Document No. 80-3 - Ft. WingateDocument No. 80-3 Final Report Environmental Survey of Ft. Wingate...
Transcript of Document No. 80-3 - Ft. WingateDocument No. 80-3 Final Report Environmental Survey of Ft. Wingate...
FW81-I
Administrative Record
FORTWINGATE DEPOTACTIVITY, GALLUP, NEW MEXICO
Document No. 80-3
Final ReportEnvironmental Survey of
Ft. Wingate Depot Activity,
Gallup, New Mexico
Environmental Science and Engineering, Inc.
September 1981
INQUIRIESREGARDINGTHISDOCUMENT AND/OR THEADMINISTRATE RECORD FOR
FORT WINGATE DEPOTACTIVITY SHOULDBEMADETO:
COMMANDER, TOOELEARMY DEPOT, TOOELE, UTAH 84074
u.
Contract DAAK1 1-80-C-0096
ENVIRONMENTAL SURVEY OFFT. WINGATE DEPOT ACTIVITY
Gallup, New Mexico 87301
FINAL REPORT
Authors:L.S. Wiese, J.B. Sosebee, R.G. Gregory, J.J. Mousa,
J.G. Morse, M.A. Keirn, E.A. Knauft
ENVIRONMENTAL SCIENCE AND ENGINEERING, INC.Post Office Box ESE
Gainesville, Florida 32602
19 September 1981
APPROVED FOR PUBLIC RELEASEDISTRIBUTION UNLIMITED
Prepared fo~Ft. Wingate Depot ActivityGallup, New Mexico 87301
S. ARMY TOXIC AND HAZARDOUS MATERIALS AGENCYAberdeen Proving Ground, Maryland 21010
USATRAMAFR. l/WIN/DIST. 19/15/81
TNE VIEWS, OPINIONS AND/OR FINDINGS
CONTAINED IN TNIS REPORT ARS TNOSE
OF TNE AuTNOR(S) AND SHOULD NOT BE
CONSTRUED AS AN OFFICIAL DEPARTMENT
OF TEE ARMY POSITION, POLICY, OR
DECISION, UNLESS SO DESIGNATED BY
OTHER DOCUMENTS
—
,cu RITy CL A551FIc AT10N OF THIS PAGE (U?I- D-. skt~
REPORT OOCLIMENTATION PAGEREAD lNSTRUcnoNs
BEFORECompleting FORMREPORT NIJhSBER Z. GOV7 ACCESSION NO. 3. RECIPIENT*S CATALOG NUMEER
I ITITLE (md subtitle) S. TYPE OF RIEPORT h PCRIOD COVERED
Final Report
Environmental Survey of Fort ‘Jingate Deoot September 1980-Sentember 1981
0. PCRFORMIMGORG. REPORT NuMBCRActivity 80-606-260
AuTHOR(.)
L.S.a.CONTRACT OR GRAMTMUMBER(.,
TJiese, J.B. Sosebee, R.G. Gregory,
J.J. Yousa, J.G. Morse, V.A. Keirn, E.A. Knauft“’ DAAK-11-80-c-oo9fj
PCRFORMIMG ORGANIZATION NAMK ANO AOORSSS 10. PROGRAM ELSMCNT,PROJECT, TASK
Environmental Science and Engineering, Inc.ARCA & WORK UNIT NUMOERS
P.(3. Box ESEGainesville, Florida 32602
. CONTROLLING O??ICENAMC ANOAODRSSS 1S. REPoRT DATE
Commander 19 September 1981Ft. Wingate hDOt Activity Il.NuMOCROP PAGES
Gallup, New Yexico 87301 181L MONITORING AGCNCY NAME & AOORSSSfffdSttaNt - CrnR8111mSOtfieq IS. SECURITY CLASS. (ofthSm~)
lJ.s. Amy ‘TOxic and Hazardous Materials Agenq
Aberdeen ProvinS Ground, Uaryland 2101(-JUnclassified
!5a.DCCLASSIFICAmON/~WNGRAOINGSCNCOULC
I6.OISTRISUTION STATEMENT (efthJ. JSe)
B. SUPPLSWENTARV NOTES
1. KEYWoROS(ti,bmm-”d*Jf”m”-&i&u~~~~~,
‘x?lOsivesY Propellants, Fort ‘liwaf= ArmyDepot Activity, 2,4-dinitrotoluene,2,4,6-trinitrotoluene, 2,6-dinitrotoluene, 1,3,5-trinitrobenzene,l,3-dinitrobenzene, nitrobenzene, tetryl, white phosphorus,cvclotrinethylenetrinitramine, Environmental Sumey
An Environmental Survey of Fort lJingate Denot Activity was performed to
determine the extent of contamination caused by activities related to munitionsstorage, recycling, and trea~ent. Sanmle sites were selected based on sitehistory and uotential for contamination. Yonitor wells were installed.?round water, 5 surface water, 9 sediment,
Uourand 15 soil sites were sam~led and
analyzed for nitroaromatics, tetryl, white phosphorus, Cvclotrimethylenetrf-nitramine, priority uollutant metals, or,yanfcs,?esticides and pc~s, and
Do ,!&-mlm -nowor tNOV6SISOSSOLSTISullClaSsifiecJ
s~cumn CLASSIFtCATtON OFTNIS PAGc(tiDu.sntU@
CIJRITY CLASSIFICATION OF THIS PAGC~-DUa Bmand)
). (Cent’d)
nutrients. Soil contamination, consisting of nitroaromatic compounds,found in the Ammunition Vorkshop Area and in the Demolition Area.
wasOne
sediment site inGround water andcontamination.
the Demolitionsurface water
Area contained nitroaronatic cormounds.were free of munitions-related compound
UnclassifiedsECURITY CL ASS1FICATION OF THIS pAGC~- D-= EIW.-)
.
usATHAMAFR.1 /wIN/Toc.l
9/17/81
.
.
TABLE
Section
1.0 INTRODUCTION
2.0
1.11.21.3
1.4
OF CONTENTS
STATEMENT OF WORKDEPOT HISTORYENVIRONMENTAL SE’11’ING
1.3.1 METEOROLOGICAL DATA
1.3.2 TOPOGRAPHY AND DRAINAGE1.3.3 GEOLOGY1.3.4 SATIONALE FOR SA14YLEAREA SELECTION
Aomnition Workshop AreaDemolition and Burning Ground AreaeAdministration Area
property Boundary AreaBackground Areas
TECHNICAL APPROACH
FIELD STUDIES
2.1 RATIONALE FOR SAMPLING SITE SELECTION
2.1.1 AMMUNITION WORKSHOP AREA2.1.2 DEMOLITION AND BURNING GROUND AREAS2.1.3 ADMINISTMTION AREA2.1.4 OTHER AREAS
2.2 WELL INSTALLATION/GROUNDWATER SAMPLING
2.2.1 WELL DESIGN AND CONSTRUCTION
Sample Description and Logging ProceduresWell InstallationWell Development
2.2.2 SAMPLING TBCRNIQUES
2.3 SORFACE WATER AND SEDIMENT SAMPLING2.4 SOIL SAMPLING
1
5?%s
7
7
1011
11111521
2123232424
24
26
26
26282836
36
u
464951
51
5454
—
usATHAMAFR.1/wIN/Toc.29/17/81
TABLE OF CONTENTS (Continued, Page 2 of 2)
*
59
Section
3.0 LABORATORY STUDIES
3.1 CHEMICAL ANALYSIS
3.1.1 CERTIFICATION OF METHODS3.1.2 DEVELOPMENT OF NEW METHODS
3.1.3 METHODS OF ANALYSIS
59
596465
3.2 QUALITY ASSURANCE 68
3.2.1 ORGANIZATION AND RESPONSIBILITIES3.2.2 TRAINING AND CERTIFICATION3.2.3 METHOD CERTIFICATION3.2.4 SAMPLE COLLECTION3.2.5 ANALYTICAL SYSTEMS CONTROL3.2.6, DATA VALIDATION3.2.7 CONTAMINATION SAFEGUARDS
75757575757676
3.3 DATA MANAGEMENT 77
4.0 RESULTS 83
4.1 RBSULTS OF CHEMICAL ANALYSES 83
4.1.1 AMMUNITION WORRSHOP AREA4.1.2 DEMOLITION ARBA4.1.3 OTHER AREAS
838587
874.2 GEOIWDROLOGY
4.2.1 AMMUNITION WORXSHOP ARBA4.2.2 DEMOLITION AREA4.2.3 ADMINISTRATION AREA
899091
935.0 CONCLUSIONS
966.0 REFERENCES
7.0 APPENDICES
APPENDIX A—WELL PROFILESAPPENDIX B--SURVEY REPORTAPPENDIX C-CHEMICAL DATAAPPENDIX D--SUPPORTING REPORTS AND DOCUKENTS
A-1B-1c-1D-1
2
USATHAMAFR.1/WIN/LOT. 19/17/81
LIST OF TABLES
-.
Table
2-1
2-2
2-3
2-4
2-5
2-6
2-7
2-8
2-9
2-1o
2-11
2-12
2-13
2-14
3-1
3-2
3-3
3-4
3-5
Anmmnition Workshop Area Soil Siting Rationale
Ammunition Workshop Area Surface Water and SedimentSiting Rationale
Ammunition Workshop Area Monitor Well Siting Rationale
Demolition Area Soil Siting Rationale
Demolition Area Surface Water and Sediment SitingRationale
Demolition Area Monitor Well Siting Rationale
Administration Area Monitor Well Siting Rationale
Other Areas Soil Siting Rationale
Other Areas Surface Water and Sediment Siting Rationale
Other Areas Monitor Well Siting Rationale
FWDA Groundwater Sampling Sites
Water Sample Preservation Techniques
Surface Water and Sediment Sampling Sites
Soil Sampling Sites
Analyses for Which ESE has been Certified byUSATHAMA--Quantitative Methods
Analyses for Which ESE has been Certified byUSATHAMA-Semi-Quantitative Methods
EPA Priority Pollutants
Groundwater Analyses, FWDA Environmental Survey
Surface Water Analyses, FWDA Environmental Survey
29
30
32
33
34
37
38
39
40
42
53
55
57
60
61
66
71
72
—
USATRAMAFR.1/WIN/LOT. 29/17/81
LIST OF TASLES(Continued, Page 2 of 2)
Table
3-6 Sediment Analyses, FWDA Environmental Survey
3-7 Soil Analyses, FWDA Environmental Survey
3-8 FWDA Level 2 Data Files
4-1 Summary of Analytical Reaulta at the AmmunitionWorkshop Area
@s73
74
82
,—
84 —
USATNAMAFR. 1/wN/LOF .19/17/81
e
M
i=
Eiw!2
1-1
1-2
1-3
1-4
1-5
1-6
2-1
2-2
2-3
2-4
2-5
2-6
2-7
2-8
3-1
3-2
3-3
4-1
4-2
LIST OF FIGURES
Site Map--FWDA
General
Surface
Geology
Layout and Areas of Potential Contamination
Drainage Map
Map
Movement of Ground Water
Geologic Cross Sections A-A’ and B-B’ (Figure 1-4)
on and Near FWDA, McKinley County, New Mexico
Ammunition Workshop Area Sample Sites
Demolition Area Sample Sites
Administration, Igloo, andSample Sites
Location of Well Sites
Monitor Well Construction
Sample Boring Log for FWDA
Surface Water and Sediment
Soil Sampling Sites
Background Areas
Geotechnical Study
Sampling Sites
Flow Chart for Water Sample Organic Analyses
Flow Chart for Soil and Sediment Organic Analyses
Overview of Data Management Plan
Detail Map of Administration and Ammunition WorkshopArea Contamination
Demolition Area Contamination
533s
8
9
13
16
18
20
31
35
41
43
45
47
56
58
69
70
81
86
88
An Environmental
USATRAMAFR. l/WIN/INTRO. 19/17/81
1.0 INTRODUCTION
Survey of the Ft. Wingate Depot Activity (FWDA),
Gallup, New Mexico, (Figure 1-1) was conducted by Environmental Science
and Engineering, Inc. (ESE), Gainesville, Florida. The objective of the
Environmental Survey was to determine if hazardous materials from past
depot activities are migrating beyond depot boundaries or threatening
potable groundwater supplies. Since both surface and subsurface
pathways offer potential migration routes, the survey included sampling
of ground water, surface water and sediment, and soils. These samples
were analyzed under stringent quality control conditions for selected
organic and inorganic chemicals.
