PG-40LA945.5
E-1LA1,060.4
PA-22LA1,077.8
T. 1 N.
T. 2 N.
R. 4 E.
R. 4 E.
R. 5 E.
R. 5 E.
T. 1 N.
T. 2 N.
GIS-TUC\366.1402\WL\2013\LAU_WLOct2013\27Feb2014
0 3,000
Feet
NORTH INDIAN BEND WASH AREAMARICOPA COUNTY, ARIZONA
GROUNDWATER LEVEL CONTOURSLOWER ALLUVIUM UNIT WELLS
OCTOBER 2013
FIGURE 6
EXPLANATION
= Inactive Production Water Well Location and Identifier
Groundwater Level Altitude, in feet above mean sea levelPA-15LA
COS75A
COS74
SRP22.5E, 6N
!( Lower Alluvium Monitor Well Location and Identifier
Production Water Well Location and Identifier
COS69 ( Abandoned Production Water Well orMonitor Well Location and Identifier
? Extraction Water Well Location and Identifier!.
1,083.2
Groundwater Level Altitude Contour, in feet above mean sea level1,090
Indicates Data from Transducer Used for Contouring+
NOTE: Water level collected from LAU completed well at piezometer PA-11/12 located approximately 80 feet northwest of original well PA-11LA
-40
-30
-20
-10
0
10
20
30
40
50C
HA
NG
E IN
GR
OU
ND
WA
TE
R L
EV
EL,
IN F
EE
T
PG
-10
PG
-29
PG
-16
PG
-28
PG
-31
PG
-30
PG
-11
E-2
E-6
E-1
PG
-8
E-7
PG
-22
PG
-4
PG
-25
PG
-5
E-5
M-2
PG
-23
PG
-19
E-1
3
PG
-24
B-J
E-1
2
PG
-6
PG
-18
PG
-3
B-1
PG
-7
FIGURE 7. CHANGE IN UPPER ALLUVIUM UNIT GROUNDWATER LEVEL,OCTOBER 2012 TO OCTOBER 2013
P:\366\2013 Annual Report\Figure7-WLChangeUAU12to13.grf 28Jan14
Notes: 1) Well locations arrangednorth to south
2) Thirty (30) UAU wells wereabandoned in 2013.
3) PG-10 water level measurementis anomalous.
-70
-60
-50
-40
-30
-20
-10
0
10C
HA
NG
E IN
GR
OU
ND
WA
TE
R L
EV
EL,
IN F
EE
T
PA
-7
PA
-3
S-2
PA
-4
PA
-14
S-1
D-2
PG
-50
PG
-51
PA
-17
W-1 E
-10
W-2
M-1
2M
A2
PA
-10
PA
-1
PA
-12
MA
2
M-1
6
PA
-21 P
G-5
7
M-9
M-1
4
M-1
1
M-1
5
M-1
0M
A2
M-6
PG
-47
PG
-48
E-1
PA
-20
M-5
M-7
PG
-4
M-1
M-4
PG
-5
E-5
M-2
M-3
E-8
PG
-6
PA
-16
B-1
PG
-7
PA
-23
FIGURE 8. CHANGE IN MIDDLE ALLUVIUM UNIT GROUNDWATER LEVEL,OCTOBER 2012 TO OCTOBER 2013
P:\366\2013 Annual Report\Figure8-WLChangeMAU12to13.grf 06Feb14
Notes: 1) Well locations arrangednorth to south
-20
-15
-10
-5
0
5
10C
HA
NG
E IN
GR
OU
ND
WA
TE
R L
EV
EL,
IN F
EE
T
PG
-43
PG
-42
PG
-40
PG
-44
PG
-1
PG
-2
PA
-6P
A-2
S-2
PA
-5
PA
-13
S-1
PA
-18
PA
-8L
A2
PA
-9 E-1
4
M-1
7M
A/L
A PA
-11
LA2
M-1
6
M-9
M-1
4
M-1
0L
A2
E-1
PA
-19
M-5
E-7
PG
-39
PG
-38
MA
/LA
M-2
PG
-23
MA
/LA
PA
-15
PA
-22
FIGURE 9. CHANGE IN LOWER ALLUVIUM UNIT GROUNDWATER LEVEL,OCTOBER 2012 TO OCTOBER 2013
P:\366\2013 Annual Report\Figure10-WLChangeLAU12to13.grf 06Feb14
Notes: 1) Well locations arrangednorth to south
!
!(
!
!.
!=
!=
!(
!
!
!
!
!(
!(
!
!
!
!(
!(
!(
!(
!(
! !(
!(
!(
!(
!
! !(
!(
!(
!
!(
!
!
!(!(
!
!!
!
!(
!(
!!
!
!
!(
!(
!(
!(
!(
!
!
!
!
!
!
!(
!.
!(
!(
!?
!?
!?
!?
!.
!(
!?
!?
!.
!.
!.
!.
!.
!=
!.
!? !?
!.
!?
!=
!.
!.
!.
!.
!.
!=
!.
!.
!=
!=
!.
!(
!( !(
!(
!(
!=
!.
!=
!.
!.
!.
!.
!=
!(
!.
!?
!?
!.
!=
!.
!?
!?
!(
!(
!.
!.
!.
!.
!.
Estimated Extent ofUpper Alluvium UnitSaturation
ARIZO
NACR
OSS
CUT
CANA
L
INDIAN
BEND
WASH
SALTRIVER
<0.5
<0.5
5 5
Scott
sdale
Roa
d
Thomas Road
McDonald Drive
Pima R
oad
Hayd
en R
oad
McDowell Road
McKellips Road
Chaparral Road
Indian School Road
Inverg
ordon
Roa
d
Indian Bend Road
AVI
AWC8
MDWC
QRIA
IBGC
COS 3
COS 4
COS 2
COT 6
AWC9A
PV-17
PV-16PV-12
PV-11
W-3UA
M-9UA
M-5UA
M-4UA
M-3UA
E-9UA
E-6UA
E-4UA
E-3UA
E-2UA
E-1UA
D-1UA
COS 6
B-3UAB-1UA
PV-12B
COS 69
COS 70
COS 14
COS 78COS 77
COS 74
COS 25
COS 11
AWC-8A
AWC-7A
SRIR-4
PG-9UA
PG-7UA
M-16UA
M-15UA
M-11UA
COS 76
COS 73
PG-38UA
PG-37UA
Laird 2
SRIR-10
AWC-12A
7EX-5MA
7EX-1UA
PG-39UA
PG-36UA
PG-34UA
PG-33UA
PG-32UA
PG-30UA
PG-27UA
PG-26UA
PG-21UAPG-20UA
PG-17UAPG-15UA
PG-13UA
PG-12UA
SRIR-SCCSRP22.4E,9N
SRP22.3E,7N
SRP21.5E,8N
SRP22.5E,6N
SRP22.6E,10N
SRP24E,10.5N
SRP22.5E,5.5N
SRP23.5E,8.8N
SRP23.5E,9.5N
SRP23.5E,5.3N
SRP22.1E,8.5N
SRP23.5E,10.6N
SRP22.9E,10.8N
SRP23E,10.8N[COS5W]
SRP23.4E,10.6N[COS5E]
11abb[Scottsdale Raddison]
ST-1UA
PV-15
E-7UA1
PCX-1
COS 72
E-12UA7.0
COS 31
COS 71
PV-14
PG-25UA3.0
M-2UA1.8
E-5UA3.6
MEX-1MA
COS 75A
PG-8UA
PG-6UA2.3
PG-5UA3.4
PG-3UA3.3
M-13UAPG-4UA0.94
PG-31UA3.7
PG-29UA2.5PG-28UA
1.2
PG-24UA7.8
PG-23UA2.4
PG-16UA1.5
PG-11UA
B-J2.8
E-13UA3.4
PG-22UA9.1
PG-19UA1.9
PG-18UA3.5
PG-10UA1.3
7EX-4MA
7EX-3aMA
SRP23.6E,6N
T. 1 N.
T. 2 N.
R. 4 E.
R. 4 E.
R. 5 E.
R. 5 E.
T. 1 N.
T. 2 N.
0 3,000
Feet
GIS-TUC\366.1402\TCE\2013\UAU_TCE_Oct2013\11Feb2014
NORTH INDIAN BEND WASH AREAMARICOPA COUNTY, ARIZONA
FIGURE 10
EXPLANATIONPG-5UA
COS75A
COS74
SRP22.5E, 6N
!( Upper Alluvium Monitor Well Location and Identifier
Production Water Well Location and Identifier
COS69 ( Abandoned Production Water Well orMonitor Well Location and Identifier
? Extraction Water Well Location and Identifier!.
CONCENTRATION OF TCE INUPPER ALLUVIUM UNIT WELLS
OCTOBER 2013
Concentration of TCE, micrograms per liter3.4
TCE Concentration Contour, in micrograms per liter5
= Inactive Production Water Well Location and Identifier
Abandoned Production Water Well orMonitor Well Location and Identifier
!
!.
!=
!=
!
!
!
!
!
! !
!
!
!
! !
!
! !
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!!
!!
!
!
!!
!
!!
!
!
!
!
!
!
!
!
!.
!
!
!?
!?
!?
!?
!.
!(
!?
!?
!.
!.
!.
!.
!.
!=
!.
!? !?
!.
!?
!
!=
!.
!.
!.
!.
!.
!=
!.
!.
!=
!=
!.
!(
!( !(
!(
!(
!=
!.
!=
!.
!.
!.
!.
!=
!(
!.
!?
!?
!.
!=
!.
!?
!?
!
!
!.
!.
!.
!.
!.
Estimated Extent ofMiddle and LowerAlluvium Units
ARIZO
NACR
OSS
CUT
CANA
L
INDIAN
BEND
WASH
SALTRIVER
PA-21MA<0.5
M-7MA<0.5
B-1MA<0.5
S-2MA<0.5
S-1MA<0.5
PA-14MA<0.5
PG-49MA<0.5
M-11MA<0.5
Scott
sdale
Roa
d
Thomas Road
McDonald Drive
Pima R
oad
Hayd
en R
oad
McDowell Road
McKellips Road
Chaparral Road
Indian School Road
Inverg
ordon
Roa
d
Indian Bend Road
AVI
AWC8
MDWC
QRIA
IBGC
COS 3
COS 4
COS 2
COT 6
AWC9A
PV-17
PV-16PV-12
PV-11
M-3MA
M-1MA
COS 6
PV-12B
COS 69
COS 70
COS 14
COS 78COS 77
COS 74
COS 25
COS 11
AWC-8A
AWC-7A
SRIR-4
PA-7MA
PA-4MA
PA-1MA
M-14MA
COS 76
COS 73
Laird 2
SRIR-10
AWC-12A
7EX-5MA
7EX-1UA
PG-57MAPG-53MA
PG-52MA
PG-51MA
PG-47MA
PG-46MA
PA-23MA
PA-17MA
SRIR-SCCSRP22.4E,9N
SRP22.3E,7N
SRP21.5E,8N
SRP22.5E,6N
SRP22.6E,10N
SRP24E,10.5N
SRP22.5E,5.5N
SRP23.5E,8.8N
SRP23.5E,9.5N
SRP23.5E,5.3N
SRP22.1E,8.5N
SRP23.5E,10.6N
SRP22.9E,10.8N
SRP23E,10.8N[COS5W]
SRP23.4E,10.6N[COS5E]
11abb[Scottsdale Raddison]
PG-45MA
PV-15
PCX-1
COS 72
M-5MA11
M-4MA24
E-8MA21
E-5MA49
E-1MA33
COS 31
PV-14
W-1MA480
PG-5MA32
M-9MA5.2
M-2MA2.1
M-16MA18
M-12MA221
W-2MA4,000
PG-7MA6.1
PG-6MA170
PG-4MA3.1
PA-3MA
PA-20MA81
PA-16MA25
PA-10MA25
E-10MA5.1
PG-55MA[3.2]
PA-12MA310
M-17MA/LA3.8
PG-23MA/LA20
SRP23.6E,6N49PG-38MA/LA
1.4
M-6MA85
COS 71
PG-56MA[4.0]
M-10MA242 MEX-1MA
50
COS 75A
PG-54MA[32]
PG-48MA[61]
M-15MA9.1
D-2MA1,900PG-50MA
[5.1]
7EX-4MA1,300
7EX-3aMA440
5
50
100
50
5001,000
100
T. 1 N.
T. 2 N.
R. 4 E.
R. 4 E.
R. 5 E.
R. 5 E.
T. 1 N.
T. 2 N.
GIS-TUC\366.1402\TCE\2013\MAU_TCE_Oct2013\12Feb2014
0 3,000
Feet
NORTH INDIAN BEND WASH AREAMARICOPA COUNTY, ARIZONA
FIGURE 11
CONCENTRATION OF TCE INMIDDLE ALLUVIUM UNIT WELLS
OCTOBER 2013
EXPLANATIONPG-6MA
COS75A
COS74
SRP22.5E, 6N
!( Middle Alluvium Monitor Well Location and Identifier* denotes the well is a Lower MAU well
Production Water Well Location and Identifier
COS69 (
? Extraction Water Well Location and Identifier!.
Concentration of TCE, micrograms per liter;[ ] indicates data not used for contouring
170
TCE Concentration Contour, in micrograms per liter5
= Inactive Production Water Well Location and Identifier
!.
!=
!=
!
!!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!!
!!
!
!
!
!.
!?
!?
!?
!?
!.
!(
!?
!?
!.
!.
!.
!.
!.
!=
!.
!? !?
!.
!?
!
!=
!.
!.
!.
!.
!.
!=
!.
!.
!=
!=
!.
!(
!( !(
!(
!(
!=
!.
!=
!.
!.
!.
!.
!=
!(
!.
!?
!?
!.
!=
!.
!?
!?
!
!
!.
!.
!.
!.
!.
Estimated Extent ofMiddle and LowerAlluvium Units
ARIZO
NACR
OSS
CUT
CANA
L
INDIAN
BEND
WASH
SALTRIVER
M-5LA<0.5
S-1LA<0.5
PA-2LA<0.5
PA-15LA<0.5
PG-44LA<0.5
PG-43LA<0.5
Scott
sdale
Roa
d
Thomas Road
McDonald Drive
Pima R
oad
Hayd
en R
oad
McDowell Road
McKellips Road
Chaparral Road
Indian School Road
Inverg
ordon
Roa
d
Indian Bend Road
AVI
AWC8
MDWC
QRIA
IBGC
COS 3
COS 4
COS 2
COT 6
AWC9A
PV-17
PV-16PV-12
PV-11
M-9LA
M-2LA
E-1LA
COS 6
PV-12B
COS 69
COS 70
COS 14
COS 78COS 77
COS 74
COS 25
COS 11
AWC-8A
AWC-7A
SRIR-4
E-14LA
COS 76
COS 73
Laird 2
SRIR-10
AWC-12A
7EX-5MA
7EX-1UA
PG-41LA
PA-22LA
SRIR-SCC
SRP22.4E,9N
SRP22.3E,7N
SRP21.5E,8N
SRP22.5E,6N
SRP22.6E,10N
SRP24E,10.5N
SRP22.5E,5.5N
SRP23.5E,8.8N
SRP23.5E,9.5N
SRP23.5E,5.3N
SRP22.1E,8.5N
SRP23.5E,10.6N
SRP22.9E,10.8NSRP23E,10.8N[COS5W]
SRP23.4E,10.6N[COS5E]
11abb[Scottsdale Raddison]
PV-157.0
PCX-177
COS 72
S-2LA29
E-7LA17
COS 31
PV-141.7
PG-2LA62
PA-9LA16
M-16LA53
M-14LA21
M-10LA210
COS 75A81
PG-40LA23
PG-1LA1.1
PA-6LA240
PA-5LA140
PA-19LA61
PA-8LA29.5
PG-42LA1.4
PG-39LA6.4
PA-18LA1.5
PA-13LA180
7EX-4MA
7EX-3aMA
PA-11LA0.57
M-17MA/LA3.8
PG-23MA/LA20
PG-38MA/LA1.4
COS 71
MEX-1MA
SRP23.6E,6N
5
5010
0 200
50
50
T. 1 N.
T. 2 N.
R. 4 E.
R. 4 E.
R. 5 E.
R. 5 E.
T. 1 N.
T. 2 N.
GIS-TUC\366.1402\TCE\2013\LAU_TCE_Oct2013\25Feb2014
0 3,000
Feet
NORTH INDIAN BEND WASH AREAMARICOPA COUNTY, ARIZONA
FIGURE 12
EXPLANATION
= Inactive Production Water Well Location and Identifier
PA-13LA
COS75A
COS74
SRP22.5E, 6N
!( Lower Alluvium Monitor Well Location and Identifier
Production Water Well Location and Identifier
COS69 ( Abandoned Production Water Well or Monitor Well Location and Identifier
? Extraction Water Well Location and Identifier!.