Sampling sites were selected using information from the records search
(Record Evaluation Report No. 136), the preliminary site survey,
interviews with the U.S. Army Toxic and Hazardous Materials Agency
(USATHAMA) and FWDA personnel, and a review of U.S. Geological Survey
(USGS) reports and other related material. Areas” identified as likelY
to contain some degree of contamination are shown on the site map for
FWDA (Figure 1-2). Thirty-eight individual sampling sites were selected
at FWDA. Of these, 10 were for collecting upgradient and downgradient
data for the base, and 28 were for detecting possible contaminants. The
individual sampling sites included 14 groundwater sites, 15 soil sites,
and 9 surface water and sediment sites.
1.1 STATEMENT OF WOK
The survey consisted of the following seven activities:
1. Preparation and submission to the government for approval of
the Detailed Sampling and Analysis Plan, Accident Prevention
Safety Program, Quality Control Plan, and Data Management Plan.
These reports incorporated the USATRAMA Quality Assurance and
Minimum Well Drilling Requirements and included discussions of
operations in all areas of potential contamination.
7
QALLUP
3AlE
ACllV~
II oN
SCALE 100
~ ‘“s100 KILOMErERS SOURCE: E“, 1900.100 0
Figura 1-1
SITE MAP--FWDA
ENViRONMENIAi. SURVEYFt. Wlngata Dapot Actlvlly
Gallup, Naw Maxico
U.S. ArmyToxic and Hazardous Materials Agency
Abardaan Proving Ground, Maryiand
8
G?‘Q@/9
2
@@21
I
● 2● 34s
● 67Is10
*1112
● la● M1s1811la1sso
● 21● SS● sa● SS%SE
57SE55m31
ADM AREA
WORKSMOPAREA●.O.L.DuMPou MOFILLPLuGRS?ARSTORAGELAN061 LL IWO 70 PRESENT
OEACTIVATIGNFuRM&CEDOE EWIPMENT STOMGE*UNCTIONTESf RANGEIIHOWFUNCTIOMTE~ RANGE2.SINCHROCKET1s65,s7
S70RAGEAREAA M lGLCCG-ORAGE AREAs la lG~STORAGEAREAC 37 IGI.~ETGnAGCAREAO l= tG-E70RAGEAREA E SGlG~STORAGEANEAF 3SlGLOOSSTORAGEAREAG 100lGLDOS-ORAGE AREAM IW IGLOOSSTORAGEAREAJW tGLODESTORAGEAREAK 27tGmDEMOLITIONAREASURN1?EGGRGuNO9URMIMG GRGuNOLANOFILLDOS EOUIPMSNTSTORAGSFUMCTION tSST aANGEIMINES.PMmES. ROCKETS WEWSS
RIFLSRANGE9MTEMl~l LELAUNCHEWEPERSNINGMISS4LEtiUNCN SITEwfEnuEN UKSLANOSPXWOSEOFOn EXCESSIW3m us FOnSSTRYSERVICEm “24ME’ER’● POTENTIAU.Y CONTAMINATED SITES
Flgura 1-2
GENERAL LAYOUT AND AREAS OF
POTENTIAL CONTAMINATION
SOURCE: ESE, lSSl.
ENVIRONMENTAL SURVEYFt. Wingata Dapot Activity
Gallup, Naw Maxico
Us. AfmvToxic and Hazardous M&lals Agency
Abardaen Proving Ground, MarylandI
9
USATiiAMAFR.1/WIN/INTRO. 2
9/17/81
1.2
Fort
2.
3.
4.
5.
6.
7.
Construction, instal ation, protection, development, and survey
of groundwater monitoring wells as determined necessary.
Collection and analysis of geohydrological data from the
monitoring wells.
Collection and chemical analysis of subsurface and surface
water, sediment, and soil samples.
Maintenance and operation of a field and laboratory quality
control program to ensure reliability, precision, and accuracy
of all generated data at a level compatible with the
environmental study programs of USATRAMA.
Maintenance and reporting of all field and laboratory data in a
format compatible with the data management system and minimum
requirements for boring logs and well sketches established by
USATHAMA .
Technical evaluation of all generated data and presentation of
an assessment of current and potential contaminant migration
from the boundaries of FWDA.
DEPOT HISTORY
Wingate was established in 1850 as a military outpost. In 1862,
the fort received the name Fort Wingate and was garrisoned by units of
the New Mexico Volunteers, the 37th U.S. Infantry, and the 3rd Cavalry.
At the beginning of World War I, the installation was designated as the
Fort Wingate General Ordnance Depot, with the mission to store trinitro-
toluene. The depot was the largest storage depot of high explosives in
the world.
The current FWDA dates back to February 25, 1941, when construction was
started on a new depot several miles west of the original Fort Wingate.
FWDA is located 11 miles east of Gallup, New Mexico, and occupies an
area of 34 square miles.
—
10
usATRAMAFR .1/wIN/IwRo.39/17/81
.
?%
In 1941, as the United States entered World War II, the installation
becmoe highly active with incoming and outbound shipments of high
explosives. Storage of ammunition other than trinitrotoluene began in
1942. Operations declined at the termination of World War II, but
increased again during the Korean and Southeast Asian conflicts.
Currently, FWDA operates under the Cowmend of Tooele Army Depot, Utah.
FWDA operates aa an active storage facility for care, preservation, and
maintenance of assigned commodities. Military tenant activities include
the U.S. Army Reserve and National Guard. More detailed information on
FWDA activities is included in the Installation Aeaeasment of Fort
Wingate Army Depot Activity, Record Evaluation Report No. 136 (USATRAMA,
1980).
1.3 ENVIRONMENTAL SETTING
1.3.1 METEOROLOGICAL DATA
The climate of this area of New Mexico ia generally dry with seasonal
changes, consistent with the classification of semi-desert biotic zone
aaaigned to the region. Annual precipitation in the area varies from
about 8 inches (in.) in the lower elevations to 20 in. in the Zuni
Mountains. Records at FWDA indicate that the average yearly rainfall is
11 in. Thunderstorms during the months of July, August, andSeptember
account for mst of this amount. Snowfall during the period from
December to March accounts for the remainder of the precipitation at the
site. The temperature ranges from an average winter value of -2.8”c to
an average summer value of 20.6”C. Daily temperature fluctuations of
17*C to 22°C are common.
1.3.2 TOPOGRAPHY AND DRAWAGE
FWDA is situated both in the Puerto River Valley and in the foothilla of
the Zuni Mountains. FWDA ia bounded on the west by a ridge of steeply
dipping sedimentary rocks called the Elogback. The southern boundary is
formed by the Zuni Mountains. To the eaat of FWDA, there is a small
valley which terminates at the base of the Zuni Mountains. The Puerto
11
USATHAMAPR.1 /WIN/INTRO.5
9/17/81
merge and reach alluvium-filled canyons and valley floors, deep,
steep-walled channels develop in the alluvium. These arroyos have low
to moderate gradients and can be quite wide. As these deeply cut
channels approach the flat valley floor, within which the Ammunition
Workshop and Administrative Areas of FWDA are located, they become
broad, shallow, and poorly defined. During
water flow, sheet flow becomes an important
northern portions of the depot.
periods of high surface
means of drainage in the
Nearly all drainage features were dry during November 1980 and January
1981, when the field operations associated with the current study were
undertaken. Several components, however, were active. The main arroyo
which drains the eastern side of the Hogback (i.e., the Demolition Area)
contained flowing water until it reached the culvert at the Demolition
Area gate. At this point, the rate of infiltration into the ground
exceeded the surface flow. The arroyo draining Fenced-Up Horse Valley,
a tributary of the main arroyo, was completely dry. From the culvert
north, the main arroyo was dry until it merged with another arroyo which
drained Igloo Areaa H and J. Surface flows were noted from this point
north until infiltration
The C-Area Pond, a small
arroyo, contained water,
exceeded flow in the vicinity of Igloo Area C.
impoundment on another tributary of the main
but inflow and outfall channels were dry.
D-Area Pond 425, selected as a background surface water sampling
during the initial visit to PWDA (November 1980), was completely
site
dry
during subsequent trips (January 1981).
Lake Knudson, located near the northern boundary
water, although the level was quite low. Inflow
were dry.
of PWDA, did have
and outflow channels
With the exception of a small stock-atering pond (fed by
on Eastern Patrol Road and the metal stock tanks in Igloo
remaining surface water features were devoid of water.
well) located
Area H, all
—
14
USATHAMAFR.1 /wIN/INTRO.69/17/81
1.3.3 GEOLOGY
Potable drinking water, in the vicinity of FUDA, is primarily from the
San Andres-Glorieta Aquifer. The San Andres Limestone and the Glorieta
Sandstone, both of Permian age, are exposed at an elevation of approxi-
mately 8,100 ft above MSL in the Zuni Mountains in the southeast region
of FWDA (Figures 1-3, 1-4, 1-5). From this location, these formation
dip steeply to the west and to the north. To the west, the San Andres
and the Glorieta are buried beneath a thick sequence of younger
sedimentary rocks composed of 10 different formations. From bottom to
top, these formations are:
1. Moenkopi Formation (claystone, siltatone, sandstone);
2. Chinle Formation (claystone, siltstone, sandstone, limestone);
3. Wingate Sandstone;
4. Entrada Sandstone;
5. Todilto Limestone;
6. Cow Springs Sandstone;
7. Morrison Formation (sandstone, congl~erate);
8. Dakota Sandstone;
9. Mancos Shale; and
10. Crevasse Canyon Formation (Gallup Sandstone, shale,
claystone).
Within FWDA property boundaries , only the Moenkopi Formation, the Chinle
Formation, and Quaternary alluvium overlie the San Andres-Glorieta
(Figures 1-4 and 1-5). Most of the remainder of the stratigraphic
column observed to the west is also present north of the Puerto River.
However, it appears that the Mancos Shale, Gallup Sandstone, and the
Crevasse Canyon Formation have been removed by erosion, leaving the
Dakota Sandstone as the top of the mesas in this area.
FWDA lies in an erosional basin formed by the Zuni Uplift, of which the
Zuni Mountains form the core. The steeply dipping rocks which form the
Hogback are the result of the draping of sediments over an assumed fault
in the Precambrian basement rocks underlying this region. The draping
15
A—A’
8—B’ }
LOCATION OF GEOLOQIC
.\ Ill
—.-OURC15 UBNHAMA, 1980.
ENVIRONMENTAL SURVEY
Figura 1-4 Ft. Wlngate Dapot Activity
GEOLOGY MAP – Gallup, Now Maxko
(CONTINUED, PAGE 1 OF 2) Us. /uWlyToxic and Hazardous Matarials Agancy
Abdaen Proving Ground, Maryland
16
Qal
Qal
Kmf
Kc
KS
Knl
Kd
Jmu
Jcs
Js
Jt
Je
TRw
TRCU)TRcm~
TRc 1)
TRcs
TRm
.
.
.
.
.
Veneer (Alluvium)
Alluvium
Menefee Fm - Sandatone, Clay=tone, Shale
Crevasse Canyon Fm - Sandstone, Shale, Claystone
Gallup Sandstone
Mancos Shale
Dakota Sandstone
Morrison Fm - West Water Canyon Member - Sandstone
ConglomerateCOW Springs - Sandstone
Sunsnerville Sandstone
Todilto Limestone
Entrada Sandstone
Wingate Sandstone
Chinle Formation -
Claystone, Siltstone,
Sandstone, Limestone
Shinarump Conglomerate
Moenkopi Fm - ClayStone, Siltatone, sandstone
San Andreas Limestone
Glorieta Sandstona
SOURCE:USATHAMA, 1S80.
Figure l-4
GEOLOGY MAP I=55=5_(CONTINUED, PAGE 2 OF 2) I Us. Army
Toxic and Hazardous Matarlals Agancy
Abardaan Proving Ground, Ma@md
war lablQIn Olwvhm
EXPLANATION
~%rmsoble rock unit. .