CONCENTRATION OF TCE INLOWER ALLUVIUM UNIT WELLS
OCTOBER 2013
Concentration of TCE, micrograms per liter
TCE Concentration Contour, in micrograms per liter5
180
!
!(
!
!.
!=
!=
!(
!
!
!
!
!(
!(
!
!
!
!(
!(
!(
!(
!(
! !(
!(
!(
!(
!
! !(
!(
!(
!
!(
!
!
!(!(
!
!!
!
!(
!(
!!
!
!
!(
!(
!(
!(
!(
!
!
!
!
!
!
!(
!.
!(
!(
!?
!?
!?
!?
!.
!(
!?
!?
!.
!.
!.
!.
!.
!=
!.
!? !?
!.
!?
!=
!.
!.
!.
!.
!.
!=
!.
!.
!=
!=
!.
!(
!( !(
!(
!(
!=
!.
!=
!.
!.
!.
!.
!=
!(
!.
!?
!?
!.
!=
!.
!?
!?
!(
!(
!.
!.
!.
!.
!.
Estimated Extent ofUpper Alluvium UnitSaturation
ARIZO
NACR
OSS
CUT
CANA
L
INDIAN
BEND
WASH
SALTRIVER
5 5
Scott
sdale
Roa
d
Thomas Road
McDonald Drive
Pima R
oad
Hayd
en R
oad
McDowell Road
McKellips Road
Chaparral Road
Indian School Road
Inverg
ordon
Roa
d
Indian Bend Road
AVI
AWC8
MDWC
QRIA
IBGC
COS 3
COS 4
COS 2
COT 6
AWC9A
PV-17
PV-16PV-12
PV-11
W-3UA
M-9UA
M-5UA
M-4UA
M-3UA
E-9UA
E-6UA
E-4UA
E-3UA
E-2UA
E-1UA
D-1UA
COS 6
B-3UAB-1UA
PV-12B
COS 69
COS 70
COS 14
COS 78COS 77
COS 74
COS 25
COS 11
AWC-8A
AWC-7A
SRIR-4
PG-9UA
PG-7UA
M-16UA
M-15UA
M-11UA
COS 76
COS 73
PG-38UA
PG-37UA
Laird 2
SRIR-10
AWC-12A
7EX-5MA
7EX-1UA
PG-39UA
PG-36UA
PG-34UA
PG-33UA
PG-32UA
PG-30UA
PG-27UA
PG-26UA
PG-21UAPG-20UA
PG-17UA
PG-15UA
PG-13UA
PG-12UA
SRIR-SCCSRP22.4E,9N
SRP22.3E,7N
SRP21.5E,8N
SRP22.5E,6N
SRP22.6E,10N
SRP24E,10.5N
SRP22.5E,5.5N
SRP23.5E,8.8N
SRP23.5E,9.5N
SRP23.5E,5.3N
SRP22.1E,8.5N
SRP23.5E,10.6N
SRP22.9E,10.8N
SRP23E,10.8N[COS5W]
SRP23.4E,10.6N[COS5E]
11abb[Scottsdale Raddison]
ST-1UA
PV-15
E-7UA
PCX-1
COS 72
E-12UA
COS 31
COS 71
PV-14
PG-25UAM-2UA
E-5UA
MEX-1MA
COS 75A
PG-8UA
PG-6UA
PG-5UA
PG-3UA
M-13UAPG-4UA
PG-31UA
PG-29UAPG-28UA
PG-24UAPG-23UA
PG-16UA
PG-11UA
B-JE-13UA
PG-22UA
PG-19UA
PG-18UA
PG-10UA
7EX-4MA
7EX-3aMA
SRP23.6E,6N5
5 5
T. 1 N.
T. 2 N.
R. 4 E.
R. 4 E.
R. 5 E.
R. 5 E.
T. 1 N.
T. 2 N.
0 3,000
Feet
GIS-TUC\366.1402\TCE\2013\UAU_TCE_Oct2001-2013\05Feb2014
NORTH INDIAN BEND WASH AREAMARICOPA COUNTY, ARIZONA
FIGURE 13
CONCENTRATION OF TCE INUPPER ALLUVIUM UNIT WELLS
OCTOBER 2001 - OCTOBER 2013
EXPLANATIONPG-3UACOS75ACOS74
SRP22.5E, 6N
!( Upper Alluvium Monitor Well Location and Identifier
Production Water Well Location and Identifier!.
COS69 Abandoned Production Water Well orMonitor Well Location and Identifier(
TCE Concentration Contour, in micrograms per liter (October 2001)TCE Concentration Contour, in micrograms per liter (October 2013)
55
= Inactive Production Water Well Location and Identifier
? Extraction Water Well Location and Identifier
!
!.
!=
!=
!
!
!
!
!
! !
!
!
!
! !
!
! !
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!!
!!
!
!
!!
!
!!
!
!
!
!
!
!
!
!
!.
!
!
!?
!?
!?
!?
!.
!(
!?
!?
!.
!.
!.
!.
!.
!=
!.
!? !?
!.
!?
!
!=
!.
!.
!.
!.
!.
!=
!.
!.
!=
!=
!.
!(
!( !(
!(
!(
!=
!.
!=
!.
!.
!.
!.
!=
!(
!.
!?
!?
!.
!=
!.
!?
!?
!
!
!.
!.
!.
!.
!.
Estimated Extent ofMiddle and LowerAlluvium Units
ARIZO
NACR
OSS
CUT
CANA
L
INDIAN
BEND
WASH
SALTRIVER
S-1MA
PA-14MA
S-2MA
M-11MA
PA-21MA
B-1MA
M-7MA
1,000
500
10050
100
50
5
50
Scott
sdale
Roa
d
Thomas Road
McDonald Drive
Pima R
oad
Hayd
en R
oad
McDowell Road
McKellips Road
Chaparral Road
Indian School Road
Inverg
ordon
Roa
d
Indian Bend Road
AVI
AWC8
MDWC
QRIA
IBGC
COS 3
COS 4
COS 2
COT 6
AWC9A
PV-17
PV-16PV-12
PV-11
M-3MA
M-1MA
COS 6
PV-12B
COS 69
COS 70
COS 14
COS 78COS 77
COS 74
COS 25
COS 11
AWC-8A
AWC-7A
SRIR-4
PA-7MA
PA-4MA
PA-1MA
M-14MA
COS 76
COS 73
Laird 2
SRIR-10
AWC-12A
7EX-5MA
7EX-1UA
PG-57MAPG-53MA
PG-52MA
PG-51MA
PG-47MA
PG-46MA
PA-23MA
PA-17MA
SRIR-SCCSRP22.4E,9N
SRP22.3E,7N
SRP21.5E,8N
SRP22.5E,6N
SRP22.6E,10N
SRP24E,10.5N
SRP22.5E,5.5N
SRP23.5E,8.8N
SRP23.5E,9.5N
SRP23.5E,5.3N
SRP22.1E,8.5N
SRP23.5E,10.6N
SRP22.9E,10.8N
SRP23E,10.8N[COS5W]
SRP23.4E,10.6N[COS5E]
11abb[Scottsdale Raddison]
PG-45MA
PV-15
PCX-1
COS 72
M-5MA
M-4MA
E-8MA
E-5MA
E-1MA
COS 31
PV-14
W-1MA
PG-5MA
M-9MA
M-2MA
M-16MA
M-12MA2
W-2MA
PG-7MA
PG-6MA
PG-4MA
PA-3MA
PA-20MA
PA-16MA
PA-10MA
E-10MA
PG-55MA
PG-49MA
PA-12MA
M-17MA/LA
PG-23MA/LA
SRP23.6E,6NPG-38MA/LA
M-6MA
COS 71
PG-56MA
M-10MA2
MEX-1MA
COS 75A
PG-54MA
PG-48MA
M-15MA
D-2MAPG-50MA
7EX-4MA7EX-3aMA
5
50
100
50
5001,000
100
T. 1 N.
T. 2 N.
R. 4 E.
R. 4 E.
R. 5 E.
R. 5 E.
T. 1 N.
T. 2 N.
GIS-TUC\366.1402\TCE\2013\MAU_TCE_Oct2001-2013\18Feb2014
0 3,000
Feet
NORTH INDIAN BEND WASH AREAMARICOPA COUNTY, ARIZONA
FIGURE 14
CONCENTRATION OF TCE INMIDDLE ALLUVIUM UNIT WELLSOCTOBER 2001 - OCTOBER 2013
EXPLANATION
? Extraction Water Well Location and Identifier
= Inactive Production Water Well Location and Identifier
PG-16MACOS75ACOS74
SRP22.5E, 6N
!( Middle Alluvium Monitor Well Location and Identifier
Production Water Well Location and Identifier!.
COS69 Abandoned Production Water Well orMonitor Well Location and Identifier(
TCE Concentration Contour, in micrograms per liter (October 2001) Indicates contour re-evaluated based on new data for well M-17MA/LATCE Concentration Contour, in micrograms per liter (October 2013)
50
50
!.
!=
!=
!
!!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!!
!!
!
!
!
!.
!?
!?
!?
!?
!.
!(
!?
!?
!.
!.
!.
!.
!.
!=
!.
!? !?
!.
!?
!
!=
!.
!.
!.
!.
!.
!=
!.
!.
!=
!=
!.
!(
!( !(
!(
!(
!=
!.
!=
!.
!.
!.
!.
!=
!(
!.
!?
!?
!.
!=
!.
!?
!?
!
!
!.
!.
!.
!.
!.
Estimated Extent ofMiddle and LowerAlluvium Units
ARIZO
NACR
OSS
CUT
CANA
L
INDIAN
BEND
WASH
SALTRIVER
PA-15LA
M-5LA
S-1LA
PA-2LA
PG-44LA
PG-43LA
50
100
50
5Sc
ottsd
ale R
oad
Thomas Road
McDonald Drive
Pima R
oad
Hayd
en R
oad
McDowell Road
McKellips Road
Chaparral Road
Indian School Road
Inverg
ordon
Roa
d
Indian Bend Road
AVI
AWC8
MDWC
QRIA
IBGC
COS 3
COS 4
COS 2
COT 6
AWC9A
PV-17
PV-16PV-12
PV-11
M-9LA
M-2LA
E-1LA
COS 6
PV-12B
COS 69
COS 70
COS 14
COS 78COS 77
COS 74
COS 25
COS 11
AWC-8A
AWC-7A
SRIR-4
E-14LA
COS 76
COS 73
Laird 2
SRIR-10
AWC-12A
7EX-5MA
7EX-1UA
PG-41LA
PA-22LA
SRIR-SCCSRP22.4E,9N
SRP22.3E,7N
SRP21.5E,8N
SRP22.5E,6N
SRP22.6E,10N
SRP24E,10.5N
SRP22.5E,5.5N
SRP23.5E,8.8N
SRP23.5E,9.5N
SRP23.5E,5.3N
SRP22.1E,8.5N
SRP23.5E,10.6N
SRP22.9E,10.8NSRP23E,10.8N[COS5W]
SRP23.4E,10.6N[COS5E]
11abb[Scottsdale Raddison]
PV-15
PCX-1
COS 72
S-2LA
E-7LA
COS 31
PV-14
PG-2LA
PA-9LA
M-16LA
M-14LA
M-10LA2
COS 75A
PG-40LA
PG-1LA
PA-6LA
PA-5LA
PA-19LA
PA-8LA2
PG-42LA
PG-39LA
PA-18LA
PA-13LA
7EX-4MA7EX-3aMA
PA-11LAM-17MA/LA
PG-23MA/LA
PG-38MA/LA
COS 71
MEX-1MA
SRP23.6E,6N
5
5010
0 200
50
T. 1 N.
T. 2 N.
R. 4 E.
R. 4 E.
R. 5 E.
R. 5 E.
T. 1 N.
T. 2 N.
GIS-TUC\366.1402\TCE\2013\LAU_TCE_Oct2001-2013\25Feb2014
0 3,000
Feet
NORTH INDIAN BEND WASH AREAMARICOPA COUNTY, ARIZONA
FIGURE 15
CONCENTRATION OF TCE INLOWER ALLUVIUM UNIT WELLSOCTOBER 2001 - OCTOBER 2013
EXPLANATIONPA-15LACOS75A
COS74SRP22.5E, 6N
!( Lower Alluvium Monitor Well Location and Identifier
Production Water Well Location and Identifier!.
COS69 Abandoned Production Water Well orMonitor Well Location and Identifier(
TCE Concentration Contour, in micrograms per liter (October 2001) Indicates contour re-evaluated based on new data for well M-17MA/LATCE Concentration Contour, in micrograms per liter (October 2013)
50
50
? Extraction Water Well Location and Identifier
= Inactive Production Water Well Location and Identifier
!.
!=
!=
!.
!?
!?
!?
!?
!.
!(
!?
!?
!.
!.
!.
!.
!.
!=
!.
!? !?
!.
!?
!=
!.
!.
!.
!.
!.
!=
!.
!.
!=
!=
!.
!=
!.
!=
!.
!.
!.
!.
!=
!.
!?
!?
!.
!=
!.
!?
!?
!.
!.
!.
!.
!.
Extent of UpperAlluvium UnitSaturation
ARIZO
NACR
OSS
CUT
CANA
L
INDIAN
BEND
WASH
SALTRIVER
Extent of >5 µg/LTCE in LAUOctober 2013
Extent of >5 µg/LTCE in MAUOctober 2013
Scott
sdale
Roa
d
Thomas Road
McDonald Drive
Pima R
oad
Hayd
en R
oad
McDowell Road
McKellips Road
Chaparral Road
Indian School Road
Inverg
ordon
Roa
d
Indian Bend Road
0811
17
11
06
31
05
05
04
33
18
07
32
30
16
09
18
28
0710
19
06
34
1415
08
1314
09
15
03
21
12
03
10
23
35
01
22
02
2927
01
26
20
16
17
04
36
12
25
13
02
24
IBGC0
PCX-10
COS 30
QRIA36
COS 40
PV-120
COS 60
COS 700
COS 140
COS 110
SRIR-40
COS 760
COS 730
AVI157.5
SRIR-100
AWC-12A0
PV-17109
7EX-5MA0
7EX-1UA0
COS 31790
MDWC114.9
AWC-8A347
Laird 21.7
COS 2536.1
PV-16566.2
COS 74478.4
COS 72518.7
AWC-7A703.1
PV-152550.6
PV-142136.5
PV-112525.9
MEX-1MA978.2
SRP22.4E,9N0
SRP22.3E,7N0
SRP22.5E,6N0
COT 61553.94
7EX-4MA157.9
SRIR-SCC174.2
COS 75A3401.3
7EX-3aMA254.5
SRP23.5E,5.3N0
SRP22.1E,8.5N0
SRP24E,10.5N992
SRP23.6E,6N237.6
SRP23.5E,8.8N1.6
SRP21.5E,8N356.4
SRP23.5E,9.5N46.2
SRP22.5E,5.5N196.7
SRP23.5E,10.6N586.8
SRP22.9E,10.8N532.5
11abb[Scottsdale Raddison]0
AWC8470.4
AWC9A946.8
PV-12B2361.9
COS 711136.7
SRP22.6E,10N210.1
T. 1 N.
T. 2 N.
R. 4 E.
R. 4 E.
R. 5 E.
R. 5 E.
T. 1 N.
T. 2 N.
GIS-TUC\366.1402\AnnualWellProduction_2013\04March2014
0 3,000
Feet
NORTH INDIAN BEND WASH AREAMARICOPA COUNTY, ARIZONA
ANNUALWELL PRODUCTION
2013
FIGURE 16
VOLUME PUMPED, acre-feet0 -10
11 - 50
51 - 100
101 - 500
501 - 1,000
1,001 - 2,000
2,001 - 3,000
>3,000
EXPLANATIONCOS75A
COS25
SRP22.4E, 9N
Production Water Well Locationand Identifier
COS69 ( Abandoned Production Water Well orMonitor Well Location and Identifier
!.