EzzRsmfkelyimpermoablo
rockunit
IFault
.
Mavemsnt ofwaterwithinaquifw
Figure 1-5
MOVEMENT OF GROUND WATER(Not to SC8hS)
~NVtRONMENTAL SURVEYFt. WhlgataDapot Activity
Gallup, Naw Maxtco
U.S. Army
Toxic and Hazardous Matedals AgencyAbardean Pruving Ground, Ma@md
18
usATHAMAFR .1/wIN/INmo.79/17/81
—
of sediments over this fau
which is known as the Nutr
t produced a fold in the sedimentary rocks
a Monocline.
At one point in the geologic past, the sedimentary rocks exposed in the
Hogback probably were continuous with the rocks exposed in the cliffs
north of the Puerto River. The Zuni Uplift forced the upward movement
of a large mass of material, and the area currently occupied by FWDA was
subjected to extreme tensional stresses. The rocks were evidently
extensively fractured and subsequently removed by erosion, leaving the
present-day basin. This is easily seen in the geologic cross-sections
presented in Figure 1-6. There is an upward bowing of bedrock beneath
FWDA, and some rock units , continuous in the area around FWOA, are
missing at the site. The numerous
throughout FWDA are formed by port:
have resisted erosion (Figure I-5)
.
. .
. .*.
i%
-,
ridges and hills distributed
ons of the Chinle Formation which
Surface exposures of several rock units described earlier constitute the
recharge areas for several aquifers. The San Andres Limestone and the
Glorieta Sandstone function hydrologically as a single aquifer unit and
provide water to FWDA via a single deep well (Figure 1-3). Recharge for
the aquifer occurs in the outcrop areas in the Zuni Mountains, where
water enters the San Andres-Glorieta aquifer and flows downgradient
(northward). The production well at FWDA taps the San Andrea-Glorieta
aquifer at a depth below land surface of 1,352 ft (equivalent to an
elevation of approximately 5,330 ft above MSL), almost 3,000 ft lower in
elevation than the outcrop areas in the southern region of FWDA.
The City of Gallup draws a major portion of its potable water supply
from the Gallup Sandstone aquifer, which receives part of its total
recharge from outcrops along the Hogback. The outcrop of the Gallup
Sandstone aquifer on the Hogback is approximately 7,500 ft above MSL.
Near the,City of Gallup (elevation 6,500 ft), the Gallup Sandstone
aquifer is at a shallow depth. The 1,000-ft difference in altitude is
indicative of the steepness of the dipping sandstone.
19
.-.
>1s%...,,, . ...**.,>..
“.0”.3. k.-....%..).
; }—
—
20
—
USATHAMAFR.l /WIN/INTRO.89/17/81
Y.
..._.
-.
The water table aquifer in the Puerto River area, north of ~A, can
locally produce significant amounts of water as documented in studies by
USGS (1971, 1975). The alluvial gravels of the Puerto River are capable
of producing approximately 100 gallons per minute (gpm) from a depth of
125 ft. This alluvial gravel would provide a rapid transport medium for
potentially contaminated ground water and/or surface runoff, if present
on FWDA.
Groundwater flow within the water table aquifer would only be possible
during wet portions of the year, specifically with the snowmelt in
spring. This flow would be expected to be at shallow depth (less than
50 ft) and would move from areas of high elevation (e.g., the Zuni
Mountains at the southern boundary of FWDA) to areas of lower elevation
(e.g., the Puerto River Valley, north of FWDA).
1.3.4 RATIONALE FOR SAMPLE mA SELECTION
A-unition Workshop Area
Beginning in 1949, munitions washout operations were conducted in the
500 series buildings area. Munitions were received in Building 500
where they were unpacked, broken down, and transported to Building 503.
There, a hot water~ operation was conducted for unmitions
containing trinitrotoluene, cyclotrimethylenetrinitrmine, and
Tritonal.
Red water from the trinitrotoluene washout was disposed of by draining
it into three settling tanks outside of Building 503 (Area 2,
Figure 1-2), from which it overflowed into “~ed immediately
north of the building. This leaching bed was used in the late 1940’s
and was deactivated when the building was renovated to accommodate
washout of larger nmnitions. The *in this bed were
removed to the Demolition Area for-g. The renovatedmvt
operations used ~ northeast of Building 503. These beds
were used until washout operations cease~” t During operation of
21
USATNAMAFR.l IWINIINTRO.99117181
the washout facility, the settling tanks were cleaned once a week, and
the residue was taken to the burning ground at the Demolition Area where
it was burned,
Building 515 housed the ammunition painting facility, and contained acid
tanka used for - prior to painting. The diluted
acid wastes from the pickling tanks were routed into an~~?”
st of Building 515. The material in this pond was
Currently, an agreement exists between FWDA and the City of Gallup, New
Mexico, whereby all garbage from FWDA is collected by the city and
hauled to a city-owned landfill for disposal. Trash from other
activities on the installation is buried within a landfill (Area 6 on
Figure 1-2) located just east of Storage Area B on the installation.
Waste material at this landfill is covered once a month. In addition,
the old landfill and burning area (Area 4 on Figure 1-2) was located
just north of the water storage tanks off North Patrol Road. Activity
in this area ceaaed h 1968. Surface runoff from these areas generally
is low and dissipates either through evaporation or infiltration. Any
runoff from the landfills is to the north into the Puerto River Valley.
The potentially contaminated areas within the Ammunition Workshop Area, ‘!
the acid disposal pit, trinitrotoluene washout leaching pits, triangular ,~
leaching pit, and current sanitary landfill, are situated o%- -- - ““
J_unconeo&idated alluvial. sediments (sand, silt, md c!?I). previously
existing data indicate that these sediments would be expected to be
approximately 30 ft deep and rest upon the consolidated rocks of the
Chinle Formation. ~Ground water was expected to exint”a; a &rched wat~______....... --—— ___ ———-table within the alluvial sediments. If signifi;&-t—contamination
--._..
exists in the area, the contaminants could possibly move both
horizontally and vertically toward potable water supplies. Of principal
concern would be the ability of contaminants to reach the highly
permeable and shallow gravels of the Puerto River.
22
—
USATHAMA.FR.l/WIN/INTRO .109/17/81
Demolition and Burning Ground Areas
The Demolition Area (Area 21 in Figure 1-2) haa been used as a disposal
ground for explosives-cont=inated material. Old equipment from the
trinitrotoluene drying and flaking operations was removed from
Building 503 during the renovation of the building and was disposed of
in the Demolition Area.
Two burning ground areas were located at FWDA.
in Figure 1-2) W>S used t<burn explosives and
The first area (Area 22
explosive-contminated
material froz@~ to.~~~fi) ‘l’hisburning ground was certified clean and
closed in 1955. The second area (Area 23 in Figure 1-2) is the current
area used for burning, and was started in 195s.
The geological setting of this area indicated that it was unlikely that
shallow ground water would be present during the dry season, but the
spring snowmelt would probably cause a short-term shallow groundwater
supply . Aquifer recharge areas exist nearby, but at a much higher
altitude. The determination of the degree of contamination present and
the potential effects upon the recharge areas was considered important.
Major drainage features originate in this area and drain to the north
toward the Puerto River valley. Potential contaminants could possibly
travel via this route.
Administration Area
The two potential contaminant sources within this area are the sewage
lagoon md the oil disposal/fluorspar sites. The main sewage treatment
plant (STP) is located on a flat, low area just west of the Administra-
tion Area. TheSTPconsists of a bar screen, lift station, I&off tank,
sludge beds, three stabilization ponds in series, and an evaPoration-
infiltration lagoon. The evaporation-infiltration rates generally equal
or exceed flow into the system. However, discharge from the system
(during periods of low evaporation, heavy rainstorm, or snowfalls) is
into an open drainage ditch north of the installation which drains
eventually into the South Fork of the Puerto River. Both of these
23
—
usATHAMAFR. 1/wIN/INTRO. 11
9/17/81
sources are n the alluvium-filled valley of the South Fork of the
Puerto River. Although there was the possibility that no shallow ground
water existed during the dry season, monitor wells were constructed to
intercept any existing perched water tables. Potential contaminants
from this area could possibly reach the Puerto River via subsurface
flow, or by surface runoff.
Property Boundary Area
The northern property boundary of PWDA was selected as a sampling area
because it is the area toward which all ground end surface water flows.
The adjacent Puerto River is the ultimate receiving water for both
stormwater and wastewater treatment plant effluent, if any.
Background Areaa
Background areas were selected to determine naturally occurring
concentration of analytes for all sampled mediums. These areas were
distributed throughout FWDA.
1.4 TECHNICAL APPROACH
An initial survey of FWDA was made by key members of the ESE project
team in conjunction with USATHAMA and FWDA personnel who defined, on
site, the approach to the Environmental Survey. In addition, Army
personnel provided essential background information which affected the
determination of sample points and analyses required.
As a result of the visit to FWDA and a search of the available
literature (see Section 6.0), including the USATEAMA Records Search,
ESE’S project teem identified the proposed sampling points and
analytical requirements for determining the extent of munition end other
pollutant contamination. The Detailed Sampling and Analysis Plan,
Accident Prevention Safety Program, Quality Control Plan, and Data
Management Plan, presenting in detail the approach that ESE was taking
in performing the Environmental Survey, were submitted to USATHAMA in
November 1980 and finalized by December 1980.
24
—. —
USATNAMAFR. l/WIN/INTRO. 129/17/81
Field efforts began in November 1980. A survey of the well locations
was conducted by Stitzer and Associates in November. Well dri
began in early November and was completed within 2 weeks.
FWDA was sampled from January 22 to 26, 1981. Samples were sh:
1ing
pped by
air, arriving in Gainesville within 24 hours of sample collection. ‘l’he
samples were processed and stored at ESE’S laboratories in keeping with
the chain-of-custody procedures practiced at ESE. Analyaes occurred
within holding times, subject to procedures outlined in the August 1980
Quality Control Plan.
Data were evaluated and presented to USATHAMA in April 1981. Final data
validation and entry to the USA2’SAMA Installation Restoration Data
Management System were completed in tiy 1981.
. .
.,
25
usATNANAFR.2/wIN/Fs .1
9/17f81
2.0 FIELD STUDIES
The field sampling
groundwater, soil,
program included those activities necessary to obtain
and surface water and sediment samples at selected
sites at FWDA. The program consisted of both geotechnical and sample
collection activities.
A total of 38 ssmpling sites was selected based on information from the
FWDA records search, ESE’S on-site survey, interviews with USATNANA and
FWDA personnel, and a review of USGS reports and other related material.
Most of these sample sites were located in the Ammunition Workshop Area,
the Administration Area, Igloo Areas A and C, and the Demolition Area.
Background samples were collected at upgradient and downgradient sites
near the base perimeter and at selected springs and tanks.
The individual sites included 14 groundwater sites, 15 soil sites, and
9 surface water and sediment sites. At surface water sites, bo~h a
water and sediment sample were collected, if possible. The dry
condition of many of the watercourses allowed only a sediment sample to
be collected. The sampling site selection rationale, number of samples,
and procedure for the geotechnical and sampling activities are presented
in the following sections.
2.1 RATIONALE FOR SAMFLING SITE SELECTION
2.1.1 AMMUNITION WORKSHOP AREA
The Ammunition Workshop Area contains the remains of an acid disposal
pit and two trinitrotoluene washout leaching pits. Because of the
nature of the activities conducted here, this site was considered to be
a potentially contaminated area. Seven soil sites, one surface water
and sediment site, and seven monitor well sites were selected for
contamination assessment. Table 2-1 describes well locations and
26
—
-%!
. .
.
FW06
FW09
USATHAMAFR. 2/FS/VTE2-1 .1
9/17/81
Table 2-1. Ammunition Workshop Area Soil Siting Rationale
SiteNumber Siting Rationale
FWO 1 —Downgradient (north) of currentsanitary landfill to detectpotential contamination.
—Within acid disposal pit toquantify amount of contamination.
—Within triangular leaching pitto quantify amount of contsmina-
FW14
FW15
FW16
tion.
—Within leachingquantify amount
—Within leachingquantify mnount
pit (eastern) toof contamination.
pit (western) toof contamination.
‘In overflow ditch west of leach-ing pits to detect downgradientmigration of contaminants viasurface runoff.
FW17 —To detect downgradient migrationof potential contamination fromtriangular pit via this ditch.
Source: ESE, 1981.-.
27
usATNAMAFR.2/wIN/Fs.2
9/17/81
rationale for siting; Table 2-2 lists soil sampling sites and siting
rationale; and Table 2-3 lists surface water and sediment sampling sites
and rationale. These sites are mapped in Figure 2-1.
The geologic environment of the Aumtunition Workshop Area indicated that
shallow perched ground water may be present during times of high surface
water activity (e.g., snowmelt in spring). The sandy alluvium in the
area would be capable of transporting quantities of ground water down-
gradient toward the property boundary to the north. The sampling
program was designed to determine the level of contamination within
washout leaching beds, and then to determine if contaminants have
migrated downgradient via surface water runoff or shallow groundwater
flow.
2.1.2 DEMOLITION AND BURNING GROUND AREA
The primary activity in this area has been the destruction of a wide
variety of ordnance materials. One well, four soil sites, and four
surface water and sediment sites were sampled. Table 2-4 lists soil
sampling sites and siting rationale; Table 2-5 lists surface water and
sediment sampling sites and rationale; and Table 2-6 describes well
locations and rationale for siting. These sites are shown on
Figure 2-2.
This area is located in the topographically higher regions of FWDA.
Recharge to major aquifers occurs near this area, and the sampling
program waa developed with attention to the spatial relationships of
contaminated areaa and recharge areas. Bedrock ia either exposed or at
very shallow deptha in this area, except in the narrow alluvium-filled
arroyos. The sampling sites were, therefore, concentrated within the
major drainageways or within known burning and demolition grounds.
2.1.3 ADMINISTRATION ARSA
The Administration Area containa two locations which are potentially
contaminated, the sewage lagoon area and the area containing the oil
28
..
usATliAMAFR.2/Fs/vTB2-2. 19/17/81
Table 2-2. Ammunition Workshop Area Surface Water and Sediment SitingRationale
SiteNumber Siting Rationale
Fli30 —To determine whether impounded
surface runoff from Ammunitionstorage areaa to the south hascontaminated lake and sediments.
Source: ESE, 1981.
--
29
USATHAMAFR. 2/Fs/vTB2-3. 19/17/81
Table 2-3. Ammunition Workshop Area Monitor Well Siting Rationale
SiteNumber Siting Rationale
FW07 —Downgradient (north) of aciddisposal pit to detect potentialcontaminants.
FW08 —Upgradient (south) of aciddisposal pit and Ammunition Work-shop Area to define incominggroundwater quality and todetermine depth to bedrock inthis area.
FWICI
FW11
FW12
FW13
FW35
—Upgradient (southeast) ofleaching pits and AomwnitioriWorkshop Area, to define incominggroundwater quality and todetermine depth to bedrock.
—Downgradient (northeast) ofleaching pits to detect potentialcontaminants.
—Downgrsdient (north) of leaching
pits to detect potentialcontaminants.
—Downgradient (northwest) ofleaching pits to detect potentialcontsminanta.
—Downgradient of Lake Knudson todetermine if impounded surfacerunoff in lake is allowingcontaminants to migrate towardnorthern property boundary
(downgradient) via shallowgroundwater system.
—
Source: ESE, 1981.
30
s 1~
Sounce Eaa,lem.
‘Igure 2-1 ENVIRONMENTAL SIJRVEYhMMUNITION WORKSHOP AREA Pt. WingataDapolActivity3AMPLE SITES Gallup,NawMEXICO
U.S. ArmyToxic and Hazardous Matariais Agancy
Abardaan Proving Ground, Maryiand
31
USA~R.2/F5/VTB2 -4.l9/17/81
Table 2-4. Demolition Area Soil Siting Rationale
SiteNumber Siting Rationale
FW19 —Within old demolition ground toquantify amount of contamina-tion.
FW21
FW20 -Within old burning ground toquantify amount of contsmina-tion.
—Within old burning ground toquantify amount of contamina-tion.
FW32 —Within the drywash leading fromthe old burning ground to detectpotential contaminants migratingvia surface runoff.
Source: ESE, 1981.
—
—
—
—
—
32
USATHAMAFR.2/FS/VTB2-5 .19/17/81
Table 2-5. Demolition Area Surface Water and Sediment Siting Rationale
SiteNumber Siting Rationale
FW18 —Within active demolition ground
to quantify level of contamina-tion present.
FW22 —At intersection of arroyosdraining old and new DemolitionAreas to quantify existingcontamination.
FW23 —From arroyo, further downgradient(north) than FW22.
FW24 —From arroyo, further downgradient
(north) than Fw23.
Source: ESE, 1981.
%
>,
33
USATRAMAFR. 2/FS/VTB2-6 .19/17/81
tion Area Monitor Well Siting RationaleTable 2-6. Demol
SiteNumber Siting Rationale
FW24 —Downgradient of Demolition Area,next to arroyo draining the sameareas to detect potentialcontamination moving down-gradient (north).
Source: ESE, 1981.
—
-.
34
35
USA~R.2/WIN/FS.3
9/17/81
disposal and fluorspar sites. Both of these locations are in the
alluvium-filled valley of the South Fork of the Puerto River. Two
monitor wells were sampled in this area. Table 2-7 describes the
location and rationale for siting of these wells. The geologic setting
of this area is nearly identical to that of the Ammnition Workshop
Area. Sandy alluvium appeared to be capable of transporting shallow
ground water downgradient (to the north). The umnitor wells in this
area were sited downgradient of the potential contaminant sources. The
STP lagoons provide an artificial source of shallow ground water, and
the mnitor well downgradient of the lagoons was intended to also
determine the alluvium’s ability to transmit ground water.
2.1.4 OTNER AREAS
Property boundaries and background sites were sampled
potential contaminants were migrating off property to
determine natural background levels of all analytes.
and 2-10 describe site locations and siting rationale
sampling sites, surface water and sediment sites, and
sites, respectively (see Figure 2-3).
to determine if
the north, and to
Tables 2-8, 2-9,
for wells, soil
well sampling
The geologic environment of FWDA strongly favors water movement along
relatively narrow and well-defined watercourses. As a result, sampling
sites were concentrated within or near these features. Monitor wells
were sited to detect perched water tables near these drainageways.
2.2 WELL INSTALLATION/GROUNDWATER SAMPLING
The geotechnical activities at FWDA included the drilling, logging, and
construction of 14 water quality sampling wells. The sample site
number, location, and depth of these wells are listed in Table 2-11.
Locations of the wells are shown in Figure 2-4. Dry holes which were
drilled were constructed as wells to make them available for sampling
during spring high water.
36
usATHAUAFR.2/Fs/wB2-7. 19/17/81
,
Table 2-7. Administration Area Monitor Well Siting Rationale
SiteNumber Siting Rationale
Fw26 —Downgradient (north) of oildisposal area and fluorsparstorage pile to detect potentialcontaminants.
FW29 —Downgradient (north) of STP pondsto detect potential cont~inants.
Source: ESE, 1981.
37
USATHAMAFR. 2/FS/VTB2-8 .19/17/81
Table 2-8. Other Area Soil Siting Rationale
SiteNumber Siting Rationale
FW04 —In dry ravine containing muni-tions container refuse todetect potential contaminants.
FW33 —In drainageuay near Well FW27 todetect potential contaminantsat property boundary.
FW34 —In drainageway near Well FW28 to
detect potential contaminants atproperty boundary.
Source: ESE, 1981.
—
—.
38 I{_
USATllAMAFR.2/FS/VTB2-9 .1
‘3/17/81
.Table 2-9. Other Areas Surface Water and Sediment Siting Rationale
SiteNumber Siting Rationale
FW02 —D-Area Pond 425, to detectpotential contamination frommunitions storage activities.
FW03
FW05
FW37
--C-Area Pond, to detect potentialcontamination from munitionsstorage activities.
-Opposite Igloo C-1119, to detectpotential contamination from❑unition storage activities.
—East of the Demolition Area, to
detect migration potential ofdemolition activities contamina-tion.
Source: ESE, 1981.
m
*. ,,.
39
Table 2-10. Other Areas Monitor Well Siting
usATHAMAFR.2/Fs/vTB2-lo. 19/17f81
Rationale
SiteNumber Siting Rationale
FW27 —Located next to a drainaflewav(eastern half) leading o~f -property (north) to detectpotential contamination fromactivities.
FW28 —Located next to drainageway(western half) leading offproperty (north) to detect
FWDA
FW3 1
FW36
potential contamination in theshallow ground water as it flowsoff property.
—Background well (upgradient)located on East Patrol Road nearFt. Wingate School to define in-coming groundwater quality.
—Deep well in Administration Areaused for quality control samplesand well drilling fluid.
Source: ESE, 1981.
40
Y“—-—..
:igure 2-3IIDMINISTRATION, IGLOO, ANDBACKGROUND AREAS SAMPLE SITES
/1 SOURCt2ES~ 1981
ENVIRONMENTAL SURVEYFt. Wingata Dapot Activity
Gallup, MW MSXICO
U.S. AmyToxic and Hazardous Matadals Agency
Abardaan Proving Ground, Maryland
41
.
USATRAMAFR.2/FS/VTB2-11 .19/17/81
Table 2-11. FWDA Groundwater Sampling Sites
DepthSite Number Location (feet)
Ammunition Workshop Area
FW07FW08FW1 OFW11FW12FW13FW35
Demolition Area
FW24
Administration Area
FW26
FW29
FW36 (FwOOGW)
Igloo Area A
FW27
FW28
Other Areas
FW31
North of Acid Pit 26Upgradient of Acid Pit 49Upgradient of Leaching Pits 49Northeast of Leaching-PitsNorth of Leaching PitsWest of Leaching PitsLake Knudson Downgradient
North of Demolition AreaEntrance and Building 601
North of Oil Disposal andFluorspar Pile
North of Sewage PondsDeep Well (Drill Water
Source)
North Boundary Road, EastDrainage
North Boundary Road, WestDrainage
East Patrol Road,Upgradient Well
282930.530
23
3130
1,650
30
33
50
Source: ESE, 1981.
42
!
I.
/
,,.1/
SOURCE ES& 1SS1.
ENVIRONMENTAL SURVEYFiguns 2-4
LOCATION OF WELL SITESFt. Wingata Dapot Activity
GaiiuP, Naw Maxico
U.S. AmIyToxic and Hazardous Matariais Agancy
Abardaan Proving Ground, Maryiand
All wells were dri,
following section.
USATHAMAFR.2/VTIN/FS.4
9/17/81
led, logged, and constructed as specified in the
All drilling sites were surveyed by Stitzer &
Associates surveying and engineering company. The surveyor obtained all
the necessary benchmark information from the Corps of Engineers and
installed a reference marker at each drilling site prior to drilling.
2.2.1 WELL DESIGN AND CONSTRUCTION
Sampling wells constructed at FWDA were
surface stratigraphy and ground water.
constructed to maximize the probability
used to investigate both near
The monitor wells were
of obtaining a representative
sample of shallow ground water (if available) and intercepting any
leachate plume. Construction of the wells follows the design ahown in
Figure 2-5. Wells constructed in the Ammunition Workshop Area were
constructed with a 4-ft riser to prevent flooding of the wells during
peak spring runoff. Each well was constructed in an 8-in. diameter hole
drilled to the depth presented in Table 2-11. This table shows actual,
not intended, depths resulting from these considerations. Bedrock was
not encountered in the drilling of any of the FWDA monitor wells.
An ESE geologist supervised the drilling of the wellsi maintained
detailed drilling logs, and collected appropriate aemples. The drilling
was performed by a subcontractor and proceeded as follows:
1. Unchlorinated water for drilling and well installations was
obtained from the deep well, Site 1948.
2. An 8-in. hole was drilled using hollow-stem augers. This
allowed the collection of soil samples through the barrel of
the auger.
3. During the drilling of each hole, soil samples were collected
continuously for the first 10 ft and at every 5 ft or at each
major stratigraphic change following, whichever occurred
first.