Annual Production for 2012, in acre-feet36.1
?Extraction Water Well Locationand Identifier
=Inactive Production Water Well Locationand Identifier
NA = Data not available
N.I.S. = Not in Service
Indian Bend Road
McDonald Drive
AREA12
AREA 7
Chaparral Road
Thomas Road
McDowell Road
McKellips Road
SALT RIVER
Indian School Road
ARIZO
NA
CA
NA
L
Inve
rgor
don
Roa
d
Sco
ttsda
le R
oad
Hay
den
Roa
d
Pim
a R
oad
Dob
son
Roa
d
FIGURE 17. LOCATIONS FOR EXTRACTION WELLS, PIPELINES, AND TREATMEANT FACILITIES, NIBW SUPERFUND SITE
AR
IZO
NA
CR
OS
SC
UT
CA
NAL
Miller Road Treatment Facility
3000 60000
Central Groundwater Treatment Facility
Area 12Groundwater Extraction and Treatment System
Area 7Groundwater Extraction and Treatment System
PV-14
PV-15
PCX-1
COS-75A
7EX-3aMA
7EX-4MA
7EX-5MA
COS-71
COS-72
COS-31
GRANITE REEFMEX-1MA
Drafting\366.1402\2013AnnualReport\FIG17_Extractionwells_pipelineUPDATED_Feb2014.AI\27Feb2014
NIBW Granular Activated Carbon Treatment Facility
FIGURE 18. TOTAL MASS OF VOLATILE ORGANIC COMPOUNDS IN SATURATED PORTION OF UPPER ALLUVIUM UNIT
P:\366\2013 Annual Report\Fig18_TotalMass.grf 15Jan2014
1993 1994 1995 1996 1997 1998 1999 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013 2014
YEAR
0
1,000
2,000
3,000
4,000
5,000
6,000
7,000
8,000
9,000
10,000
11,000
12,000T
OT
AL
VO
C M
AS
S, I
N P
OU
ND
S
Excluding PG-4UA PCE
Including PG-4UA PCE
10,900
3,055
2,364
1,9631,612
1,5371,408
1,223 1,115856
643 514 502 423 274 274 280 375 376 455 355 287 294 242 202
11,105
3,142
2,4262,079
1,838 1,9271,625
1,3881,204
1,075789
568 710 533 356 358 289521 469 592
427 306 309 251 213
5-Year Average, in pounds
Total VOCsTime Frame Total VOCs Excluding PG-4UA
1996 through 2000 1749 15781997 through 2001 1320 11371998 through 2002 1091 9131999 through 2003 828 6942000 through 2004 627 4982001 through 2005 469 3782002 through 2006 411 3252003 through 2007 399 3162004 through 2008 446 3522005 through 2009 460 3682006 through 2010 463 3702007 through 2011 421 3532008 through 2012 377 3272009 through 2013 301 276
!
!.
!=
!=
!
!
!
!
!
! !
!
!
!
! !
!
! !
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!!
!!
!
!
!!
!
!!
!
!
!
!
!
!
!
!
!.
!
!
!?
!?
!?
!?
!.
!(
!?
!?
!.
!.
!.
!.
!.
!=
!.
!? !?
!.
!?
!
!=
!.
!.
!.
!.
!.
!=
!.
!.
!=
!=
!.
!(
!( !(
!(
!(
!=
!.
!=
!.
!.
!.
!.
!=
!(
!.
!?
!?
!.
!=
!.
!?
!?
!
!
!.
!.
!.
!.
!.
Estimated Extent ofMiddle and LowerAlluvium Units
ARIZO
NACR
OSS
CUT
CANA
L
INDIAN
BEND
WASH
SALTRIVER
PV-12B
1,085
1,0751,070
Estimated Extent of Hydraulic Capture
1,0701,080
Scott
sdale
Roa
d
Thomas Road
McDonald Drive
Pima R
oad
Hayd
en R
oad
McDowell Road
McKellips Road
Chaparral Road
Indian School Road
Inverg
ordon
Roa
d
Indian Bend Road
AVI
AWC8
MDWC
QRIA
IBGC
PCX-1
COS 3
COS 4
COS 2
COT 6
AWC9A
PV-17PV-16
PV-15
PV-14
PV-12
PV-11
COS 6
COS 31
COS 69
COS 70
COS 14
COS 78COS 77
COS 74
COS 72COS 71
COS 25
COS 11
AWC-8AAWC-7A
SRIR-4
COS 76
COS 73
MEX-1MA
Laird 2
SRIR-10
COS 75A
AWC-12A
7EX-5MA
7EX-4MA
7EX-1UAPG-56MA*
PG-55MA*
PG-54MA*PG-53MA*
PG-52MA*
PG-49MA
PG-46MA*PG-45MA*
SRIR-SCC
SRP23.6E,6N
SRP22.4E,9N
SRP22.3E,7N
SRP21.5E,8N
SRP22.5E,6N
SRP24E,10.5N
SRP22.5E,5.5N
SRP23.5E,8.8N
SRP23.5E,9.5N
SRP23.5E,5.3N
SRP23.5E,10.6N
SRP22.9E,10.8NSRP23E,10.8N[COS5W]
SRP23.4E,10.6N[COS5E]
11abb[Scottsdale Raddison]
7EX-3aMA
SRP22.6E,10N
SRP22.1E,8.5N
M-14MA
W-2MA
S-2MA
S-1MA
PA-20MA
M-9MA
M-4MA
M-3MAM-2MA
E-8MA
E-5MA
B-1MA
PG-7MA
PG-6MA
PG-5MA
PG-4MA
PA-7MAPA-3MA
PA-1MA
M-16MA
M-15MA
M-11MA
E-10MA
M-12MA2
PG-57MA
PA-23MA
PA-21MA
PA-17MA
PA-14MA
PA-10MA
PA-12MA
M-17MA/LA
PG-38MA/LA
M-7MA
W-1MA
M-6MA
M-5MA
M-1MA
E-1MA
D-2MA
PA-4MA
M-10MA2
PG-51MA*
PG-50MA*
PG-48MA*
PG-47MA*
PA-16MA
PG-23MA/LA
1,100
1,120
1,0951,125
1,125
1,105
1,1101,115
1,1151,085
1,120
1,090
1,090
1,130
1,135
1,080
1,060
1,080
1,0501,040
1,100
T. 1 N.
T. 2 N.
R. 5 E.
R. 5 E.
T. 1 N.
T. 2 N.
GIS-TUC\366.1402\WL\2013\MAU_WLOct2013CAPTURE\18Feb2014
0 3,000
Feet
NORTH INDIAN BEND WASH AREAMARICOPA COUNTY, ARIZONA
ESTIMATED HYDRAULIC CAPTUREZONE OF MIDDLE ALLUVIUM UNIT
PLUME, OCTOBER 2013
FIGURE 19
EXPLANATIONPG-7MA
COS75ACOS74
SRP22.5E, 6N
!( Middle Alluvium Monitor Well Location and Identifier* Denotes the Well is a Lower MAU Well
Production Water Well Location and Identifier
COS69 ( Abandoned Production Water Well or Monitor Well Location and Identifier
? Extraction Water Well Location and Identifier!.
Groundwater Level Altitude Contour, in feet above mean sea level1,090
= Inactive Production Water Well Location and Identifier
Direction of Groundwater Movement
!.
!=
!=
!
!!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!
!!
!!
!
!
!
!.
!?
!?
!?
!?
!.
!(
!?
!?
!.
!.
!.
!.
!.
!=
!.
!? !?
!.
!?
!
!=
!.
!.
!.
!.
!.
!=
!.
!.
!=
!=
!.
!(
!( !(
!(
!(
!=
!.
!=
!.
!.
!.
!.
!=
!(
!.
!?
!?
!.
!=
!.
!?
!?
!
!
!.
!.
!.
!.
!.
Estimated Extent ofMiddle and LowerAlluvium Units
ARIZO
NACR
OSS
CUT
CANA
L
INDIAN
BEND
WASH
SALTRIVER
940
Scott
sdale
Roa
d
Thomas Road
McDonald Drive
Pima R
oad
Hayd
en R
oad
McDowell Road
McKellips Road
Chaparral Road
Indian School Road
Inverg
ordon
Roa
d
Indian Bend Road
960
995990
1,065
980970
1,075
1,080
955
1,070
1,060
1,055
950
1,0501,045
1,0401,035
1,025
945
1,0201,005
1,085
94094
5
985
975965
1,030
1,015
1,000
1,010
AVI
AWC8
MDWC
QRIA
IBGC
PCX-1COS 3
COS 4
COS 2
COT 6
AWC9A
COS 6
PV-12B
COS 31
COS 69
COS 70
COS 14
COS 78
COS 74
COS 72COS 71
COS 25
COS 11
AWC-8A
AWC-7A
SRIR-4
COS 76
COS 73
MEX-1MA
Laird 2
SRIR-10
COS 75A
AWC-12A
7EX-5MA
7EX-4MA
7EX-1UA
PG-41LA
SRIR-SCC
7EX-3aMA
SRP23.6E,6N
SRP22.4E,9N
SRP22.3E,7N
SRP21.5E,8N
SRP22.5E,6N
SRP22.6E,10N
SRP24E,10.5N
SRP22.5E,5.5N
SRP23.5E,8.8N
SRP23.5E,9.5N
SRP23.5E,5.3N
SRP23.5E,10.6N
SRP22.9E,10.8N
PV-17PV-16
PV-15
PV-14PV-11
11abb[Scottsdale Raddison]
COS 77
SRP22.1E,8.5N
SRP23E,10.8N[COS5W]
PV-12
SRP23.4E,10.6N[COS5E]
S-2LA
S-1LA
PG-2LA PG-1LA
PA-6LA
PA-5LAPA-13LA
M-9LA
M-5LA
M-2LA
E-7LA
PA-9LA
M-16LA
M-14LA
E-14LA
PA-8LA2
M-10LA2PG-39LA
PA-19LA
PA-18LA
PA-15LA
PA-11LA
M-17MA/LA
PG-38MA/LA
PG-23MA/LA
PA-2LA
PG-44LA
PG-43LAPG-42LA
PG-40LA
E-1LA
PA-22LAT. 1 N.
T. 2 N.
R. 4 E.
R. 4 E.
R. 5 E.
R. 5 E.
T. 1 N.
T. 2 N.
GIS-TUC\366.1402\WL\2013\LAU_WLOct2013_CAPTURE\18Feb2014
0 3,000
Feet
NORTH INDIAN BEND WASH AREAMARICOPA COUNTY, ARIZONA
ESTIMATED HYDRAULIC CAPTUREZONE OF LOWER ALLUVIUM UNIT
PLUME, OCTOBER 2013
FIGURE 20
EXPLANATIONPA-15LACOS75A
COS74
SRP22.5E, 6N
!( Lower Alluvium Monitor Well Location and Identifier
Production Water Well Location and Identifier
COS69 ( Abandoned Production Water Well orMonitor Well Location and Identifier
? Extraction Water Well Location and Identifier!.
Groundwater Level Altitude Contour, in feet above mean sea level1,090Direction of Groundwater Movement
= Inactive Production Water Well Location and Identifier
1999 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
END OF FIVE-YEAR AVERAGE RANGE
0
200
400
600
800
1,000
1,200
1,400
1,600
1,800A
VE
RA
GE
TC
E C
ON
CE
NT
RA
TIO
N, I
N M
ICR
OG
RA
MS
PE
R L
ITE
R
FIGURE 22. FIVE-YEAR RUNNING AVERAGE TCE CONCENTRATIONSUPPER MIDDLE ALLUVIUM UNIT VICINITY OF AREA 7
366\2013 Annual Report\Figure 23-Area7-5yr Ave TCE13 27Feb14
INCLUDES AVERAGE TCE CONCENTRATIONSFOR MONITOR WELLS D-2MA, E-10MA, PA-10MA,PA-12MA, W-1MA, AND W-2MA
START-UP O
F 7EX-3MA AND
7EX-4MA EXTRACTION W
ELLS
START-UP O
F 7EX-5MA
EXTRACTION W
ELL
AREA 7 GWETS
FULLY OPERATIO
NAL
Note: The requirement for computing and reporting a5-Year running average was initiated in 2004.
1998 1999 2000 2001 2002 2003 2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
END OF FIVE-YEAR AVERAGE RANGE
0
20
40
60
80
100
120
140
160
180A
VE
RA
GE
TC
E C
ON
CE
NT
RA
TIO
N, I
N M
ICR
OG
RA
MS
PE
R L
ITE
R
FIGURE 24. FIVE-YEAR RUNNING AVERAGE TCE CONCENTRATIONSUPPER MIDDLE ALLUVIUM UNIT, VICINITY OF AREA 12
366\2013 Annual Report\Figure 25-Area12-5yr Ave TCE13 14Jan14
INCLUDES AVERAGE TCE CONCENTRATIONSFOR MONITOR WELLS E-1MA, M-4MA, M-5MA,M-6MA, M-7MA, M-9MA, M-15MA, AND PA-21MA
START-UP OF MEX-1 AND SRPGRANITE REEF EXTRACTION WELLS
AREA 12 GWETSFULLY OPERATIONAL
Note: The requirement for computing and reporting a5-Year running average was initiated in 2004.
2,000,000
2,500,000
3,000,000
3,500,000
4,000,000
4,500,000
5,000,000
VO
LU
ME
, IN
TH
OU
SA
ND
GA
LL
ON
S
PCX-1 PV-15 PV-14 PV-11 PV-12 PV-12B PV-16 PV-17 SRP22.6E,10N
366\2013 Annual Report\Figure 26. PV Pumpage Dist13
0
500,000
1,000,000
1,500,000
, ,
AN
NU
AL
PU
MP
ING
V
FIGURE 26. DISTRIBUTION OF PUMPING IN VICINITY OF PV PUMPING CENTER
APPENDIX A
ROLES AND RESPONSIBILITIES FOR NIBW SUPERFUND SITE REMEDIAL ACTIONS
APPENDIX A
ROLES AND RESPONSIBILITIES FOR NIBW SUPERFUND SITE REMEDIAL ACTIONS
EPAREMEDIAL PROJECT MANAGER
Travis BarnumREMEDIAL PROJECT MANAGER
Rachel LoftinEPA RESPONSE ACTION CONTRACTOR
Larry Phillips, P.G.TECHNICAL SUPPORT
Ric Morgan
REMEDIATION PROGRAM MANAGERTerry Lockwood
REMEDIATION MANAGERSusan R. O’Connor
REMEDIATION MANAGERDoug Finan
NIBWParticipating Companies
City ofScottsdale
PROJECT COORDINATORDennis Shirley, P.G.