4. The soil samples were collected by using driven samplers of the
split barrel types. Weight of hammer, diameter of sampler,
number of blows, drop distance, penetration distance, and
length of sample recovered were recorded.
44
2fmfr
OROUND m 4:,
L<:;j-,,;:,:;
,0/
mAMErER)
‘-E--Er
M,..5;; ;5/
;:;
~=(3T05~
:..
::; 1 PooT ::.
.**. ●**”● . ●**
. . Pvc WELL~ (vARIAalELaNQTH):**’* .***. . .
Elr;.
● ●-●*
● ●*●.●●*●.QRAVR PACK
● .●*
●“.●* :*:.●*
● * .
9V●“: ●
.: ● >“9* ●*:: : ●*
. ..> .0●. ●:*●* .*.: :...*9 “::.
-.
aounaa Eaa, 1220.
ENVIRONMENTAL SURVEY
Figure 2-5 Ft. Whlgata Dapot Actfvity
MONITOR WELL CONSTRUCTION Gallup, Naw Maxico
Us. Army
Toxic and Hazardoua Materials AgancyAbardaan Pmvlng Ground, Matyland
45
USATNAMAFR.2/WIN/FS.59/17/81
5. Between borings, the drilling tools were thoroughly cleaned
with unchlorinated water from the approved source to prevent
cross-contamination.
Sample Description and Logging Procedures
Each boring was fully described on the boring log (shown in Figure 2-6)
as it was being drilled. Well profilea which show lithology and Unified
Soil Classification System (USCS) abbreviations plotted by elevation are
provided in Appendix A. Original well logs were provided to USATNAMA.
Data which were included in the logs, when applicable, are listed below.
These requirements and procedures conform to the USATHAMA minimal
requirements for boring logs.
1. Depths were recorded in ft and decimal fractions thereof.
Metric measurements only were entered on the data entry forms.
2. Soil descriptions were in accordance with the USCS. These
descriptions were prepared in the field by the ESE geologist.
3. Soil samples were fully described on the log. The description
included:
a. Classification;
b. USCS symbol;
c. Secondary components and estimated percentage;
d. Color (using Munsell Soil Color Chart);
e. Plasticity;
f. Consistency (cohesive soil) and density (noncohesive
soil);
g. Moisture content;
h. Texture/fabric/bedding; and
i. Depoaitional environment.
4. Numerical, visual estimates were made of secondary soil
constituents. If such terms as “trace, “ “some,” or “several,”
were used, their quantitative meaning was defined on each log
or with a general legend.
5. The length of sample recovered for each sampled interval was
recorded.
46
)ring No. Location Coordinates N
]le Size slot g
:reen Length Mat’1 Filter Materials
Lameter Mat’1 Grout Type
~sing Length Mat’1 Development
Lameter Static Water Level
lte Start Finish Top of I&ll Elevation
‘ound Elevation Depth to Water
?pth Sketch of Standard Penetrationfeet) Sample Lithology, Color Construction Blow Count
aOUaC&Ea&lm
ENVIRONMENTAL SURVEYFigura 2-6SAMPLE BORING LOQ FOR FWDA
Ft. wlngate Dapot Acnvlty
GEOTECHNICAL STUDYGallup, Naw Maxico
(REDUCED) Us. Amly
(PAGE 1 0=2) Toxic and Hazardous Matadda AgancyAbardwn Proving Ground, Mafyland
47
Boring No. Sheet of—.
Figura 2-6
SAMPLE BORING LOG FOR FWDAGEOTECHNICAL STUDY(REDUCED)(CONTINUED, PAGE 2 OF 2)
Date Signed
aouR* Esa,Ioaa
ENVIRONMENTAL SURVEYFt. whlg8t9DapotActMty
Gallup, Naw Maxlco
U.S. ArmyToxic and Hazurdous MatarialsAgancy
Abardaan Proving Ground, Matyland
—
48
6.
7.
8.
9.
10.
11.
12.
13.
14.
15.
16.
USATHAMAFR.2/WIN/FS.69/17/81
B1OW counts, hammer weight, and length of fall for split spoon
were recorded.
Minimum information on the sample container included the boring
and sample number.
The estimated interval for each sample was specified.
Depth to water was indicated along with the method of
determination, as first encountered during drilling. Any
distinct water-bearing zones below this first one also were
noted.
The drilling equipment used was generally described either on
each log or in a general legend including such information as
rod size, bit type, pump type, rig manufacturer, and model.
Each log recorded the drilling sequence.
All special problems were recorded.
The dates for the start and completion of any boring were
recorded on the log.
Lithologic boundaries were noted on the boring log.
The boring logs were submitted directly from the field to the
Contracting Officer’s Representative (COR) within 3 working
days after the boring was completed.
Only the original log and sketch(es) were submitted to COR to
fulfill this requirement.
A sketch of the well installation was included on the boring log and
showed, by depth, the bottom of the boring, screen location, coupling
location~ granular backfills seals$ grout , cave-in, and height of riser
above ground surface. The actual composition of the grout, seals, and
granular backfill was also recorded on each sketch. Well sketches also
included the protective casing detail.
Well Installation
When the boring was complete, the ESE geologist inapec.ted the hole to
ensure plumbness and cleanliness. The well screen and casing were
carefully cleaned with unchlorinated water from the deep well prior to
49
USATlLM4AFR.2/TJINfFS.7
9/17/81
installation in the hole. The specifics of length of screen versus
solid casing were field determined (generally, however, the gravel/sand
pack was placed around the screen to at least 1 ft above the estimated
seasonally high water table).
As the 3-ft bentonite seal was placed on top of the filter material,
unchlorinated water from the deep well was added, if necessary, to
ensure that the pellets expended to form a tight seal.
The gel-cement grout seal extended from the top of the bentonite seal to
the land surface. Grouting waa completed as a continuous operation in
the presence of the ESE geologist. The grout was placed into the
amular space to ensure that there was a continuous grout seal. The
protective casing was sealed in the grout, as shown in Figure 2-5.
Three 6-ft steel posts were driven 2 ft into the ground, 4 ft from the
well, and strung with barbed wire to enclose the well against livestock
grazing in the vicinity.
The following materials were used in well construction:
1.
2.
3.
4.
Casing used in the well was PVC
welded joints. The well screen
width was 0.01 in.
Grout was composed by weight of
Sctiedule 40 with solvent-
was factory slotted. slot
six parts cement to one part
bentonite, with just enough approved unchlorinated water for a
pumpable mix.
Bentonite pellets used in the seal were a commercially
available product designed for well sealing purposes.
The well graded silica sand used in the filter envelope around
the well screen was selected to be compatible with both the
screen slot size and the natural subsurface materials end was
approved by USATNAMA. At lesst one sample (1/2 to 1 pint in
volume) of the granular backfill used as part of a well
installation was taken from each shipment of granular material,
and stored with the soil samples.
50
USATXAt4AFR.2/UIN/Fs .89/17/81
The well site was surveyed and marked prior to drilling, with the
finished well tied into’the mark by a hand level and measurement
adjustment. Vertical control for the ground surface and top of each
well casing (not protective casing) at each boring/monitor well was
established within + 0.1 ft.
Well Development
Since water was not encountered during the drilling operations, well
development activities were not performed.
2.2.2 SAMPLING TECHNIQUES
Groundwater sampling began approximately 6 weeks after installation of
the monitor wells. The groundwater sampling program produced five
samples. One,well was sampled in duplicate to provide data concerning
the variability in the data associated with field sampling.
The following subsurface water sampling procedures were followed:
1. The depth to water was measured.
2. Samples were taken after the fluid in the screen and well
casing had been exchanged a number of times (preferably five
times). However, due to the soil types, some wells had slow
recovery rates. These wells had the fluid exchanged at least
twice. Sampling was accomplished by a bailer constructed of
Pvc .
3. To protect the wells from contamination during sampling
procedures, a separate bailer was supplied for, and attached
to, each well. This bailer remained in place in the well
during the mnitoring phases. The sample was collected in a
manner which minimized its aeration and prevented oxidation of
reduced compounds in the sample. The container was filled to
the top without air bubbles and tightly stoppered. The metals
fraction was vacuum filtered through a 0.45-micron filter,
chilled to 4“C, appropriately preserved (Table 2-12), and
immediately transported to the laboratory.
51
USATHAnA.FR.2/WIN/FS.9
9/17/81
4. On-site measurements of water quality included conductivity and
depth of wells from the topographical surface to the surface of
the well water.
Essentially inert PVC well casings were used in this program since
stainless steel casings would have been prohibitively expensive.
However, three potential problems may be associated with the use of PVC
for sampling organic parameters. First, adsorption of certain compounds
in the plastic could affect the apparent groundwater concentration.
Second, phthalate plasticizers could be introduced into the samples.
Third, compounds preeent in the PVC cleaner or cement could contaminate
the esmples. To minimize the effect of these potential probleme, each
well was pumped and then sampled as soon as sufficient water returned
(typically less than 5 minutee). The contact time between the water
sample and the PVC well casing was kept to the shortest poseible
period.
Each esmple fraction wae carefully labeled so that it could be identi-
fied by laboratory personnel. The sample label included the project
number, sample number, time and date, and sampler’s initials. Al1
samples were identified with a standard preprinted and prenumbered label
immediately after collection. Information concerning preservation
methods, ‘matrix, and sample location was included on the label. As a
further precaution, each sample container was marked with water-
insoluble ink.
For data to be valid, samples had to arrive at the laboratory unaltered.
To accomplish this objective, several fractions were collected at each
site and preserved. Table 2-12 lists the containers, volumes, and
preservative technique employed for water ssmplee. Samples were
shipped in styrofosm ice cheets and were kept at 4°C from time of sample
collection until analysis.
52
USATHAMAFR.21FSIVTB2-12.19/15/81
Y
Table 2-12. Water Sample Preservation Techniques
Analysis/ Container Holding
Parameter Type Vo1ume Preservation* Time (days)
L
GC/MS andHPLC ScreenPicric Acid
Volatile Organics
GC/HPLC AnalysesPesticidesPCBNitroaromatics
TetrylRDx
White Phosphorus
Metals
Acid AnionsPhosphate,Total
Nitrate +Nitrite
Sul fate
Amber GlassBottle
Septum Vials
Amber GlassBottle
Amber GlassBottle
PlasticCubitainer
PlasticCubitainer
PlasticCubitainer
PlasticCubitainer
2x1 gal
2x60 ml
1 gal
1 gal
250 ml
1 liter
1 liter
1 liter
Chill to 4*C
Chill to 4-C
Chill to 4°C
Chill to 4*C
Acidify withconcentratedHN03 to pH<2
Acidify withconcentratedH2S04 to pH<2
Chill to 4°C
Chill to 4°C
7
7
7
7
180
1
1
7
* All samples were chilled to 4*C at time of collection and kept at
y or below that temperature.
Source: ESE, 1981.
%
7.
53
.
usATHAMAFR.2/wINIFs. 109/17/81
2.3 SURFACE WATER AND SEDIMENT SAMPLING
Surface water and sediment samples were both taken at each location
where water was available. Bottom sediment samples were taken at
stations which were dry. Sample station locations are identified in
Table 2-13 and Figure 2-7. Surface water was collected as grab samples,
directly filling containers at the sample points.
Sediment samples were collected at all stations with a Ponar sampler.
When sediments encountered were composed of gravel and small rocks, post
hole diggers were used for sampling. Sediment samples were placed in
l-quart glass containers with Teflon-lined lids, shipped under ice, and
stored at 4*C.
Samples were labeled, preserved, and shipped in the same manner as were
groundwater samples.
2.4 SOIL SAMPLING
Soil samples were taken at representative locations at each site
(Table 2-14 and Figure 2-8). Surface vegetation, rocks, leaves, and
debris were removed prior to sampling. Each sample was taken from the
surface to a depth of 2 ft with a post hole digger, quartered to
approximately l~ound size, end placed in glass containers with
Teflon@-lined lids. These containers were labeled with a preprinted
label, chilled to 4*C, and shipped to the laboratory for analysis.
Soil Sample Number 1934 was obtained using a soil auger. A 6-ft-deep
s=ple was obtained and composite. Sampling equipment was thoroughly
cleaned, with water from the deep well, between sampling locations.
54
USATNAMAFR.2/FS/VTE2-13 .1
9/17/81
Table 2-13. Surface Water and Sediment Sampling Sites
Site Number Location
Ammunition Workshop Area
FW30
Igloo Areas C and D
FW03FW05FW02 (FWOOSW and
Background)
Demolition Area
FW18FW22
FW23FW24FW37
Lake Knudson
C-Area PondOpposite C-1119
FWOOSE , D-Area Pond 425
Pond Near Active AreaOld and New Demolitim
Area DrainageMasonry DamNear Well FW25Metal Stock Tank
Source: ESE, 1981.
55
9/17/81
Table 2-14. Soil Sampling Sites
Site NumberDepth
Location (feet)
Ammunition Workshop Area
FWOOSO (Background) Near FW1OFWO1
2Current Sanitary Landfill
FW062
Center of Acid PitFW09
2Center of Triangle Pit
FW142
Center of Leaching BedFW15
6Center of Leaching Bed
FW166
Ditch West of Leaching Bed 2FW17 Drainageway of Triangle Pit 2
Demolition Area
FW19 Old Demolition AreaFW20
2Old Burning Ground
FW214
Old Burning GroundFW32
4Drywash From OldBurning Ground 2
Igloo Area A
FW33 Ditch Near Well FW27FW34
2Ditch Near Well Fw28 2
Igloo Area C
FW04 Dry Ravine ContainingMunitions Container Refuse 2
Source: ESE, 1981.
57
——*-\\.
. \r---->--,.,~,1 , ‘, ‘.1
d
i ,“”7 SOURCE SSIE.1ss1..-- #--- .. -., . . .
I ENVIRONMENTAL SURVEY
~9U~ 2-8
SOIL SAMPUNQ SITESI Ft. wlngsta Dspot Acuvny
Gallup, W Msldco
Us. ArmyToxk and Hazmkus Mataflals Agancy
Abardaon Proving Qmund, Maryland
USATHAMAFR. 2/WIN /l.AB.19/17/81
-,3.1 CHEMICAL ANALYSIS
3.1.1 CERTIFICATION OF
3.0 LABORATORY STUDIES
METHODS
For semi-quantitative methods, spiked samples of standard media
(standard water or soil) were analyzed at concentrations of 0.5X, X, 2X,
5X, and 10X, where X was the desired/required detection limit. A blank
was also run. The detection limit was calculated by the method of
Hubaux and Vos (1970) from the results of these analyses. The reported
detection limit was not less
For quantitative methods, pr(
analyzing spikes of standard
5X, and 10X, where X was the
was also run. One replicate
of 4 separate days. The CO1
than the lowest spiked standard sample.
cision and accuracy data were generated by
samples at concentrations of 0.5X, X, 2X,
desired/required detection limit. A blank
at each concentration was analyzed on each
ective data were subjected to the Hubaux
and Vos detection limit program. The reported detection limit was not
less than the lowest spiked standard sample. Precision and accuracy
were calculated from the standard error and slope of the best-fit linear
regression line.
A sunmtary of analyses performed and certification status are presented
in Tables 3-1 and 3-2.
In the gas chromatography/~ss spectroscopy (GC/MS) semi-quantitative
screening certification, the detection limit for the various priority
pollutants and other specific compounds was calculated by analysis of
standard matrices spiked with solutions containing at least five of the
priority pollutant acid compounds, five of the base/neutral compounds,
and five of the volatile compounds. The munitions-reIated priority
pollutant compounds 2,6-dinitrotoluene and 4,6-dinitro-o-cresol were
.—
59
USATHAMAFR.2/WIN/VTB3-l .1
9/15/81
Table 3-1. Analyses for which ESE has been Certified by USA~--
Quantitative Methods
DetectionTest
CompoundLimit
Medium Name Number (ppb)
Nitrobenzene WA (Water) NBSO (Soil) NE
2,4-Dinitrotoluene WA 24DNTso 24DNT
2,6-Dinitrotoluene WA 26DNTso 26DNT
l,3-Dinitrobenzene WA 13DNBso 13DNB
l,3,5-Trinitrobenzene WA 135TNBso 135TNB
2,4,6-Trinitrotoluene WA 246TNTso 246TNT
Tetryl WA Tetrylso Tetryl
RDX WA RDx(cyclotrimethylenetrinitramine) SO RDx
Silver WA AGArsenic WA ASBeryllium WA BECadmium WA CDChromium WA CRCopper WA CuMercury WA HGNickel WA NILead WA PBAnt imony WA SBSelenium WA SEThallium WA TLZinc WA ZNNitrate WA N03
so N03Total Phoaphatea WA TP04
so TP04Sulfate WA S04
so S04
lKlLlKlLlKlLlKlLlKlLlKlLlKlL2B2ClBlBlBlBlBIBlDlBlBlBlBlBlMmlT2G2HlWIV
171,6403.02233.84194.8
3179.7
1,0801.4194
23.91,50010.52886.310.09.53.77.329
0.47.61139
8.67.134
0.01300
0.027904.0
259,000
Source: USATHAMA, 1981.
60
USATHAMAFR.2/WIN/VTB3-2. 19/17/81
Table 3-2. Analyses for which ESE has been Certified by USATHAMA—Semi-Quantitative Methods
DetectionTest Limit
Compound Medium Name Number (ppb)
Acid Fraction2,4-Dimethylphenol WA (Water)
SO (Soil)WAsoWAsoWAsoWAsoWAso
24DMPN24DMPN4CL3C4CL3C46D?J2c46DN2CPCPPCPPHENOL
lxlYlxlYlxlYlxlYlxlYlxlY
lZ2AlZ2AlZ2AlZ2AlZ2AlZ2AlZ2AlZ2AlZ2Alz2Alz2AlZ2AlZ2A
2J2J
2J2J
9.06008.060020
5009.040020
2008.0100
2.04004.0
1,00020
4,00020
4,0004.041920
3,0001.04003.04002.04001.0
1,0005.0
1,0001.0
4,0001.0
2,000
0.50.5
0.51.0
3-Methyl-4-chlorophenol
2-Methyl-4,6-dinitrophenol
.Pentachlorophenol
Phenol
2,4,6-Trichlorophenol 246TCP246TCP
.
Base/Neutral FractionNaphthalene
1,2,4-Trichlorobenzene
2-Amino-4,6-dinitrotoluene
WAsoWAsoWAsoWAsoWAsoWAsoWAsoWAsoWAsoWAsoWAsoWAsoWAso
NAPNAP124TCB124TCB2A46DT2A46DT3NT3NT26DNT26DNT35DNA35DNAFANTFANTANAPYLANAPYLDEPDEPCHRYCHRYmNBBGEIPYBGEIPYFLRENEFLRENE
3-Nitrotoluene
2,6-Dinitrotoluene
3,5-Dinitroaniline, ,,
Fluoranthene
Acenaphthylene
Diethylphthalate
Chrysene
Nitrobenzene
Benzo(g,h,i)perylene
Fluorene
Volatile Organic FractionBenzene -Bromodichloromethane
ChlorobenzeneDibromochloromethane
C6H6BR.DCLM
CLC6H5DBRCLM
WAWA
WAWA
61
USATHAMAFR.2/WIN/VTB3-2.2
9/15/81
Table 3-2. Analyses for which ESE has been Certified by USATHAMA--Semi-Quantitative Methods (Continued, page 2 c,f3)
DetectionTest Limit
Compound Medium Name Number (ppb)
1,2-DichloroethaneTrans-l, 2-dichloroethene1,2-DichloropropaneEthylbenzene1,1,2,2-Tetrachloroethane1,1,1-Trichloroethane1,1,2-TrichloroethaneTrichloroethene
Organochlorine Pesticidesand PcBs (EpA 608)
Aldrin
Alpha-BHC
Beta-BHC
Delta-BHC
Lindane
Chlordane
4,4’-DDD
4,4’-DDE
4,4’-DDT
Dieldrin
Endosulfan I
Endosulfan II
Endosulfan Sulfate
WAWAWAWAWAWAWAWA
WAsoWAsoWAsoWAsoWAsoWAsoWAsoWAsoWAsoWAsoWAsoWAsoWAso
12DCLET12DCE12DCLPETC6H5TCLEAlllTCE112TCETRCLE
ALDRNALDRNABHCABHCBBHCBBHCDBHCDBHCLINLINCLDANCLDANPPDDDPPDDDPPDDEPPDDEPPDDTPPDDTDLDRN
AENSLFAENSLFBENSLFBENSLFESFS04ESFS04
2J2J2J2J2J2J2J2J
2Fm2F2M2F2M2Fm2F2M2F2M2F2M2Fm2Fm2Fm2F2M2F2F!2F2M
0.90.50.62.00.90.60.70.7
2.00.72.01.0“1.02.02.05.02.02.00.7
202.06.02.03.03.06.01.00.83.03.04.05.03.03.0
—
62
.
.
USATHAMAFR.2/WIN/VTB3-2 .39/15/81
Table 3-2. Analyses for which E.SEhas been Certified by lJSATHAMA--Semi-Quantitative Methods (Continued, page 3 of 3)
DetectionTest Limit
C.ompound Medium Name Number (ppb)
Endr in
Heptachlor
Heptachlor Epoxide
Toxaphene
PCB-1016
PCB-1260
Others-d GreaseWhite Phosphorus
Picric Acid
WAsoWAsoWAsoWAsoWAsoWAso
soWAsoWAso
ENDRNENDRNHPCLHPCLHPCLEHPCLE~HENTXPHENPCB016PCB016PCB260PCB260
OILGRWPWP246TNP246TNP
2F2M2F2M2F2M2F2M2F2M2F2M
2E2K2L2B2C
1.00.72.02.02.03.09.0
504.0200.920
5,0000.7
706.o
500
Source: ESE, 1981.
63
usATHAMAFR .2/wIN/LAg.29/17/81
included in the spiking compounds for the base/neutral and acid
fractions, respectively. Specific munitions-related compounds found to
be chromatographable under the same conditions used for the priority
pollutants were also included in the spiking mixture. These compounds
included nitrotoluene, 2-smino-4,6-dinitrotoluene, and 3,5-dinitro-
aniline. For those compounds not included in the detection limit study,
a detection limit was aasumed to be that of the most chemically similar
compound involved in the study.
3.1.2 DEVELOPMENT OF NEW METHODS
Several analyses required the development of new analytical techniques
or major modifications of existing approached. Method development and
subsequent semi-quantitative certification were required for white
phosphorus and for the high pressure liquid chromatography (HPLC) screen
for organic compounds (including picric acid). Method development and
quantitative certification were required for cyclotrimethylenetrinitra-
mine (RDX).
The method developed for white phosphorus in water and soil involved
extraction using toluene followed by gas chromatographic (GC) analysis
on a non-polar column with a 526-nanometer (rim)flame photometric detec-
tor. Sediment samples were extracted with 50 percent toluene/50 percent
acetone solvent and analyzed by GC with detection Limits attainable in
the microgram-per-Liter (ug/1) range. An interim Standard Analytical
Reference Material (SARM) was obtained in the form of yellow phosphorus
(i.e., white phosphorus with small impurities of the other allomers, red
and black phoaphorua). This method was qualitatively certified for
standard water and soil.
HPLC was used to screen for those specific munitions compounds and
degradation products which are unstable andlor are nonvolatile and can-
not be satisfactorily analyzed by GC/MS. Specifically, this screen was
limited to acidic and neutral organic compounds. Picric acid
specifically was analyzed semi-quantitatively by this screen. Spiked
64
USATXAMAFR. 2fWIN/LAB .39/17f81
.-
standard samples containing picric acid were tested with an extraction
scheme similar to that used for the GC/MS screen for United States
Environmental Protection Agency (EPA) acidic priority pollutants
(Method 625). Picric acid was extracted from acidified media using
methylene chloride.
The RDX analysis included an acidic neutral extraction from water
samples with methylene chloride followed by concentration, solvent
exchange, and analysis by HPLC. Soil samples were extracted with
methylene chloride, and the solvent was exchanged and analyzed by
HPLC .