PROJECT ENGINEERJames Lutton, P.E.
PROJECT COORDINATORCraig Miller
PROJECT COORDINATORAndrea Martinez
SUPERVISING CONTRACTORANALYTICAL LABORATORY
Carlene McCutcheon
SUPERVISING CONTRACTORGROUNDWATER MONITORING PROGRAM
Chuck Gordon, P.G.WATERMASTER
Joshua Hand
CGTF
City ofScottsdale
AREA 7 GWETS COORDINATOR AREA 12 GWETS COORDINATOR MRTFNGTF
City ofScottsdale
Chris Whitmer Michael Nesky Larry Lynch Todd Farrell
• COS-31• COS-71• COS-72• COS-75A
• 7EX-1UA• 7EX-3aMA• 7EX-4MA• 7EX-5MA
• MEX-1• Granite Reef Well
• PV-15• PV-14
• PCX-1
Chris Whitmer
CONTACTS LIST AND KEY ROLES
Site Wide Operation and Maintenance Plan
NIBW Participating Companies Agency
Motorola Project Manager
Terry Lockwood Motorola Solutions, Inc. 2900 South Diablo Way Building A, Suite 150 Tempe, AZ 85282 602-760-4763 office 602-617-8563 mobile 602-760-5151 fax
EPA Remedial Project Manager
Rachel Loftin, Region IX (SFD-6-2) U.S. Environmental Protection Agency 75 Hawthorne Street San Francisco, CA 94105-3901 415-972-3253 phone 415-947-3528 fax [email protected]
NIBW Project Coordinator
Dennis Shirley, P.G. 10645 North Tatum Blvd. Suite 200 – 437 Phoenix, AZ 85028-3053 602-852-9455 home 602-319-2977 mobile
ADEQ Project Manager
Travis Barnum Arizona Department of Environmental Quality 1110 West Washington Street Phoenix, AZ 85007 602-771-4196 phone 602-771-4272 fax [email protected]
NIBW Project Engineer
James Lutton, P.E. 4756 Brand Way Sacramento, CA 95819 916-452-4684 office 916-698-2726 cell [email protected]
AREA 7 KEY ROLES
Site Project Manager
Terry Lockwood Motorola Solutions, Inc. 2900 South Diablo Way Building A, Suite 150 Tempe, AZ 85282 602-760-4763 office 602-617-8563 mobile 602-760-5151 fax [email protected]
Incident Coordinator
Michael Nesky, P.E. ARCADIS U.S., Inc. 14201 North 87th Street, Suite 135 Scottsdale, Arizona 85260 480-905-9311 office 480-905-9353 fax [email protected]
Treatment System Coordinator
Ryan O’Keefe ARCADIS U.S., Inc. 14201 North 87th Street, Suite 135 Scottsdale, Arizona 85260 480-905-9311 office 602-295-6708 mobile 480-905-9353 fax [email protected]
AREA 12 KEY ROLES
Site Project Manager
Terry Lockwood Motorola Solutions, Inc. 2900 South Diablo Way Building A, Suite 150 Tempe, AZ 85282 602-760-4763 office 602-617-8563 mobile 602-760-5151 fax [email protected]
Incident Coordinator
Larry Lynch, P.E. EnSolutions, Inc. 7620 East McKellips Road, Suite 4-71 Scottsdale, AZ 85257 561-762-7690 mobile [email protected]
Treatment System Coordinator
Larry Lynch, P.E. EnSolutions, Inc. 7620 East McKellips Road, Suite 4-71 Scottsdale, AZ 85257 561-762-7690 mobile [email protected]
MILLER ROAD TREATMENT FACILITY KEY ROLES
MRTF Operations Manager
Paul Cornejo EPCOR 6215 North Cattletrack Road Scottsdale, AZ 85250 623-445-2403 phone 928-600-1240 mobile [email protected]
NIBW Program Manager
Terry Lockwood Motorola Solutions, Inc. 2900 South Diablo Way Building A, Suite 150 Tempe, AZ 85282 602-760-4763 office 602-617-8563 mobile 602-760-5151 fax [email protected]
EPCOR Incident Coordinator
Paul Cornejo EPCOR 6215 North Cattletrack Road Scottsdale, AZ 85250 623-445-2403 phone 928-600-1240 mobile [email protected]
NIBW PC’s Incident Coordinator
Larry Lynch EnSolutions. Inc. 7620 East McKellips Road, Suite 4-71 Scottsdale, AZ 85257 561-762-7690 mobile [email protected]
MRTF Coordinator
Todd Farrell EPCOR 6215 North Cattletrack Road Scottsdale, AZ 85250 602-388-7170 mobile [email protected]
CENTRAL GROUNDWATER TREATMENT FACILITY KEY ROLES
Project Coordinator
Craig Miller City of Scottsdale 8787 East Hualapai Drive P.O. Box 25089 Scottsdale, AZ 85255 480-312-8743 phone 480-312-8728 fax [email protected]
Emergency Response Coordinator Priority List During Normal Business Hours: 1. Chris Whitmer, CGTF Senior Operator Phone: 480-312-0390 Mobile: 602-402-3223 2. Senior Operator on staff Pager: 602-238-0278 3. Brian Paulson, Treatment Manager
Phone: 480-312-8722 Mobile: 602-319-2931
After Hours: 1. Chris Whitmer, CGTF Senior Operator Mobile: 602-402-3223 2. Senior Operator on staff Mobile: 480-341-4629 Pager: 602-238-0278 3. Water Production Operator on call Mobile: 602-309-1743 Pager: 602-223-0481 4. Telemetry Pager Pager: 602-223-4812 5. Water Distribution on call Pager: 602-229-3677 6. Brian Paulson, Treatment Manager
Mobile: 602-319-2931 COS Regulatory Contact List:
A.) Craig Miller, COS Water Quality Coordinator 480-312-8743 office, business hours 480-329-8902 mobile, after hours
B.) Carie Wilson, COS Regulatory Compliance Manager 480-312-8718 office, business hours 602-499-7942 mobile, after hours
C.) Suzanne Grendahl, Water Quality Director 480-312-8719 office, business hours
623-640-1474 mobile, after hours
NIBW GAC TREATMENT FACILITY KEY ROLES
Site Project Manager
Terry Lockwood Motorola Solutions, Inc. 2900 South Diablo Way Building A, Suite 150 Tempe, AZ 85282 602-760-4763 office 602-617-8563 cell 602-760-5151 fax [email protected]
NIBW PC’s Incident Coordinator
Larry Lynch EnSolutions. Inc. 7620 East McKellips Road, Suite 4-71 Scottsdale, AZ 85257 561-762-7690 mobile
NGTF Operator:
1. Chris Whitmer, CGTF Senior Operator Phone: 480-312-0390 Mobile: 602-402-3223 2. Senior Operator on staff Pager: 602-238-0278
GROUNDWATER MONITORING AND EXTRACTION WELL
FIELD SERVICES KEY ROLES
Site Project Manager
Terry Lockwood Motorola Solutions, Inc. 2900 South Diablo Way Building A, Suite 150 Tempe, AZ 85282 602-760-4763 office 602-617-8563 cell 602-760-5151 fax [email protected]
Field Services Contractor, Project Manager
Chuck Gordon, P.G. Terranext 4050 East Cotton Center Boulevard Suite 73 Phoenix, AZ 85040 480-496-4100 phone [email protected]
PHASE 2 SAMPLING AND ANALYSIS PLAN KEY ROLES
NIBW Project Coordinator
Dennis Shirley, P.G. 10645 North Tatum Blvd. Suite 200 – 437 Phoenix, AZ 85028-3053 602-852-9455 home 602-319-2977 cell
NIBW PCs QA Officer
James Lutton, P.E. 4756 Brand Way Sacramento, CA 95819 916-452-4684 phone 916-698-2726 cell
Samplers
Central Groundwater Treatment Facility Tom Byers City of Scottsdale Miller Road Treatment Facility Larry Lynch, P.E. EnSolutions Area 7 GWETS Michael Nesky, P.E. ARCADIS U.S., Inc. Area 12 GWETS Larry Lynch, P.E. EnSolutions
COS QA Officer
Gail Adams City Of Scottsdale 8787 E. Hualapai Drive Scottsdale, AZ 85255 480-312-8744 phone 480-312-8728 fax
Data Quality Control Officer
Carlene McCutcheon Test America 4645 E. Cotton Center Blvd. Building 3, Suite 189 Phoenix, AZ 85040
602-437-3340 phone 602-454-9303 fax
NIBW PARTICIPATING COMPANIES CONTACT LIST AND KEY ROLES
Call-Out for any Reported Release of Untreated Groundwater at:
SRP 22.5E-9.3N (PCX-1) SRP 23.3E-7.3N (COS-31)
SRP 23.6E-6N (Granite Reef)
1) NIBW Project Coordinator
Dennis Shirley, P.G. 10645 North Tatum Blvd. Suite 200 – 437 Phoenix, AZ 85028-3053 602-852-9455 home 602-319-2977 cell [email protected]
2) NIBW Project Engineer
James Lutton, P.E. 4756 Brand Way Sacramento, CA 95819 916-452-4684 office 916-698-2726 cell [email protected]
3) Motorola Project Manager
Terry Lockwood Motorola Solutions, Inc. 2900 South Diablo Way Building A, Suite 150 Tempe, AZ 85282 602-760-4763 office 602-617-8563 cell 602-760-5151 fax [email protected]
APPENDIX B
NORTHERN LAU CONTINUOUS WATER LEVEL MONITORING GRAPHS, 2013
2013
880
900
920
940
960
980
1,000G
RO
UN
DW
AT
ER
LE
VE
L A
LTIT
UD
E, i
n fe
et a
bove
mea
n se
a le
vel
Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec
FIGURE B-1. GROUNDWATER LEVEL HYDROGRAPH FOR EXTRACTION WELL PV-14
366.2\Hydrographs\Appendix B\2013 PV14.grf
Note: 1) Higher water levels are representative of non-pumping conditions;lower water levels are representative of pumping conditions..
EXPLANATION
PRESSURE TRANSDUCERWATER LEVEL MEASUREMENT
ELECTRIC SOUNDERWATER LEVEL MEASUREMENT
2013
880
900
920
940
960
980
1,000G
RO
UN
DW
AT
ER
LE
VE
L A
LTIT
UD
E, i
n fe
et a
bove
mea
n se
a le
vel
Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec
FIGURE B-2. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL PG-1LA
P:\366.2\Hydrographs\Appendix B\2013 PG-1LA.grf
EXPLANATION
PRESSURE TRANSDUCERWATER LEVEL MEASUREMENT
ELECTRIC SOUNDERWATER LEVEL MEASUREMENT
2013
880
900
920
940
960
980
1,000G
RO
UN
DW
AT
ER
LE
VE
L A
LTIT
UD
E, i
n fe
et a
bove
mea
n se
a le
vel
Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec
FIGURE B-3. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL PG-2LA
P:\366.2\Hydrographs\Appendix B\2013 PG-2LA.grf
EXPLANATION
PRESSURE TRANSDUCERWATER LEVEL MEASUREMENT
ELECTRIC SOUNDERWATER LEVEL MEASUREMENT
2013
880
900
920
940
960
980
1,000G
RO
UN
DW
AT
ER
LE
VE
L A
LTIT
UD
E, i
n fe
et a
bove
mea
n se
a le
vel
Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec
FIGURE B-4. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL PG-40LA
P:\366.2\Hydrographs\Appendix B\2013 PG-40LA.grf
EXPLANATION
PRESSURE TRANSDUCERWATER LEVEL MEASUREMENT
ELECTRIC SOUNDERWATER LEVEL MEASUREMENT
2013
880
900
920
940
960
980
1,000G
RO
UN
DW
AT
ER
LE
VE
L A
LTIT
UD
E, i
n fe
et a
bove
mea
n se
a le
vel
Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec
FIGURE B-5. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL PG-42LA
P:\366.2\Hydrographs\Appendix B\2013 PG-42LA.grf
EXPLANATION
PRESSURE TRANSDUCERWATER LEVEL MEASUREMENT
ELECTRIC SOUNDERWATER LEVEL MEASUREMENT
2013
880
900
920
940
960
980
1,000
GR
OU
ND
WA
TE
R L
EV
EL
ALT
ITU
DE
, in
feet
abo
ve m
ean
sea
leve
l
Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec
FIGURE B-6. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL PG-43LA
P:\366.2\Hydrographs\Appendix B\2013 PG-43LA.grf
EXPLANATION
PRESSURE TRANSDUCERWATER LEVEL MEASUREMENT
ELECTRIC SOUNDERWATER LEVEL MEASUREMENT
2013
880
900
920
940
960
980
1,000
GR
OU
ND
WA
TE
R L
EV
EL
ALT
ITU
DE
, in
feet
abo
ve m
ean
sea
leve
l
Jan Feb Mar Apr May Jun Jul Aug Sep Oct Nov Dec
FIGURE B-7. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL PG-44LA
P:\366.2\Hydrographs\Appendix B\2013 PG-44LA.grf
EXPLANATION
PRESSURE TRANSDUCERWATER LEVEL MEASUREMENT
ELECTRIC SOUNDERWATER LEVEL MEASUREMENT
APPENDIX C
WATER LEVEL HYDROGRAPHS AND TCE TIME-SERIES DATA FOR NIBW MONITOR, PRODUCTION AND EXTRACTION WELLS
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
TCE
FIGURE C-1. TCE CONCENTRATIONS FOR EXTRACTION WELL 7EX-1UA
P:\366.2\Hydrographs\2013\7EX-1UA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
0
400
800
1,200
1,600
2,000
2,400
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
TCE
FIGURE C-2. TCE CONCENTRATIONS FOR EXTRACTION WELL 7EX-3aMA
P:\366.2\Hydrographs\2013\7EX-3aMA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
0
400
800
1,200
1,600
2,000
2,400
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
TCE
FIGURE C-3. TCE CONCENTRATIONS FOR EXTRACTION WELL 7EX-4MA
P:\366.2\Hydrographs\2013\7EX-4MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
1,000
1,030
1,060
1,090
1,120
1,150
1,180
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
400
800
1,200
1,600
2,000
2,400
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
TCE
FIGURE C-4. TCE CONCENTRATIONS FOR EXTRACTION WELL 7EX-5MA
P:\366\2013 Annual Report\7EX-5MA_10yr.grf
WL
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-5. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL B-1MA
P:\366.2\Hydrographs\2013\B-1MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
980
1,010
1,040
1,070
1,100
1,130
1,160
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-6. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL B-1UA
P:\366.2\Hydrographs\2013\B-1UA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
980
1,010
1,040
1,070
1,100
1,130
1,160
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-7. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL B-3UA
P:\366.2\Hydrographs\2013\B-3UA 10yr.grf
Note: B-3UA was officially abandoned on January 9, 2014.
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
1,000
1,030
1,060
1,090
1,120
1,150
1,180
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-8. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL B-J
P:\366.2\Hydrographs\2013\B-J 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
TCE
FIGURE C-9. TCE CONCENTRATIONS FOR EXTRACTION WELL COS-31
P:\366.2\Hydrographs\2013\COS-31 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
0
50
100
150
200
250
300
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
TCE
FIGURE C-10. TCE CONCENTRATIONS FOR EXTRACTION WELL COS-71
P:\366.2\Hydrographs\2013\COS-71 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
TCE
FIGURE C-11. TCE CONCENTRATIONS FOR EXTRACTION WELL COS-72
P:\366.2\Hydrographs\2013\COS-72 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
0
50
100
150
200
250
300
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
TCE
FIGURE C-12. TCE CONCENTRATIONS FOR EXTRACTION WELL COS-75A
P:\366.2\Hydrographs\2013\COS-75A 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
1,000
1,030
1,060
1,090
1,120
1,150
1,180
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-13. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL D-1UA
P:\366.2\Hydrographs\2013\D-1UA 10yr.grf
Note: D-1UA was officially abandoned on October 9, 2013.
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
400
800
1,200
1,600
2,000
2,400
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-14. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL D-2MA
P:\366.2\Hydrographs\2013\D-2MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
920
950
980
1,010
1,040
1,070
1,100
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-15. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL E-1LA
P:\366.2\Hydrographs\2013\E-1LA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
950
980
1,010
1,040
1,070
1,100
1,130
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
50
100
150
200
250
300
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-16. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL E-1MA
P:\366.2\Hydrographs\2013\E-1MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
980
1,010
1,040
1,070
1,100
1,130
1,160
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-17. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL E-1UA
P:\366.2\Hydrographs\2013\E-1UA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
980
1,010
1,040
1,070
1,100
1,130
1,160
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-18. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL E-2UA
P:\366.2\Hydrographs\2013\E-2UA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
980
1,010
1,040
1,070
1,100
1,130
1,160
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-19. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL E-3UA
P:\366.2\Hydrographs\2013\E-3UA 10yr.grf
Note: E-3UA was officially abandoned on August 29, 2013.
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
980
1,010
1,040
1,070
1,100
1,130
1,160
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-20. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL E-4UA
P:\366.2\Hydrographs\2013\E-4UA 10yr.grf
Note: E-4UA was officially abandoned on September 5, 2013.
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
950
980
1,010
1,040
1,070
1,100
1,130
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
50
100
150
200
250
300
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-21. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL E-5MA
P:\366.2\Hydrographs\2013\E-5MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
1,000
1,030
1,060
1,090
1,120
1,150
1,180
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-22. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL E-5UA
P:\366.2\Hydrographs\2013\E-5UA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
980
1,010
1,040
1,070
1,100
1,130
1,160
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-23. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL E-6UA
P:\366.2\Hydrographs\2013\E-6UA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
920
950
980
1,010
1,040
1,070
1,100
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-24. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL E-7LA
P:\366.2\Hydrographs\2013\E-7LA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
1,000
1,030
1,060
1,090
1,120
1,150
1,180
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-25. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL E-7UA
P:\366.2\Hydrographs\2013\E-7UA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-26. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL E-8MA
P:\366.2\Hydrographs\2013\E-8MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
1,000
1,030
1,060
1,090
1,120
1,150
1,180
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-27. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL E-9UA
P:\366.2\Hydrographs\2013\E-9UA 10yr.grf
Note: E-9UA was officially abandoned on August 2, 2013.
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-28. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL E-10MA
P:\366.2\Hydrographs\2013\E-10MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
1,000
1,030
1,060
1,090
1,120
1,150
1,180
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-29. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL E-12UA
P:\366.2\Hydrographs\2013\E-12UA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
1,000
1,030
1,060
1,090
1,120
1,150
1,180
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-30. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL E-13UA
P:\366.2\Hydrographs\2013\E-13UA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
920
950
980
1,010
1,040
1,070
1,100
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-31. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL E-14LA
P:\366.2\Hydrographs\2013\E-14LA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-32. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL M-1MA
P:\366.2\Hydrographs\2013\M-1MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
920
950
980
1,010
1,040
1,070
1,100
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-33. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL M-2LA
P:\366.2\Hydrographs\2013\M-2LA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-34. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL M-2MA
P:\366.2\Hydrographs\2013\M-2MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
1,000
1,030
1,060
1,090
1,120
1,150
1,180
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-35. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL M-2UA
P:\366.2\Hydrographs\2013\M-2UA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL) WL
FIGURE C-36. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL M-3MA
P:\366.2\Hydrographs\2013\M-3MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
980
1,010
1,040
1,070
1,100
1,130
1,160
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-37. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL M-3UA
P:\366.\2\Hydrographs\2013\M-3UA 10yr.grf
Note: M-3UA was officially abandoned on October 10, 2013.
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
950
980
1,010
1,040
1,070
1,100
1,130
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)WL
TCE
FIGURE C-38. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL M-4MA
P:\366.2\Hydrographs\2013\M-4MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
980
1,010
1,040
1,070
1,100
1,130
1,160
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-39. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL M-4UA
P:\366.2\Hydrographs\2013\M-4UA 10yr.grf
Note: M-4UA was officially abandoned on October 14, 2013.
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
910
940
970
1,000
1,030
1,060
1,090
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-40. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL M-5LA
P:\366.2\Hydrographs\2013\M-5LA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
950
980
1,010
1,040
1,070
1,100
1,130
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
50
100
150
200
250
300
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-41. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL M-5MA
P:\366.2/\Hydrographs\2013\M-5MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
980
1,010
1,040
1,070
1,100
1,130
1,160
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-42. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL M-5UA
P:\366.2\Hydrographs\2013\M-5UA 10yr.grf
Note: Obstruction in pipe beginning October 2011.M-5UA was officially abandoned on October 10, 2013.
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
970
1,000
1,030
1,060
1,090
1,120
1,150
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
50
100
150
200
250
300
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-43. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL M-6MA
P:\366.2\Hydrographs\2013\M-6MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-44. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL M-7MA
P:\366.2\Hydrographs\2013\M-7MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
920
950
980
1,010
1,040
1,070
1,100
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-45. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL M-9LA
P:\366.2\Hydrographs\2013\M-9LA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-45. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL M-9MA
P:\366.2\Hydrographs\2013\M-9MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
980
1,010
1,040
1,070
1,100
1,130
1,160
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-46. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL M-9UA
P:\366.2\Hydrographs\2013\M-9UA 10yr.grf
Note: M-9UA was officially abandoned on October 31, 2013.
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
920
950
980
1,010
1,040
1,070
1,100
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-47. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL M-10LA2
P:\366.2\Hydrographs\2013\M-10LA2 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
950
980
1,010
1,040
1,070
1,100
1,130
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)WL
TCE
FIGURE C-48. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL M-10MA2
P:\366.2\Hydrographs\2013\M-10MA2 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-49. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL M-11MA
P:\366.2\Hydrographs\2013\M-11MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
980
1,010
1,040
1,070
1,100
1,130
1,160
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL) WL
FIGURE C-50. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL M-11UA
P:\366.2\Hydrographs\2013\M-11UA 10yr.grf
Note: M-11UA was officially abandoned on October 18, 2013.
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
950
980
1,010
1,040
1,070
1,100
1,130
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)WL
TCE
FIGURE C-51. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL M-12MA2
P:\366.2\Hydrographs\2013\M-12MA2 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
920
950
980
1,010
1,040
1,070
1,100
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)WL
TCE
FIGURE C-52. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL M-14LA
P:\366.2\Hydrographs\2013\M-14LA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-53. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL M-14MA
P:\366.2\Hydrographs\2013\M-14MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
950
980
1,010
1,040
1,070
1,100
1,130
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-54. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL M-15MA
P:\366.2\Hydrographs\2013\M-15MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
980
1,010
1,040
1,070
1,100
1,130
1,160
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-55. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL M-15UA
P:\366.2\Hydrographs\2013\M-15UA 10yr.grf
Note: M-15UA was officially abandoned on October 16, 2013.
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
920
950
980
1,010
1,040
1,070
1,100
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-56. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL M-16LA
P:\366.2\Hydrographs\2013\M-16LA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-57. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL M-16MA
P:\366.2\Hydrographs\M-16MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
980
1,010
1,040
1,070
1,100
1,130
1,160
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-58. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL M-16UA
P:\366.2\Hydrographs\2013\M-6UA 10yr.grf
Note: M-16UA was officially abandoned on October 17, 2013.
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
920
950
980
1,010
1,040
1,070
1,100
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
50
100
150
200
250
300
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-59. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL M-17MA/LA
P:\366.2\Hydrographs\2013\M-17MA/LA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
0
50
100
150
200
250
300
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
TCE
FIGURE C-60. TCE CONCENTRATIONS FOR EXTRACTION WELL MEX-1MA
P:\366.2\Hydrographs\2013\MEX-1MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-61. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL PA-1MA
P:\366.2\Hydrographs\2013\PA-1MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
810
840
870
900
930
960
990
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-62. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PA-2LA
P:\366.2\Hydrographs\2013\PA-2LA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
980
1,010
1,040
1,070
1,100
1,130
1,160
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-63. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL PA-3MA
P:\366.2\Hydrographs\2013\PA-3MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-64. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL PA-4MA
P:\366.2\Hydrographs\2013\PA-4MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
820
850
880
910
940
970
1,000
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
50
100
150
200
250
300
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-65. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PA-5LA
P:\366.2\Hydrographs\2013\PA-5LA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
810
840
870
900
930
960
990
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
50
100
150
200
250
300
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-66. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PA-6LA
P:\366.2\Hydrographs\2013\PA-6LA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-67. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL PA-7MA
P:\366.2\Hydrographs\2013\PA-7MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
880
910
940
970
1,000
1,030
1,060
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-68. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PA-8LA2
P:\366.2\Hydrographs\2013\PA-8LA2 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
880
910
940
970
1,000
1,030
1,060
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-69. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PA-9LA
P:\366.2\Hydrographs\2013\PA-9LA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
950
980
1,010
1,040
1,070
1,100
1,130
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)WL
TCE
FIGURE C-70. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PA-10MA
P:\366.2\Hydrographs\2013\PA-10MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
920
950
980
1,010
1,040
1,070
1,100
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)WL
TCE
FIGURE C-72. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PA-11LA
P:\366.2\Hydrographs\2013\PA-11LA 10yr.grf
Note: Water level collected from LAU completed well at piezometer PA-11/12located approximately 80 feet northwest of original well PA-11LA.
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
920
950
980
1,010
1,040
1,070
1,100
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
400
800
1,200
1,600
2,000
2,400
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-73. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PA-12MA
P:\366.2\Hydrographs\2013\PA-12MA 10yr.grf
Note: Water level collected from MAU completed well at piezometer PA-11/12located approximately 70 feet northwest of original well PA-12MA.
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
820
850
880
910
940
970
1,000
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
50
100
150
200
250
300
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-73. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PA-13LA
P:\366.2\Hydrographs\2013\PA-13LA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-74. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL PA-14MA
P:\366.2\Hydrographs\2013\PA-14MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-75. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PA-15LA
P:\366.2\Hydrographs\2013\PA-15LA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-76. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PA-16MA
P:\366.2\Hydrographs\2013\PA-16MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL) WL
FIGURE C-77. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL PA-17MA
P:\366.2\Hydrographs\2013\PA-17MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
880
910
940
970
1,000
1,030
1,060
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-78. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PA-18LA
P:\366.2\Hydrographs\2013\PA-18LA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
950
980
1,010
1,040
1,070
1,100
1,130
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
50
100
150
200
250
300
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-80. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PA-19LA
P:\366.2\Hydrographs\2013\PA-19LA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
950
980
1,010
1,040
1,070
1,100
1,130
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
50
100
150
200
250
300
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-81. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PA-20MA
P:\366.2\Hydrographs\2013\PA-20MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-81. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PA-21MA
P:\366.2\Hydrographs\2013\PA-21MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-82. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL PA-22LA
P:\366.2\Hydrographs\2013\PA-22LA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-83. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL PA-23MA
P:\366.2\Hydrographs\2013\PA-23MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
0
50
100
150
200
250
300
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
TCE
FIGURE C-84. TCE CONCENTRATIONS FOR EXTRACTION WELL PCX-1
P:\366.2\Hydrographs\2013\PCX-1 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
810
840
870
900
930
960
990
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-85. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-1LA
P:\366.2\Hydrographs\2013\PG-1LA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
810
840
870
900
930
960
990
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
50
100
150
200
250
300
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-86. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-2LA
P:\366.2\Hydrographs\2013\PG-2LA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
1,000
1,030
1,060
1,090
1,120
1,150
1,180
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-87. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-3UA
P:\366.2\Hydrographs\2013\PG-3UA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
950
980
1,010
1,040
1,070
1,100
1,130
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-88. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-4MA
P:\366.2\Hydrographs\2013\PG-4MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
1,000
1,030
1,060
1,090
1,120
1,150
1,180
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-89. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-4UA
P:\366.2\Hydrographs\2013\PG-4UA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-90. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-5MA
P:\366.2\Hydrographs\2013\PG-5MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
1,000
1,030
1,060
1,090
1,120
1,150
1,180
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-91. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-5UA
P:\366.2\Hydrographs\2013\PG-5UA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
50
100
150
200
250
300
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-92. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-6MA
P:\366.2\Hydrographs\2013\PG-6MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
1,000
1,030
1,060
1,090
1,120
1,150
1,180
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-93. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-6UA
P:\366.2\Hydrographs\2013\PG-6UA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-94. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-7MA
P:\366.2\Hydrographs\2013\PG-7MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-95. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL PG-7UA
P:\366.2\Hydrographs\2013\PG-7UA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
1,000
1,030
1,060
1,090
1,120
1,150
1,180
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-96. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-8UA
P:\366.2\Hydrographs\2013\PG-8UA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
1,000
1,030
1,060
1,090
1,120
1,150
1,180
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-97. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-9UA
P:\366.2\Hydrographs\2013\PG-9UA 10yr.grf
Note: PG-9UA was officially abandoned on October 9, 2013.
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
1,030
1,060
1,090
1,120
1,150
1,180
1,210
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-98. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-10UA
P:\366.2\Hydrographs\2013\PG-10UA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
1,000
1,030
1,060
1,090
1,120
1,150
1,180
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-99. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-11UA
P:\366.2\Hydrographs\2013\PG-11UA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
980
1,010
1,040
1,070
1,100
1,130
1,160
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-100. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL PG-12UA
P:\366.2\Hydrographs\2013\PG-12UA 10yr.grf
Note: PG-12UA was officially abandoned on October 15, 2013.
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
980
1,010
1,040
1,070
1,100
1,130
1,160
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL) WL
FIGURE C-101. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL PG-13UA
P:\366.2\Hydrographs\2013\PG-13UA 10yr.grf
Note: PG-13UA was officially abandoned on September 6, 2013.
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
1,000
1,030
1,060
1,090
1,120
1,150
1,180
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-102. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-15UA
P:\366.2\Hydrographs\2013\PG-15UA 10yr.grf
Note: PG-15UA was officially abandoned on October 22, 2013.
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
1,000
1,030
1,060
1,090
1,120
1,150
1,180
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-103. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-16UA
P:\366.2\Hydrographs\2013\PG-16UA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
980
1,010
1,040
1,070
1,100
1,130
1,160
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-104. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL PG-17UA
P:\366.2\Hydrographs\2013\PG-17UA 10yr.grf
Note: PG-17UA was officially abandoned on August 30, 2013.
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
1,000
1,030
1,060
1,090
1,120
1,150
1,180
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-105. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-18UA
P:\366.2\Hydrographs\2013\PG-18UA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
1,000
1,030
1,060
1,090
1,120
1,150
1,180
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-106. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-19UA
P:\366.2\Hydrographs\2013\PG-19UA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
980
1,010
1,040
1,070
1,100
1,130
1,160
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-107. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-20UA
P:\366.2\Hydrographs\2013\PG-20UA 10yr.grf
Note: PG-20UA was officially abandoned on October 7, 2013.
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
980
1,010
1,040
1,070
1,100
1,130
1,160
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-108. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL PG-21UA
P:\366.2\Hydrographs\2013\PG-21UA 10yr.grf
Note: PG-21UA was officially abandoned on September 5, 2013.