3.1.3 METHODS OF ANALYSIS
Upon arrival at ESE, samples were checked in and placed in the cold room
(4”C) until they were analyzed.
Groundwater samples were filtered on 0.45-micron membrane filters in the
laboratory for all parameters except metals, which were filtered in the
field. The groundwater samples were then transferred to clean
containers and analyzed within required holding timeq.
All soil samples were air-dried and passed through a 30-mesh sieve
before analysis. Percent moisture was determined for soil and sediment
samples according to ASTM Method D2216-71.
A general organic screening procedure was carried out using GC/US and
HPLC to look for specific munitions and hazardous chemical pollutants in
the low parts-per-billion (ppb) range in the waters and the low parts-
permillion (ppm) range in soils and sediments. A GC/MS screen for EPA
organic priority pollutants (Table 3-3) was conducted on samples from
selected sites. Volatile priority pollutants were analyzed using the
EPA purge and trap procedure (Federal Register EPA Method 624). The
priority pollutant base/neutral and acid compounds were analyzed by
Federal Register EPA Method 625. In the GC/US screen, an attempt was
65
USATHAMAFR. 2/WIN/VTB3-3.19/17f81
Table 3-3. EPA Priority Pollutants
Volatile Fraction
AcroleinAcrylonitrileBenzeneTolueneEthylbenzeneCarbon tetrachlorideChlorobenzene1,2-Dichloroethane1,1,1-Trichloroethane1,1-Dichloroethane1,1-Dichloroethylene1,1,2-Trichloroethane1,1,2,2,-TetrachloroethaneChloroethane2-Chloroethyl vinyl etherChloroform
1,2-Dichloropropane1,3-DichloropropeneMethylene chlorideMethyl chloride chloromethaneMethyl bromideBromoformDichlorobromomethaneTrichlorofluoromethaneDichlorodifluoromethaneChlorodibromomethaneTetrachloroethyleneTrichloroethyleneVinyl chloride1,2,-trans-Dichloroethylene
Acid Fraction
Phenol2-Nitrophenol4-Nitrophenol2,4-Dinitrophenol4,6-Dinitro-o-cresolPentachlorophenol
p-Chloro-urcresol2-Chlorophenol2,4-Dichlorophenol2,4,6-Trichlorophenol ‘2,4-Dimethylphenol
Base/Neutral Fraction
1,2-Dichlorobenzene Fluorene
1,3-Dichlorobenzene Fluoranthene
1,4-Dichlorobenzene Chrysene
Hexachloroethane Pyrene
Hexachlorobutadiene Phenanthrene
Hexachlorobenzene Anthracene
1,2,4-Trichlorobenzene Benzo(a)anthracene
bis(2-Chloroethoxy) methane Benzo(b)fluoranthene
Naphthalene Benzo(k)fluoranthene
2<hloronaphthalene Benzo(a)pyrene
Isophorone Indeno(l,2,3-c ,d)pyrene
Nitrobenzene Dibenzo(a,h)anthracene
2,4-Dinitrotoluene Benzo(g,h,i)perylene
2,6-Dinitrotoluene 4-Chlorophenyl phenyl ether
—
66
USATHAMAFR.2/WIN /VTB3-3 .29/17/81
4
,-.
Table 3-3. EPA Priority Pollutants (Continued, page 2 of Z)
Base/Neutral Fraction (continued)
4-Bromophenyl phenyl etherbis(2-Ethylhexyl) phthalateDi-n-octyl phthalateDimethyl phthalateDiethyl phthalateDi-n-butyl phthalateAcenaphthyleneAcenaphtheneButyl benzyl phthalate2,3, 7,8-Tetrachloro-dibenzo-
p-dioxin (TCDD)
3,3’-DichlorobenzidineBenzidinebis(2-Chloroethyl) etherl,2-DiphenylhydrazineHexachlorocyc lopentadieneN-Nitroaodiphenyl~ineN-Nitroaodimethyl~ineN-Nitrosodi-n-propyl-inebis(2-Chloroisopropyl) ether
Pesticides
alpha-Endosulfanbeta-EndoaylfanEndosulfan sulfate
alpha-BHCbeta-BHCgamma-BHCdelta-BHCEndrinEndrin aldehyde
DieldrinHeptachlorHeptachlor epoxide
ChlordaneToxapheneAldrin4,4’-DDE4,4’-DDD4,4’-DDT
Metals
Antimony Mercury
Arsenic Nickel
Beryllium Selenium
Cadmium Silver
Chromium Thallium
Copper Zinc
Lead
Source: EPA, 1980.
-.
67
USA~R. 2/WIN/l.AB.49/17/81
also made to identify other ~jor chromatographic peaks which
represented a significant portion (greater than 10 percent) of the total
ion current. The identification was accomplished with the aid of
National Bureau of Standards (NBS) library reference spectra.
A slightly modified version of the Federal Register EPA Method 608 was
used to qualitatively determine organochlorine pesticides and polychlor-
inated biphenyls (PCBS) as part of the initial screen.
A flow chart of the analyses scheme for water samples for organic
analytes is presented in Figure 3-1. Inorganic analytes were analyzed
by standard ~thods described in the Technical Report Quality Control
Part I and Supplement (ESE, 1980). The scheme for soil samples is
similar with the introduction of cleanup procedures if warranted by
sample interferences. Gel permeation chromatography was employed for
cleanup of GC/MS samples. A flow chart for the soils analyses is shown
in Figure 3-2.
Tables 3-4, 3-5, 3-6, and 3-7 summarize the analyses performed for each
sample in each matrix. The combination of parameters selected for each
sample was based on patterns of potential contamination deduced from the
records search, discussions with FWDA personnel, and the preliminary
site visit.
3.2 ~UALITT ASSURANCE
Successful accomplishment of the USATHAMA Environmental Survey objec-
tives required the addition of USATNAMA-specific requirements to ESE’S
own QA program and the complete integration of all phases of the survey:
geotechnical, sampling, analysis, data management, and reporting.
The detailed procedures used by ESE included all USATHAMA QA Program
requirements. ESE followed the procedures described in the ESE Quality
Control Plan developed for this project with appropriate modifications.
This plan was approved by USATSAMA for use in the Environmental Survey
68
1
I
69
r
Ha---Rm”I
G
“i
70
—
-
USA~R. 2/WIN/VTB3-4 .19/17/81
Table 3-4. Groundwater Analyses, FWDA Environmental Survey
SiteNumber Type of Chemical Analysis
FW-OOGw* ABC DEFGH IJKLM
FW-35 ABC DEFGH IJKLM
FW-36-1 ABC DEFGH IJKLM
FW-36-2 ABC DEFGH IJKLM
FW-31 ABC DEFGH IJKLM
Key: A = Priority pollutant volatile G = Nitroaromaticsfraction H = HPLC Screen
B = Priority pollutant acid fraction I = Tetryl
C = Priority pollutant base/neutral J = RDXfraction K = White Phosphorus
D = Priority pollutant pesticides L = Oil and greaseE = Priority pollutant metals M = AnionsF = PCBS
* Quality control background sample used as natural media for spikinganalytical parameters.
Source: ESE, 1981.
,0
71
USATHAMAFR. 2/WIN/VTB3-5 .1
9/15/81
Table 3-5. Surface Water Analyaes, FWDA Environmental Survey
SiteNumber Type of Chemical Analysis
FW30-1 A B C D E F G H --J K L M
FW30-2 A B C D E F G H --J K L M
FWO3 -- -- -- -_ E -- G H -- J -- --M
FW18 A B C --E --G H I J K —-M
FW23 A B C --E --G H -- J K --M
FW37 A B C —E -- G H --J K --M
Key: A = Priority pollutant volatile G = Nitroaromaticsfraction H = HPLC Screen
B = Priority ~llutant acid fraction I = TetrylC = Riority pollutant base/neutral J=RDX
fraction K = White PhosphorusD = Priority pollutant pesticides L = Oil and greaseE = Riority pollutant metals M = AnionsF = PCBS
Source: ESE, 1981.
—
72
.
USATHAMAFR.2/WIN/VTB3-6 .19/17/81
Table 3-6. Sediment Analyses, FWDA Environmental Survey
SiteNumber Type of Chemical Analysis
FWOOSE*
FW30-1
FW30-2
FW03
FW05
FW02
FW18
FW22
FW23
FW24
‘B C D —F G
‘B C D ‘F G
—B C D —F G
— — -- -- -- -- G
— -- -- -- _ -- G
——-- D ‘FG
‘B C — — --G
‘B C — — --G
‘B C — — --G
— B C — — --G
H
H
H
H
H
H
H
H
H
n
—J
‘J
—J
—J
‘J
—J
IJ
IJ
—J
IJ
KL—
KL—
KL—
——--
-- — --
——--
K——
K—--
K—--
K——
Key: A = Priority pollutant volatile G = Nitroaromatica
fraction H = HPLC ScreenB = Priority pollutant acid fraction I = TetrylC = Priority pollutant base/neutral J = RDX
fraction K = White PhosphorusD = Priority pollutant pesticides L = Oil and greaseE = Priority pollutant metals H - AnionsF = PCBa
* Quality control background sample used as natural ❑edia for spiking
analytical parameters.
Source: ESE, 1981.
73
USATHAMAFR. 2/WIN/VTB3-7 .19/17/81
Table 3-7. Soil Analyses, FWDA Environmental Survey
SiteNumber Type of Chemical Analysis
FWOOSO*
FWO 1
FW06
FW09
FW14
FW15
FWl 6
FW17
FW19
FW20
FW21
FW32
FW33-1
FW33-2
FW34
FW04
‘B C D —F G
‘B C D —F G
— -. —D —FG
— — -- -- — -- G
‘B C — — —G
— -- -- -- -- -- G
— -- -- -- -- -- G
— -- — -- -- -- G
— B C -- — --G
—B C — — --G
—B C — — --G
—B C D —F G
— -- -- -- -- -_ G
-- -- -- -- -- -- G
— -- -- -- -- -- G
‘B C — -- -- G
Key: A = Priority pollutantfraction
B = Priority pollutantC = Priority pollutant
fractionD = Priority pollutantE = Priority pollutantF - PCBS
* Quality control backgroundanalytical parameters.
Source: ESE, 1981.
E
H
H
H
H
H
H
H
H
H
H
H
H
H
H
H
IJ
—J
—J
—J
—J
—J
—J
—J
IJ
IJ
IJ
IJ
—J
—J
—J
—J
— -- M
—— M
-- -- M
‘M
— -- M
— -- M
— -- M
— —M
K —m
K ‘M
K —M
K —M
-- —M
— -- 1!
-- -- M
— —M
volatile G = NitroaromaticsH = HPLC Screen
acid fraction I = Tetrylbase/neutral J = RDX
K = White Phosphorus
pesticides L = Oil and greasemetals M = Anions
sample used as natural media for spiking
..+
74
.
of FWDA. The following sections highlight the
program for the PWDA Environmental Survey.
3.2.1 ORGANIZATION AND RESPONSIBILITIES
usATuAMAFR.2/wIN/LM .5
9/17/81
-jor topics of the QA
The Quality Control (QC) Program was based on the USATHAMA central-
laboratory/field-laboratory concept. ESE acted as the field laboratory
which was monitored by the USATNAMA Central Laboratory QA Coordinator.
The overall Quality Assurance/Quality Control (QA/QC) organization to
provide valid data to USATHAMA followed the requirements of the August
1980 Quality Assurance Program developed by USATHAMA.
3.2.2 TRAINING AND CERTIFICATION
Analysts were trained in the methods documented for the FWDA Environ-
mental Survey. They were also certified for these methods, based on
their analytical performance.
3.2.3 METHOD CERTIFICATION
Two different types of analyses recognized by the USATRAMA QA program,
semi-quantitative and quantitative, were conducted during this project.
Each type of analysis required a different level of documentation ,
including precision and accuracy data and a different set of daily or
batch-related QC criteria, as described in Section 3.1.
3.2.4 SAMPLE COLLECTION
The QA/QC Supervisor monitored the receipt of samples, audited the field
sampling procedures, and ensured compliance with preservation and
holding time specifications. One site visit was performed by the QA/QC
Supervisor to audit sampling performance.