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
1,000
1,030
1,060
1,090
1,120
1,150
1,180
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-110. WATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-22UA
P:\366.2\Hydrographs\2013\PG-22UA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-111. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-23MA/LA
P:\366.2\Hydrographs\2013\PG-23MA/LA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
1,000
1,030
1,060
1,090
1,120
1,150
1,180
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-111. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-23UA
P:\366.2\Hydrographs\2013\PG-23UA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
1,000
1,030
1,060
1,090
1,120
1,150
1,180
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-112. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-24UA
P:\366.2\Hydrographs\2013\PG-24UA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
1,000
1,030
1,060
1,090
1,120
1,150
1,180
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)WL
TCE
FIGURE C-113. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-25UA
P:\366.2\Hydrographs\2013\PG-25UA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
980
1,010
1,040
1,070
1,100
1,130
1,160
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-114. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-26UA
P:\366.2\Hydrographs\2013\PG-26UA 10yr.grf
Note: PG-26UA was officially abandoned on October 8, 2013.
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
980
1,010
1,040
1,070
1,100
1,130
1,160
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL) WL
FIGURE C-115. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL PG-27UA
P:\366.2\Hydrographs\2013\PG-27UA 10yr.grf
Note: PG-27UA was officially abandoned on August 30, 2013.
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
1,000
1,030
1,060
1,090
1,120
1,150
1,180
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-116. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-28UA
P:\366.2\Hydrographs\2013\PG-28UA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
1,000
1,030
1,060
1,090
1,120
1,150
1,180
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-117. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-29UA
P:\366.2\Hydrographs\2013\PG-29UA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
980
1,010
1,040
1,070
1,100
1,130
1,160
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL) WL
FIGURE C-118. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL PG-30UA
P:\366.2\Hydrographs\2013\PG-30UA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
1,000
1,030
1,060
1,090
1,120
1,150
1,180
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
50
100
150
200
250
300
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-119. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-31UA
P:\366.2\Hydrographs\2013\PG-31UA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
980
1,010
1,040
1,070
1,100
1,130
1,160
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-120. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL PG-32UA
P:\366.2\Hydrographs\2013\PG-32UA 10yr.grf
Note: PG-32UA was officially abandoned on September 3, 2013.
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
980
1,010
1,040
1,070
1,100
1,130
1,160
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)WL
TCE
FIGURE C-121. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-33UA
P:\366.2\Hydrographs\2013\PG-33UA 10yr.grf
Note: PG-33UA was officially abandoned on September 4, 2013.
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
980
1,010
1,040
1,070
1,100
1,130
1,160
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-122. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL PG-34UA
P:\366.2\Hydrographs\2013\PG-34UA 10yr.grf
Note: PG-34UA was officially abandoned on September 4, 2013.
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-124. WATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-35UA
P:\366.2\Hydrographs\2013\PG-35UA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
1,000
1,030
1,060
1,090
1,120
1,150
1,180
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-124. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-36UA
P:\366.2\Hydrographs\2013\PG-36UA 10yr.grf
Note: PG-36UA was officially abandoned on October 8, 2013.
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
950
980
1,010
1,040
1,070
1,100
1,130
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)WL
TCE
FIGURE C-125. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-37UA
P:\366.2\Hydrographs\2013\PG-37UA 10yr.grf
Note: PG-37UA was officially abandoned on October 29, 2013.
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)WL
TCE
FIGURE C-126. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-38MA/LA
P:\366.2\Hydrographs\2013\PG-38MA/LA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-128. WATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-38UA
P:\366.2\Hydrographs\2013\PG-38UA 10yr.grf
Note: PG-38UA was officially abandoned on October 29, 2013.
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
950
980
1,010
1,040
1,070
1,100
1,130
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-128. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-39LA
P:\366.2\Hydrographs\2013\PG-39LA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL) WL
FIGURE C-129. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL PG-39UA
P:\366.2\Hydrographs\2013\PG-39UA 10yr.grf
Note: PG-39UA was officially abandoned on October 29, 2013.
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
810
840
870
900
930
960
990
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-130. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-40LA
P:\366.2\Hydrographs\2013\PG-40LA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
810
840
870
900
930
960
990
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-131. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-42LA
P:\366.2\Hydrographs\2013\PG-42LA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
810
840
870
900
930
960
990
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-132. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-43LA
P:\366.2\Hydrographs\2013\PG-43LA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
810
840
870
900
930
960
990
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-133. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-44LA
P:\366.2\Hydrographs\2013\PG-44LA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-134. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL PG-47MA
P:\366.2\Hydrographs\2013\PG-47MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
950
980
1,010
1,040
1,070
1,100
1,130
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
50
100
150
200
250
300
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-135. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-48MA
P:\366.2\Hydrographs\2013\PG-48MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
TCE
FIGURE C-136. TCE CONCENTRATIONS FOR MONITOR WELL PG-49MA
P:\366.2\Hydrographs\2013\PG-49MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-137. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL PG-50MA
P:\366.2\Hydrographs\2013\PG-50MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
WL
FIGURE C-138. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL PG-51MA
P:\366.2\Hydrographs\2013\PG-51MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
TCE
FIGURE C-139. TCE CONCENTRATIONS FOR MONITOR WELL PG-54MA
P:\366.2\Hydrographs\2013\PG-54MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
TCE
FIGURE C-140. TCE CONCENTRATIONS FOR MONITOR WELL PG-55MA
P:\366.2\Hydrographs\2013\PG-55MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
TCE
FIGURE C-141. TCE CONCENTRATIONS FOR MONITOR WELL PG-56MA
P:\366.2\Hydrographs\2013\PG-56MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL) WL
FIGURE C-142. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL PG-57MA
P:\366.2\Hydrographs\2013\PG-57MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
TCE
FIGURE C-143. TCE CONCENTRATIONS FOR PRODUCTION WELL PV-11
P:\366.2\Hydrographs\2013\PV-11 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
TCE
FIGURE C-144. TCE CONCENTRATIONS FOR PRODUCTION WELL PV-12B
P:\366.2\Hydrographs\2013\PV-12B 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
TCE
FIGURE C-145. TCE CONCENTRATIONS FOR PRODUCTION WELL PV-14
P:\366.2\Hydrographs\2013\PV-14 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
TCE
FIGURE C-146. TCE CONCENTRATIONS FOR PRODUCTION WELL PV-15
P:\366.2\Hydrographs\2013\PV-15 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
840
870
900
930
960
990
1,020
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)WL
TCE
FIGURE C-147. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL S-1LA
P:\366.2\Hydrographs\2013\S-1LA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)WL
TCE
FIGURE C-148. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL S-1MA
P:\366.2\Hydrographs\2013\S-1MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
810
840
870
900
930
960
990
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-149. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL S-2LA
P:\366.2\Hydrographs\2013\S-2LA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
960
990
1,020
1,050
1,080
1,110
1,140
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)WL
TCE
FIGURE C-150. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL S-2MA
P:\366.2\Hydrographs\2013\S-2MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
0
50
100
150
200
250
300
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
TCE
FIGURE C-151. TCE CONCENTRATIONS FOR EXTRACTION WELL SRP23.6E6N
P:\366.2\Hydrographs\2013\SRP23.6E6N 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
980
1,010
1,040
1,070
1,100
1,130
1,160
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
FIGURE C-152. GROUNDWATER LEVEL HYDROGRAPH FOR MONITOR WELL ST-1UA
P:\366.2\Hydrographs\2013\ST-1UA 10yr.grf
Note: ST-1UA was officially abandoned on October 18, 2013.
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
980
1,010
1,040
1,070
1,100
1,130
1,160
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
400
800
1,200
1,600
2,000
2,400
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-153. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL W-1MA
P:\366.2\Hydrographs\2013\W-1MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
950
980
1,010
1,040
1,070
1,100
1,130
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
1,000
2,000
3,000
4,000
5,000
6,000
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WLTCE
FIGURE C-154. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL W-2MA
P:\366.2\Hydrographs\2013\W-2MA 10yr.grf
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
YEAR
1,000
1,030
1,060
1,090
1,120
1,150
1,180
WA
TE
R L
EV
EL
ALT
ITU
DE
(F
EE
T M
SL)
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N (
MIC
RO
GR
AM
S P
ER
LIT
ER
)
WL
TCE
FIGURE C-155. GROUNDWATER LEVEL HYDROGRAPH AND TCE CONCENTRATIONSFOR MONITOR WELL W-3UA
P:\366.2\Hydrographs\2013\W-3UA 10yr.grf
Note: W-3UA was officially abandoned on October 22, 2013.
APPENDIX D
2013 SITE INSPECTION REPORT GROUNDWATER TREATMENT FACILITIES
2013 INSPECTION REPORT
GROUNDWATER TREATMENT FACILITIES
Prepared for: U.S. Environmental Protection Agency
Region IX
Prepared by: NIBW Participating Companies
February 28, 2014
2013 ANNUAL INSPECTION REPORT Groundwater Treatment Facilities
North Indian Bend Wash Superfund Site Scottsdale, Arizona
1.0 INTRODUCTION
This report documents the activities and findings for the North Indian Bend Wash (NIBW) groundwater treatment plant inspections conducted in accordance with Section VI.B.4.d of the NIBW Statement of Work (SOW). The purpose of the inspections, as described in the SOW, is to identify malfunctions, deterioration, operator practices or errors, and discharges that may be causing or could result in a release of untreated groundwater. The inspections were coordinated and conducted by the NIBW Participating Companies (PCs) and attended by representatives of the U.S. Environmental Protection Agency (EPA) and Arizona Department of Environmental Quality (ADEQ).
2.0 OVERVIEW
The groundwater remedy for the NIBW Superfund Site addresses aquifer restoration by monitoring, extracting, and treating groundwater affected by volatile organic compounds (VOCs) that include the following five NIBW contaminants of concern (COCs): trichloroethene (TCE), tetrachloroethene (PCE), 1,1-dichloroethene (DCE), 1,1,1-trichloroethane (TCA), and chloroform. Treatment of the NIBW COCs is to levels set forth in the Amended Consent Decree (ACD). Five separate groundwater extraction and treatment systems were constructed to extract and treat NIBW COC-affected groundwater at the Site. These systems are referred to as the Central Groundwater Treatment Facility (CGTF), Miller Road Treatment Facility (MRTF), North Indian Bend Wash GAC Treatment Facility (NGTF), Area 7 Groundwater Extraction and Treatment System (GWETS), and Area 12 GWETS.
Complete descriptions of the CGTF, MRTF, Area 7 GWETS and Area 12 GWETS and associated operation and maintenance (O&M) activities are presented in the “Feasibility Study Addendum, North Indian Bend Wash Superfund Site”, dated November 15, 2000 (FSA), “Record of Decision Amendment – Final Operable Unit, Indian Bend Wash Area”, dated September 27, 2002 (AROD), and the Sitewide Operation and Maintenance Plan, dated June 5, 2006 (Sitewide O&M Plan). The City of Scottsdale (Scottsdale) submitted a revised O&M Plan, dated June 2010 to EPA for review.
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EPA provided comments for the CGTF, MRTF, Area 7 and Area 12 O&M Plans in April 2012. Updates and revisions to these O&M Plans are planned for March 2014.
EPA authorized the NGTF as the long-term solution for extraction and treatment of water from well PCX-1 in an Explanation of Significant Differences (ESD) dated March 2012. Construction of NGTF began in October 2012 and was essentially completed in July 2013. Functional testing, start-up, and commissioning were conducted between July and December 2013. Detailed design and operational information for NGTF has been submitted to EPA in “Design Report, PCX-1 Granular Activated Carbon Treatment Facility”, dated August 2012, and “Operation and Maintenance Plan, North Indian Bend Wash GAC Treatment Facility”, dated June 19, 2013. The NGTF O&M Plan was approved by EPA on June 24, 2013.
All five groundwater treatment systems were designed to reduce NIBW COCs to below concentrations specified in Table 3 of the AROD (Treatment Standards).
3.0 INSPECTION PROCEDURES
3.1 Routine Inspections
The operators routinely inspect the treatment facilities, either daily or weekly. Data logging of parameters such as totalized flow and equipment state is performed during site visits. Data logging of critical parameters such as air and water flow rates is performed by the computer control system at each facility on an hourly basis, at a minimum. The operators review the data for trends and anomalies to evaluate the overall operation of the treatment systems.
Due to the size and transmission of treated water to the drinking water systems, the NIBW PCs coordinate and conduct operational review meetings on an approximate monthly basis for the CGTF and NGTF. The NIBW PCs also visit all of the treatment facilities frequently for a walk-through and meet with the operators. These meetings include discussions of current operations issues, routine maintenance issues, planning for upcoming non-routine maintenance such as column cleaning, and equipment and/or systems upgrades.
Weekly, monthly, and/or quarterly data and operating reports are submitted by the facility operators. These reports are reviewed by the NIBW PCs to document O&M issues and confirm treatment effectiveness of each plant.
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3.2 Annual Inspections
Inspections are conducted annually in accordance with the SOW and ACD. The inspections for Area 7 GWETS and Area 12 GWETS were conducted on December 3, 2013, and inspections for MRTF, PCX-1, CGTF, and NGTF were conducted on December 4, 2013.
Prior to conducting the 2013 annual inspections, the PCs developed a checklist for each facility. The inspection checklists are designed to guide the inspection team through identification and evaluation of the major components and processes associated with each treatment facility.
The schedule of site inspections was coordinated in advance with EPA and ADEQ in order to provide an opportunity for regulatory agency participation. Representatives of EPA’s contractor, Gilbane, Inc., were present during the inspections. The inspections included a facility walk-through, interview with the primary operator, visual inspections of the treatment equipment, waste storage areas and groundwater containment systems, and review of operating and maintenance data. Detailed operating data and maintenance logs for routine operation and non-routine projects are maintained at and available for review at each treatment facility in accordance with the SOW. A description of each facility inspection and inspection results are provided in the following section.
4.0 FACILITY INSPECTIONS
4.1 Area 7 Groundwater Extraction and Treatment System
NIBW Area 7 is located at the southeast corner of 75th Street and 2nd Street in Scottsdale. The groundwater treatment system is located in the southeast corner of Area 7 in an area approximately 56 feet by 75 feet. The facility includes the treatment system and control equipment. Groundwater extraction is performed using three remote MAU groundwater extraction wells (7EX-3aMA, 7EX-4MA, and 7EX-5MA) and one UAU groundwater extraction well (7EX-1UA). In its current configuration, the groundwater treatment system is designed to treat up to 500 gpm of NIBW COC-affected groundwater. Treated water is delivered to one of two remote groundwater injection wells (7IN-1UA and 7IN-2UA) for recharge to the UAU.
The pump in well 7EX-5MA became lodged in the well during removal while preparing for rehabilitation of that well in July 2012. Well 7EX-5MA has remained offline since. Evaluation is currently underway, in coordination with the NIBW Technical Committee, to select a site for a replacement Area 7 extraction well
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(7EX-6MA) during the monthly NIBW Technical Meetings. At present, the NIBW PCs are working with Scottsdale regarding locations in the city right-of-way.
The pump in well 7EX-1UA failed in October 2012 and has remained offline since then. TCE concentrations in the UAU at Area 7 have consistently been below the MCL of 5 g/L. Continued pumping at well 7EX-1UA will not provide further benefit to UAU restoration. Consequently, the NIBW PCs made a formal proposal in a letter to EPA dated August 29, 2013 to terminate operation of Area 7 extraction well 7EX-1UA and allow formal abandonment of this well.
In 2013, the typical water flow rate to the Area 7 GWETS was approximately 250 to 280 gpm. The typical air flow rate through the shallow-tray air stripper at Area 7 is approximately 2,700 cubic feet per minute (cfm).
The major components of the GWETS include submersible water pumps, wellhead equipment, piping from the wellheads to the treatment plant, an equalization tank, an ultraviolet oxidation (UV/Ox) reactor, a low-profile air stripper, and a vapor-phase GAC treatment system.
During normal operation, treated groundwater is injected into the UAU via wells 7IN-1UA and 7IN-2UA. The GWETS has capabilities to discharge treated groundwater to the Scottsdale sanitary sewer under limited circumstances during non-routine maintenance or following maintenance work on the system.
The groundwater treatment plant includes a building, which houses the major treatment equipment such as the UV/Ox and air stripper systems. A control room is integral with the building and is equipped with the motor control center (MCC) and human machine interface (HMI), main control center including programmable logic controller (PLC), and motor drives.
The equalization tank and GAC adsorbers are located outside the building on the north side of the treatment plant area. A double-contained hydrogen peroxide tank is located on the south side of the treatment plant area in a contained concrete foundation with a six-inch berm. The entire treatment plant area is paved with concrete and surrounded by a two-inch berm for containment.
The treatment plant is surrounded by a block wall for security. Access to the plant is provided through three steel gates, two located on the west wall and one on the south wall.
4.1.1 Area 7 Maintenance and Condition
The Area 7 GWETS is maintained by Arcadis, Inc. (Arcadis), an engineering consultant that makes twice daily remote checks on the system and makes weekly inspections of the equipment and grounds at Area 7. The operator also
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maintains operations logs and data spreadsheets at Area 7. The logs and spreadsheets were presented for review by the inspection team. Equipment maintenance records including task and date are kept on a separate log. Other site and operational information kept in a log book includes daily inspections observations and any other data collected by the operator. Treatment system data is also automatically logged by the control system and accessed through the HMI. Based on operating and monitoring data, the Area 7 GWETS has consistently met treatment performance criteria set forth in the ACD.
The Area 7 GWETS operated greater than 85 percent of the time during 2013. Downtime is attributed to electrical issues with the air compressor, failure of one of the cooling fans associated with the UV/Ox system, routine equipment maintenance, and periodic power outages primarily related to local weather.
In general, the facility appeared clean with no apparent leaks or significant deterioration. The equipment is clean, labeled, and maintained.
Wells 7EX-3aMA and 7EX-4MA continue to operate and were the primary sources of groundwater for the Area 7 GWETS in 2013.
The process pumps in the plant appeared to be operating smoothly and without abnormal noises or vibrations. The process pumps are inspected and serviced weekly. No significant maintenance or replacement was required on the process pumps at Area 7 in 2013.
The UV/Ox system appeared to be operating normally during the inspection. The lamp in the UV/Ox reactor #1 was replaced in July 2013.
The blower appeared to run smoothly. The blower is direct drive and operated via a variable frequency drive which maintains fan speed. The operator indicated that the blower has performed well, and no service has been required. All dampers are checked monthly for operability.
The internal air stripper trays were opened by the operator and last cleaned in July 2011. The operator indicated that based on visual inspection of the trays in 2013, the minor accumulation of calcium carbonate scale did not affect operation of the air stripper.
Treated water from Area 7 is injected into the underlying aquifer using well 7IN-1UA. At the time of the inspection, no operational issues were apparent with injection well 7IN-1UA.
Arcadis indicated that all instruments, alarms, and interlocks for the main control system were tested and validated in July 2013.
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4.1.2 Results
Based on the inspection of the Area 7 GWETS, no treatment performance issues, hazards, significant deterioration, or equipment malfunctions were apparent.
4.2 Area 12 Groundwater Extraction and Treatment System
The Area 12 GWETS is located at the General Dynamics facility at 8201 East McDowell Road in Scottsdale, Arizona. At this site, the air stripping tower is located just west of the Chemical Operations Building. The Area 12 GWETS is designed to treat up to 1,850 gpm of groundwater. Groundwater is extracted from two wells: MEX-1MA and SRP well 23.6E-6.0N, also known as the Granite Reef well. The Granite Reef well is owned and operated by SRP. The treated groundwater is delivered to SRP’s irrigation distribution system through a connection to an SRP lateral pipeline located in Granite Reef Road.
Typical flow rates from MEX-1 and Granite Reef wells were approximately 1,000 gpm and 800 gpm, respectively. The Granite Reef well is typically operated only for a week to ten days four times a year prior to quarterly sampling. MEX-1 is the primary source of groundwater treated at Area 12 the rest of the time.
The Area 12 GWETS consists of an air stripping system, and an off-gas treatment system. Groundwater is pumped from the wells in individual pipes to a common manifold near the air stripper. The air stripper is a counter-current forced-draft, packed column through which the NIBW COCs are removed from the groundwater. In 2013, the typical airflow rate through the air stripper column ranged between 5,000 and 5,400 cfm.
The off-gas treatment is a vapor-phase GAC polishing system. The treated groundwater is discharged to SRP’s irrigation distribution system under an agreement between SRP and Motorola Solutions, Inc.
Located at the treatment plant is the main control panel containing the system PLC. Each well pump system is connected to the PLC using an Ethernet connection with signals traveling via a fiber optic pathway. Each well site also contains a PLC to control the individual remote well operation. The remote well pump PLCs also interface with SRP systems to monitor and control well operation.
A small control room which is located at the treatment plant houses the HMI and various plant specific records. The HMI consists of a computer that supports a graphical user interface, logs operating data, and allows remote operation and data transfer using a telephone modem.
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4.2.1 Area 12 Maintenance and Condition
The Area 12 GWETS is maintained by EnSolutions, an engineering consultant that makes daily remote checks on the system via computer and approximately twice weekly visits to the GWETS each month. During the visits, the operator conducts inspections of the equipment and grounds at Area 12. The operator also maintains operations logs and data spreadsheets at the facilities. The logs and spreadsheets were presented for review by the inspection team. A safety coordinator for the General Dynamics facility makes daily walk-throughs at the Area 12 GWETS.
Except for the scheduled maintenance shut down in January through early February 2013 for the SRP dry-up, the Area 12 GWETS was available for operation greater than 95% of the time in 2013. Based on operating and monitoring data, the Area 12 GWETS has consistently met performance criteria set forth in the ACD.
In general, the facility appeared clean with no apparent leaks or significant deterioration. The equipment is clean, labeled, and well maintained.
The blowers appeared to run smoothly. The air stripper blower belts were changed in January 2013 and July 2013. The main blower was balanced and aligned during the annual maintenance event during SRP dry-up in January 2013. The operator indicated that the blowers have performed well, and no other non-routine service has been required.
Scale removal was last performed on the air stripper columns in January 2013. Scale removal is performed annually when maintenance is performed during the SRP dry-up period.
The process control system is monitored continuously by the computer. The system must be in auto-mode for start-up and operation. The system cannot start with an active shutdown alarm. The primary control system alarms are tested annually during the maintenance period during SRP dry-up. The control system primary alarms were tested and validated in January 2013. The results of the testing were presented for review. The testing data indicated that all systems were operable. The operator indicated that the alarms are routinely tested when the system is shut down. All equipment, control device elements, transmitters, alarms, and interlocks are tested at least once per year.
4.2.2 Results
Based on the inspection of the Area 12 GWETS, no treatment performance problems, hazards, significant deterioration, or equipment malfunctions were apparent.
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4.3 Miller Road Treatment Facility
MRTF is located at 5975 Cattletrack Road, south of the intersection of Cattletrack Road and McDonald Drive in Scottsdale, Arizona. The facility is owned and operated by, and the responsibility of EPCOR Water USA (formerly, Arizona American Water Company). MRTF is used to treat water from EPCOR production wells PV-14 and PV-15. Water from well PCX-1 was delivered to and treated through a dedicated treatment train at MRTF until August 6, 2013 when the PCX-1 pipeline was disconnected from MRTF.
MRTF consists of three individual air stripping treatment trains. Each treatment train includes a counter-current, forced-draft air stripper with appurtenant equipment such as an air blower. The off-gas from each air stripper passes through a mist eliminator; then through ducting to one of three GAC adsorbers before discharge to the atmosphere. Each air stripper column was designed to treat groundwater at flow rates up to 2,100 gpm with a typical air flow rate of approximately 11,300 cfm. A comprehensive rehabilitation project completed in 2010 refurbished the air stripper column internals and made several other improvements at the facility.
Prior to August 6, 2013, water from well PCX-1 was treated through a treatment train that was physically separated (including control system) from the other systems at MRTF. During that time, treatment of water from well PCX-1 was coordinated by EnSolutions, a contractor to the NIBW PCs, in accordance with Interim Operating Plan, Miller Road Treatment Facility (Treatment Train 2), dated April 25, 2008, with addenda dated June 13, 2008 and November 21, 2008.
Water produced from wells PV-14 and PV-15 is treated by EPCOR through Treatment Train 3 and Treatment Train 1, respectively, and delivered to the clearwell at MRTF, where it is then pumped to EPCOR’s Paradise Valley Arsenic Removal Facility. If not required by EPCOR, treated water may be delivered to SRP via the Arizona Canal outfall.
At the time of the inspection, treatment of water from only wells PV-14 and PV-15 occurred at MRTF. Reconfiguration of the former PCX-1 treatment train (Treatment Train 2) to return it back to EPCOR control, is planned for summer 2014. EPCOR is responsible for all O&M of MRTF.
All of the treatment equipment except the GAC adsorbers are located inside the treatment building. The treatment building consists of several rooms including the air stripper room which houses the air stripper columns, blowers, and distribution pumps; the electrical room which supports the MCCs, starters, Remote Terminal Units (RTUs), Remote Input/Output (RIO) cabinets, transformers, and other electrical equipment; and the control room, where the HMI, laboratory, and records are located.
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For security and aesthetics, the facility is surrounded by a masonry wall with locking access gates.
4.3.1 MRTF Maintenance and Condition
EPCOR made relevant operating, monitoring, and safety documents, as well as operating data and maintenance logs for MRTF, available during the inspection. Additionally, the operator was interviewed and a walk-through of the facility was conducted.
EPCOR mans MRTF for several hours a day five days a week. The operator makes daily inspections of the equipment and grounds at MRTF. The operator also maintains operations logs and data spreadsheets at the facility. Operating and water quality monitoring data indicate that the air strippers associated with treatment of water from wells PV-14 and PV-15 have performed consistently and satisfactorily.
All three air stripper columns were cleaned of calcium carbonate scale in early 2013. Column cleaning consists of circulating a low pH solution through the packing to remove the accumulated scale.
The blowers and treatment area are inspected daily by the operator. Maintenance, such as balancing and belt alignment on the blowers, is performed by EPCOR technicians on an as needed basis in accordance with the O&M instructions provided by the manufacturer. All blowers at MRTF appeared to run smoothly without excessive vibration and unusual noises.
The equipment and work areas at MRTF appeared clean, and well maintained. The piping, valves, and instruments were labeled and appeared in good condition.
EPCOR upgraded and installed a new control system at MRTF in late 2013. The project included installation of new computer hardware and software. On-site work including installation, set-up, testing, and validation of the control system was performed between September and November 2013.
The air handling system appeared tight and in good condition. EPCOR indicated that the dampers are exercised periodically.
4.3.2 Results
Based on the inspection of MRTF, no treatment performance issues, hazards, significant deterioration or equipment malfunctions were apparent.
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4.4 Central Groundwater Treatment Facility
The CGTF is located at 8650 E. Thomas Road in Scottsdale, Arizona at the northeast corner of Pima Park, a municipal park. Other nearby facilities include the CGTF wells and Reservoir 80 into which treated water from the CGTF is discharged for beneficial use as a supply to Scottsdale’s potable water system.
Background and details of the CGTF are provided in the O&M Plan developed for this facility. The EPA-approved CGTF O&M Plan, dated March 2006, describes the facility, the major pieces of equipment, control strategies, and performance monitoring of the treatment plant. Design parameters and performance of CGTF have been validated and documented in the O&M Plan, quarterly Compliance Monitoring Reports, and annual data reports for the NIBW Site. A revised O&M Plan, dated January 2010 was submitted to EPA for review. Additionally, an extensive engineering evaluation of the plant, equipment, and control system was conducted between August and October 2008. The results and findings associated with those activities are included in the final report, Engineering Evaluation, Central Groundwater Treatment Facility, dated January 2009, by Environ.
The CGTF uses air stripping to remove NIBW COCs, primarily TCE, from groundwater. The CGTF is comprised of three separate, parallel treatment trains. Each treatment train consists of a packed column, a process air fan, and an off-gas vapor treatment system that removes NIBW COCs prior to discharge to the atmosphere. Each column has a design capacity of 3,150 gpm. The overall capacity of the CGTF is approximately 9,450 gpm. The separate treatment trains allow for one or more columns to be removed from service while the other column(s) continue to operate.
Groundwater is pumped from wells 75A, 71, 72, and 31 through transmission pipelines to the CGTF. Influent water combines in a common raw water header and is evenly distributed into the available columns where it flows top to bottom through the column packing while airflow is pulled through the tower in a counter-current direction.
Since water from the wells is delivered to CGTF in a common header, the flow rate through each column can vary depending on the number of wells and columns which are in service at any given time. Typically between approximately 1,500 and 3,000 gpm is treated through an air stripper column.
The treated water is collected in individual sumps at the bottom of each column and then flows by gravity into a common sump. The treated water is discharged to Scottsdale’s potable system or to the SRP irrigation system. The capacity of the connection to the SRP irrigation system varies based on several factors, with
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a current maximum of approximately 4,000 gpm. Blending of CGTF treated water with other water supplies occurs in the potable water storage facility, Reservoir 80, just south of the site.
A process air fan is used to pull air through an intake filter then upward through the packed column counter-current to the water flow. The off-gas is directed through a mist eliminator, a natural gas-fired duct heater, and then to a GAC contactor prior to discharge to the atmosphere. The duct heater reduces relative humidity prior to VOC adsorption in the GAC contactors.
The majority of the treatment equipment, except the duct heaters, GAC contactors, and chlorination equipment, is located inside the CGTF treatment building. The treatment building consists of several rooms, including: the air stripper room, which houses the packed columns and process air fans; the electrical equipment room, which supports the MCCs, starters, RTUs, RIO cabinets, transformers, and other electrical equipment; and the laboratory. Chlorination equipment is located in a separate building at the Reservoir 80 booster station and is part of the drinking water system operated by Scottsdale.
For security and aesthetics, the facility is surrounded by a masonry wall with locking access gates.
4.4.1 CGTF Maintenance and Condition
The CGTF is maintained by a Scottsdale water treatment operator. Scottsdale operations personnel also monitor the status of CGTF remotely. Operators make minimum daily inspections of the equipment and grounds at CGTF. The operator maintains operations logs and data spreadsheets at the facilities. The logs and spreadsheets were presented for review by the inspection team. Technical staff from Scottsdale water operations such as mechanics and instrumentation technicians also provide maintenance support, as needed.
The Scottsdale Water Resources Department uses a city-wide preventative maintenance program for all equipment operated by the water operations staff. This program maintains a service record database for each piece of equipment and alerts the technicians when routine preventative maintenance is necessary.
Based on operating data, CGTF has consistently met performance criteria set forth in the ACD. The CGTF operated nearly 100% of the time in 2013 except for approximately 5 weeks during May and June 2013 when column cleaning was performed.
In general, the facility appeared clean with no apparent leaks or significant deterioration. The equipment is clean, labeled, and well maintained.
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All piping appeared in good condition without leaks or corrosion. All valves in the plant are turned at least once per year to verify proper working order. New pipe restraints were added in 2013 to the acid lines downstream of the acid pump to minimize movement when the pump starts. Also, new valves were installed on the drain lines connected to each column influent pipe. The concrete sanitary sewer structure that collects water drained from the influent pipes was also replaced.
All blowers appeared to run smoothly. The blowers are serviced during each GAC service event on the associated treatment train. Service activities include alignment, bearing repacking, and inspection and tightening of the drive belts.
The air handling and treatment system appeared tight and in good condition. In 2013, the ducting associated with the air inlet system to the columns was replaced. The ducting runs underground from the air intake filters to the wall of the column sumps. Since original installation, the old ducting began to collapse due to the weight of overburden soil. As part of the new design, a concrete slab is used to shield the buried ducting from the overburden. Also, slide gates were installed at the air intake assemblies to seal the duct during column cleaning activities.
Visual inspection through the viewports on the air stripper column during the inspection indicated moderately scaled packing.
The trays at the top of each column are visually inspected by the operator on a monthly basis for even water distribution and for accumulation of debris produced from the wells.
The process control system is monitored continuously. Scottsdale has implemented a program to test all switches and alarms on a routine basis when a treatment train is offline for GAC service. Results of the control tests are maintained in a notebook at CGTF. Additionally, instruments are checked and calibrated during the GAC service events by Scottsdale instrument technicians.
Well 71 was shutdown in December prior to commencement of work on installation of a new well (71A) nearby.
4.4.2 Results
Based on the inspection at CGTF, no treatment performance problems, hazards, significant deterioration, or significant equipment malfunctions were apparent.
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4.5 NIBW GAC Treatment Facility
The NGTF is located at 5985 North Cattletrack Road in Scottsdale, Arizona at the southwest corner of Cattletrack Road and McDonald Drive. NGTF is owned by Motorola Solutions, Inc. and is operated under contract by Scottsdale Water Resources. Treated water from NGTF is delivered to the Arizona Canal through an outfall immediately east of the site. Final permitting by Maricopa County Environmental Services Department (MCESD) as a new water source for municipal use is expected in first quarter 2014. Once final approval from MCESD is obtained, Scottsdale will use the water in its system at the Chaparral Water Treatment Plant (CWTP) located approximately one half mile east of NGTF.
As described above, construction of NGTF was mostly completed in July 2013. Functional testing of NGTF began in early July 2013. On August 6, 2013 during restart of well PCX-1 following disconnection of the pipeline from MRTF, one of the air valves on the PCX-1 pipeline failed. The PCX-1 pipeline is owned and operated by SRP. SRP responded to the failure and fully documented the event. Following replacement of the air valve and other system checks, SRP allowed PCX-1 to restart on August 8, 2013. Dedicated treatment of water from well PCX-1 at NGTF began on August 8, 2013.
Treatment of water from well PCX-1 at NGTF is accomplished using liquid-phase GAC. Water flow from well PCX-1 is controlled using a motorized flow control valve and a magnetic flow meter to regulate influent flows to meet the treatment capacity flow rate of 2,100 gpm. A pre-filter located upstream of the GAC system removes entrained solids to prevent accumulation of sediment in the media bed. The GAC system is comprised of three separate, parallel treatment trains. Each treatment train consists of two contactors, each containing approximately 20,000 pounds of GAC with interconnecting piping and valves. Each treatment train has a design capacity of approximately 1,050 gpm which results in an empty bed contact time of just over 5 minutes.
Groundwater enters the treatment train through the lead contactor which provides the required NIBW COC treatment. Treated groundwater then flows through the lag contactor. Between each contactor in the train is a valve “tree” consisting of eight butterfly valves. The configuration of the valve tree allows for each of the two GAC contactors in the treatment train to operate in either LEAD position or LAG position and also supports reverse flow through the contactors for backwashing the media. Flow control for duty train selection and lead/lag contactor position will be performed using butterfly valves equipped with position switches that relay OPEN or CLOSE position status to the plant PLC. Valve position status is interlocked with the operation of well PCX-1 to ensure the treatment system complies with the standard operating procedures developed for the facility.
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Following GAC treatment, water will be disinfected by Scottsdale and delivered to the CWTP finished water reservoir through a dedicated 16-inch pipeline between the facilities. Chlorination is required by Scottsdale to meet drinking water standards associated with the CWTP. The disinfection system at NGTF is not considered part of treatment of NIBW COCs in groundwater, however reference to disinfection is provided in this document for completeness.
After GAC servicing or during normal operation, the media may require backwashing to remove fines and sediment build-up in the bed. Backwash operations consist of redirecting treated water to the backwash supply header, and subsequently to the valve tree of the respective treatment train. Flow control during backwash operations will be accomplished using a motor operated valve and flow meter feedback signals to provide the required backwash flow rate. Backwash water will be stored in the backwash storage tank, and will be discharged to the sanitary sewer.
The control building at NGTF supports the control console with HMI, appurtenant mechanical equipment, electrical equipment, and the RTU containing the main PLC. The system is linked with Scottsdale’s city-wide SCADA System. Remote RIO panels are located near each treatment train. The RIO panels receive inputs from the position switches at each valve on the respective valve tree. Indicator lights on each RIO panel locally indicate in which operating configuration the treatment train is set. The program logic associated with the SCADA system is secure and only accessible by authorized personnel. Changes to the program can only be made after review and acceptance by Scottsdale and the NIBW PCs.
The treatment facility site comprises approximately one and a half acres surrounded by a masonry block wall with a main vehicle entry gate and two walk-through gates. The facility is initially designed to treat groundwater extracted from well PCX-1. The facility is designed to allow for further expansion in the future, if necessary, to accept and treat groundwater from other sources with a maximum hydraulic capacity of approximately 4,400 gpm.
4.5.1 NGTF Maintenance and Condition
The NGTF is maintained by a Scottsdale water treatment operator. Scottsdale operations personnel also monitor the status of NGTF remotely. Operators make minimum daily inspections of the equipment and grounds at NGTF. The operator maintains operations logs and data spreadsheets at the facility. The logs and spreadsheets were presented for review by the inspection team.
The Scottsdale Water Resources Department uses a city-wide preventative maintenance program for all equipment operated by the water operations staff. This program maintains a service record database for each piece of equipment and alerts the technicians when routine preventative maintenance is necessary.
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Service records for all the primary equipment at NGTF were available for review at the time of the inspection.
No service records for the equipment at NGTF were available for review at the time of the inspection since the plant is new and service had not been needed up until that point.
Based on operating data, NGTF has consistently met performance criteria set forth in the ACD.
Since the facility is new, it appeared clean with no apparent leaks or deterioration. The equipment is clean, and well maintained. Labels for some parts of the piping, valves, and instrumentation were not complete at the time of the inspection. These labels, as well as other punch list items remained from the construction. Final completion of the construction related activities is planned for first quarter 2014.
All piping appeared in good condition without leaks or corrosion. Manual valves in the plant are turned when treatment trains are switched.
The process control system is monitored continuously. Instruments are checked and calibrated in accordance with the manufacturers’ instructions by Scottsdale instrument technicians.
The inspection team also visited well PCX-1 to observe the well head interconnecting piping, valves, air relief valves, and instruments. The PCX-1 well head appeared in good and operable condition.
4.5.2 Results
Based on the inspection at NGTF, no treatment performance problems, hazards, significant deterioration, or significant equipment malfunctions were apparent.
4.5.3 Recommendations
Complete labeling of the piping, valves, and instrumentation. Also, complete final punch-list items associated with the construction.
APPENDIX E
ANNUAL GROUNDWATER PRODUCTION AND TCE TIME-SERIES DATA FOR NIBW EXTRACTION WELLS
FIGURE E-1. CONCENTRATION OF TCE AND AVERAGE ANNUAL PUMPING RATE AT EXTRACTION WELL PV-142004 THROUGH 2013
0
400
800
1,200
1,600
2,000
2,400
AV
ER
AG
E A
NN
UA
L PU
MP
ING
RA
TE
, in gallons per minute
YEAR
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
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1
2
3
4
5
6
TC
E C
ON
CE
NT
RA
TIO
N, i
n m
icro
gram
s pe
r lit
er
Wellhead TCE Concentration
Average annual pumping rate
366\2013 Annual Report\E-1_PV14 PumpTCE_13.grf
Note: All values of 0.5 indicate lab results of 0.5 micrograms per liter or less.
FIGURE E-2. CONCENTRATION OF TCE AND AVERAGE ANNUAL PUMPING RATE AT EXTRACTION WELL PV-152004 THROUGH 2013
0
400
800
1,200
1,600
2,000
2,400
AV
ER
AG
E A
NN
UA
L PU
MP
ING
RA
TE
, in gallons per minute
YEAR
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
0
2
4
6
8
10
12
TC
E C
ON
CE
NT
RA
TIO
N, i
n m
icro
gram
s pe
r lit
er
Wellhead TCE Concentration
Average annual pumping rate
366\2013 Annual Report\E-2_PV15 PumpTCE_13.grf
FIGURE E-3. CONCENTRATION OF TCE AND AVERAGE ANNUAL PUMPING RATE AT EXTRACTION WELL COS-312004 THROUGH 2013
0
400
800
1,200
1,600
2,000
2,400
AV
ER
AG
E A
NN
UA
L PU
MP
ING
RA
TE
, in gallons per minute
YEAR
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N, i
n m
icro
gram
s pe
r lit
er
Wellhead TCE Concentration
Average annual pumping rate
366\2013Annual Report\E-3_COS31 PumpTCE_13.grf
Note: Well not sampled due to intermittent operation. Assume average TCE concentrations from 2008.COS did collect samples in September and December (8.51 and 6.14 micrograms per liter, respectively),however, due to the intermittent well operation, those samples may not be representative.
FIGURE E-4. CONCENTRATION OF TCE AND AVERAGE ANNUAL PUMPING RATE AT EXTRACTION WELL COS-712004 THROUGH 2013
0
400
800
1,200
1,600
2,000
2,400
AV
ER
AG
E A
NN
UA
L PU
MP
ING
RA
TE
, in gallons per minute
YEAR
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
0
40
80
120
160
200
240
TC
E C
ON
CE
NT
RA
TIO
N, i
n m
icro
gram
s pe
r lit
er
Wellhead TCE Concentration
Average annual pumping rate
366\2013 Annual Report\E-4_COS71 PumpTCE_13.grf
FIGURE E-5. CONCENTRATION OF TCE AND AVERAGE ANNUAL PUMPING RATE AT EXTRACTION WELL COS-722004 THROUGH 2013
0
400
800
1,200
1,600
2,000
2,400
AV
ER
AG
E A
NN
UA
L PU
MP
ING
RA
TE
, in gallons per minute
YEAR
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N, i
n m
icro
gram
s pe
r lit
er
Wellhead TCE Concentration
Average annual pumping rate
366\2013 Annual Report\E-5_COS72 PumpTCE_13.grf
FIGURE E-6. CONCENTRATION OF TCE AND AVERAGE ANNUAL PUMPING RATE AT EXTRACTION WELL COS-75A2004 THROUGH 2013
0
400
800
1,200
1,600
2,000
2,400
AV
ER
AG
E A
NN
UA
L PU
MP
ING
RA
TE
, in gallons per minute
YEAR
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
0
40
80
120
160
200
240
TC
E C
ON
CE
NT
RA
TIO
N, i
n m
icro
gram
s pe
r lit
er
Wellhead TCE Concentration
Average annual pumping rate
366\2013 Annual Report\E-6_COS75A PumpTCE_13.grf
FIGURE E-7. CONCENTRATION OF TCE AND AVERAGE ANNUAL PUMPING RATE AT EXTRACTION WELL MEX-1MA2004 THROUGH 2013
0
400
800
1,200
1,600
2,000
2,400
AV
ER
AG
E A
NN
UA
L PU
MP
ING
RA
TE
, in gallons per minute
YEAR
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
0
20
40
60
80
100
120
TC
E C
ON
CE
NT
RA
TIO
N, i
n m
icro
gram
s pe
r lit
er
Wellhead TCE Concentration
Average annual pumping rate
366\2013 Annual Report\E-7_MEX-1MA PumpTCE_13.grf
FIGURE E-8. CONCENTRATION OF TCE AND AVERAGE ANNUAL PUMPING RATE AT EXTRACTION WELL PCX-12004 THROUGH 2013
0
400
800
1,200
1,600
2,000
2,400
AV
ER
AG
E A
NN
UA
L PU
MP
ING
RA
TE
, in gallons per minute
YEAR
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
0
20
40
60
80
100
120
TC
E C
ON
CE
NT
RA
TIO
N, i
n m
icro
gram
s pe
r lit
er
Wellhead TCE Concentration
Average annual pumping rate
366\2013 Annual Report\E-8_PCX-1 PumpTCE_13.grf
FIGURE E-9. CONCENTRATION OF TCE AND AVERAGE ANNUAL PUMPING RATE AT EXTRACTION WELL SRP 23.6E, 6N(GRANITE REEF), 2003 THROUGH 2012
0
400
800
1,200
1,600
2,000
2,400
AV
ER
AG
E A
NN
UA
L PU
MP
ING
RA
TE
, in gallons per minute
YEAR
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
0
40
80
120
160
200
240
TC
E C
ON
CE
NT
RA
TIO
N, i
n m
icro
gram
s pe
r lit
er
Wellhead TCE Concentration
Average annual pumping rate
366\2013 Annual Report\E-9_SRP 23.6, 6 (Granite Reef) PumpTCE_12.grf
FIGURE E-10. CONCENTRATION OF TCE AND AVERAGE ANNUAL PUMPING RATE AT EXTRACTION WELL 7EX-1UA2004 THROUGH 2013
0
400
800
1,200
1,600
2,000
2,400
AV
ER
AG
E A
NN
UA
L PU
MP
ING
RA
TE
, in gallons per minute
YEAR
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
0
10
20
30
40
50
60
TC
E C
ON
CE
NT
RA
TIO
N, i
n m
icro
gram
s pe
r lit
er
Wellhead TCE Concentration
Average annual pumping rate
366\2013 Annual Report\E-10_7EX-1 PumpTCE_13.grf
FIGURE E-11. CONCENTRATION OF TCE AND AVERAGE ANNUAL PUMPING RATE AT EXTRACTION WELL 7EX-3MA2004 THROUGH 2013
0
400
800
1,200
1,600
2,000
2,400
AV
ER
AG
E A
NN
UA
L PU
MP
ING
RA
TE
, in gallons per minute
YEAR
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
0
200
400
600
800
1,000
1,200
TC
E C
ON
CE
NT
RA
TIO
N, i
n m
icro
gram
s pe
r lit
er
Wellhead TCE Concentration
Average annual pumping rate
366\2013 Annual Report\E-11_7EX-3 PumpTCE_13.grf
FIGURE E-12. CONCENTRATION OF TCE AND AVERAGE ANNUAL PUMPING RATE AT EXTRACTION WELL 7EX-4MA2004 THROUGH 2013
0
400
800
1,200
1,600
2,000
2,400
AV
ER
AG
E A
NN
UA
L PU
MP
ING
RA
TE
, in gallons per minute
YEAR
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
0
400
800
1,200
1,600
2,000
2,400
TC
E C
ON
CE
NT
RA
TIO
N, i
n m
icro
gram
s pe
r lit
er
Wellhead TCE Concentration
Average annual pumping rate
366\2013 Annual Report\E-12_7EX-4 PumpTCE_13.grf
FIGURE E-13. CONCENTRATION OF TCE AND AVERAGE ANNUAL PUMPING RATE AT EXTRACTION WELL 7EX-5MA2004 THROUGH 2013
0
400
800
1,200
1,600
2,000
2,400
AV
ER
AG
E A
NN
UA
L PU
MP
ING
RA
TE
, in gallons per minute
YEAR
2004 2005 2006 2007 2008 2009 2010 2011 2012 2013
0
200
400
600
800
1,000
1,200
TC
E C
ON
CE
NT
RA
TIO
N, i
n m
icro
gram
s pe
r lit
er
Wellhead TCE Concentration
Average annual pumping rate
366\2013 Annual Report\E-13_7EX-5 PumpTCE_13.grf