3.2.5 ANALYTICAL SYSTEMS CONTROL
Detailed procedures for controlling analytical systems were followed for
the FWDA Environmental Survey. Instrument logbooks were maintained for
all analytical equipment, and laboratory notebooks documented all sample
handling and analysis. Copies of applicable pages of these notebooks
75
USATHAMAFR. 2/WIN/LM. 69/17/8j
were submitted to the QA/QC Supervisor weekly during the analytical
phase of the survey.
The application of the USATNAMA QA Plan to the analysia of FWDA
environmental samples was accomplished by the QA/QC Supervisor, ~0
assigned spiking levels, samples to be spiked, ~d s~ple
The number of samples per batch depended on the number of
could be conveniently and efficiently analyzed as a group.
batches.
samples which
The factors
which were taken into consideration in establishing batch size included:
(1) the type of analysis, (2) the complexity, (3) the time required for
a particular analysis, and (4) the holding time for the sample. The
batch size was optimized to provide efficient analysia while meeting the
holding time criteria for the samples.
Each quantitative analysis batch included three spikes and one blank,
and each semi-quantitative batch included one spike (at the detection
limit) and one blank.
3.2.6 DATA VALIDATION
Before submittal of data to USATHA14A, all chemical and field data were
thoroughly reviewed by the QAIQG supervisor. Validation of data was
accomplished by investigation of randomly selected individual lines of
USATNAMA-formatted data. These data were checked through all channels,
validating the data management, sample handling, and analytical aspects
of the reported results. Data validated in this manner were elevated to
Level 2.
3.2.7 CONTAMINATION SAFEGUARDS
In the process of collecting and handling samples, contamination may be
accrued which is independent of the environmental setting at EWDA.
Routine practices
used in field and
which delineate real and artifactual pollutants were
laboratory procedures.
-.
.-
-.
*
-/
76
—
To provide adequate blanks for volatile organics
USATTiAMAFR.2/WIN/LAB .79/17/81
analyses, “trip blanks”
were shipped to the sampling site and returned with samples. These
blanks were prepared in the laboratory end consisted of organic-free
water purged with high purity helium (Air Products, Grade 6) while
heating at 75”c. The blank water was placed in a 60-ml amber bottle and
capped with a Teflon@-lined septum, identical to vessels used for
collecting water samples for volatile organics analysis. Like actual
sample vessels, these blanks were packed in glass Masone jars with a
packet of activated charcoal to adsorb contaminating
analysia of trip blanks shws contamination which is
vessel preparation, packing, handling, and ahipping.
organics. The
a result of sample
Care was taken to waah sampling devices between sample sites to
eliminate cross contamination. Likewise, in the laboratory, sample
processing equipment such es soil sievee and water filtration devices
were waahed and solvent rinsed between samplea. Field end laboratory
duplicates and natural background samples were used to detect cross
contamination from sample handling. All such controls showed that the
integrity of samples was maintained through sampling, processing, and
analysis.
Finally, laboratory contamination from glasaware, solvents, and other
sourcee could be detected in reagent blanks which were run daily with
smnple batches. These blanks consisted of the reagents required for a
specific analysis, run through the appropriate glasaware. Contaminants
most frequently found by these blanks are phthalatea in low
concentration.
3.3 DATA MANAGEMENT
Each of the stepa required to control the flow of data from field trip
preparation, sample collection, and field note recording through data
reduction, validation, and assembly in the required format for storage
in the Installation Restoration Data Management System (IR-DMS) was
incorporated in ESE’S Data Management System. This system included:
77
USATHAMAFR.2/WIN/LAS.89/17/81
1. Data logging and chain-of-custody
a. Field notebook requirements,
b. Sample labeling procedures,
c. Sample transmittal forms, and
d. Analysis report forms.
recording procedures such as:
2. Details of the procedures for interfacing ESE computerized,=
quality control data handling methods with IR-DMS.—,
3. Data coding and tape generation procedures. This format
conformed to requirements specified in the IR Data Management
User’s Guide.—
4. Procedures for transfer of data from ESE to USATHAMA.
ESE’S chain-of-custody protocol, used in the FWDA survey, allowed
precise accounting for the location and status of samples through the
sampling and analysis process by a computercontrolled management
program. Automated data handling at ESE facilitated the coordination of
the laboratory and field portions of a program and provided easy
monitoring for QC.
Sample kits were prepared and labeled prior to field sampling.
Acquisition of labels was part of the Pre-Field Setup procedure, in
which sample stations, sample fractions, -mph trip itinerary,
personnel, and analyses to be performed were entered in the data system
and printed on labels. Each sample container was marked with labels
obtained in this manner.
The field team, having collected samples according to applicable
protocols, shipped samples by guaranteed air freight- to ESE
laboratories. Package registration and other shipping documents were
kept to record shipping processes and to serve as tracers.
Each package shipped contained a
numbers included in the package,
collected, the site sampled, and
logsheet which recorded the sample
the date sod time each sample was
the field team member responsible for
. .
78
usATnAMAFR.2/wIN/LAB .99/17/81
sample handling. Upon arrival at ESE, the samples were received by the
Assistant Laboratory Coordinator. The logsheets were checked against
the contents of the package, the coordinator’s records of the sampling
trip itinerary, and projected sample arrivals. Samples were unpacked
and their appearance noted. If samples were broken or damaged, these
facts were recorded.
The arrival of samples was followed by notification of the Data
Management Coordinator, who logged into the computer the samples
received and the date they were collected. Also, samples which were
originally projected to be received, but were not, ~re deleted. me
samples were forwarded to the Laboratory Storage Coordinator, who
received the samples, stored them appropriately, and recorded the
location of storage.
Samples were signed out when taken from their storage places and signed
in when they were replaced. Upon completion of analyses, data reported
to the computer were filed with the historical data which described
sampling, sample handling, and quality assurance.
Field data, the field drilling file, the groundwater stabilized file,
and the map file were submitted to the Data Management Coordinator on
IR-DMS forms. After data entry, the files were checked for accuracy by
field team members and resubmitted. The field data and chemical data
were passed through quality aasurance reviews before being submitted to
USATHAMA.
Data were subjected to QC checks in the ESE data system and were
reviewed by the appropriate discipline manager. Once this review was
complete, the data were transferred to the USATHAMA data system using
the Tektronix terminal as an intermediary between ESE’S Prime computer
and USATHAMA’S Univac computer. Data were also sent to USATHAMA on
9-track magnetic tape. The data were originally loaded in aa Level 1
data. Field drilling data were checked using USATHAMA’S GEOTEST
79
usATHAMAFR.2 /wIN/LAB. 109/17/81
program. The ESE QA Supervisor performed a data validation check at
appropriate intervals, and if the data passed, they were upgraded to
Level 2 files.
The data handling process for this survey is shown in more detail in
Figure 3-3. All of the FWDA field and chemical data are available as
computer printouts and remain permanently stored for reference. Data
files are listed in Table 3-8.
80
1W.+,.,d s.,.p
-A.. im ?.. -,.,.-P, ,., S-,. bb., ,
.nd I. Oph..,
I!..pl. Call.., ,oa
Po., -?t,ld h,,,
-S-PI= Ins-l.h t., . . . . -1. F+, cul l..,,..
s-l.. ‘I,” m D.,.-Ilo,, fi<.,,w .1
Short Wldk., ?,”.
Lob Maly. i. bqw.t-hf. - -. 1,.,. d
Y S-?l.. d P**-* . . .twmri.tA-Lni.
Ic-wc.r A.l J*M ofb= kc.-C.libr.,,oaCum.
-w m.cb
-s-1. -Cntr.clom Cal. ul.cwm-s,.”0 Iima 1 D.,.
8*-L... bM.i- -
ti,r.c, i” #a,i*m
t
kt...-l. *.11,, *,rol-ch..k. f., m,. Ia. m.i., -,..
.mdVa,i.bl., OIt.,da .1lb-l h,.
C9,. hpor,i. Km h-t
cr..,. m,.. ?i,.Cmc. k,i., VU1’um
Sw.ifl. LO.-c. ti..r.-, em ?.k 7>0
ALOA *1 1D.,. 7+0 or,,.u.,... ,,U
[
P’Ak. COrr.c ,ioem
. . Wc.,”ry
b
m
SOURCE: ESE, 1961.
ENVIRONMENTAL SURVEYFigufa 3-3 Ft. Wingata Dapot Aotivlty
OVERVIEW OF DATA MANAGEMENT PIAN Gallup, Naw Maxko
Us. Army
Toxic and Hazmkma MatarlalaAgancy
~ Proving Ground, Maryland
81
USATHAMAFR.2/WIN/VTB3-8 .19/17j81
Table 3-8. FWDA Level 2 Data Files
File USATHAMA File Name
Field Drilling FwSAGFD8L125
Map FWSAGMA8L136
FWSAGMA81105FWSAGMA81128
Groundwater Stabilized
Chemical
lwSAGGS81125
FWSACGW81141
FWSACSW81141FWSACSE81141FWSACS081141
Source: ESE, 1981.
. .
82
USATHAMAFR. l/WIN/RES. 19/17/81
4.0 RESULTS
4.1 RESULTS OF CHEMICAL ANALYSES
Presented in this section is a summary
chemical analysis of FWDA groundwater,
ssmples. A complete tabulation of all
The occurrence of several compounds in
of the results obtained from the
surface water, sediment, ~d soil
data is provided in Appendix C.
the reported data is attributed
to sample contamination rather than actual presence in the environment.
Phthalates, used as plasticizers, are conznon contaminants of the GC/MS
base/neutral fraction. Methylene chloride and toluene are used in the
extraction of several analytical fractions (see Figures 3-1 and 3-2) and
are frequent laboratory contaminants of the GC/MS volatile fraction.
Groundwater samples typically contained compounds found in the PVC
adhesive and cleaner used to join sections of well casing. These
compounds included tetrahydrofuran, methylethyl ketone, md ~etone.
4.1.1 AMMUNITION WORKSHOP AREA
Samples collected from the Ammunition Workshop Area consisted of the
soil samples described in Table 2-1, a Lake Knudson surface water and
sediment sample, and a groundwater sample taken from a well downgradient
of Lake Knudson. The other wells in the Ammunition Workshop Area were
dry at the time samples were collected.
Table 4-1 summarizes the results of analyais of samples collected in the
Ammunition Workshop Area. Detectable levels of GC/MS volatiles, GC/MS
acids, GC/MS base/neutrals, picric acid, tetryl, and white phosphorus
were not found in any samples.
Pesticides and PCBS were identified in samples
landfill (FWO1) and the acid pit (FW06). FWO1
from the sanitary
contained trace amounts
83
usA~R. 1/WINVTS4-l. 19/17/81
Table 4-1. Summary of Analytical Results at the Ammunition WorkshopArea
Ground SurfaceParameters Water Water Sediment Soil
GC/HS Volatiles
GC/hlS Acids
GC/liS Baae/Neutrala
Pesticides
PCBa
Metals
Antimony
Chromium
Nitroaromatics
Picric Acid
RDX
Tetryl
White Phosphorus
Oil and Grease
Nitrate + Nitrite
Sulfate
Total Phosphate
OL
<DL
OL
@L
U)L
OL
8 mgll
2,460 mg/1
WA
UIL
@L
0.011 mg/1
308 mgll
0.13 mg/1
NA
U)L
UIL
OL
@L
NA
U)L
@L
OL
WA
@L
750 mglkg
NA
NA
NA
NA
OL
@L
See text
See text
NA
See text
OL
<2.88-10.2 mg/kg
NA
NA
NA
<3-31 mg/kg
<259-270 mgjkg
222-452mg/kg
—
.
. .
* NA = Not analyzed.i DL = Detection limit.
Source: ESE, 1981.
84
,-
usATHAMAFR. 1/wIN/REs.29/17/81
of DDD, dieldrin, endosulfan sulfate, endrin, and Aroclor 1016. FW06
contained higher concentrations of beta-BHC, chlord~e, DDD, DDE, DDT,
dieldrin, alpha-endosulfan, endosulfan sulfate, endrin, and Aroclor
1260. Trace amounts of Aroclor 1016 were also detected in soil sample
FWOO .
Dinitrotoluene was found in the triangle pit [FW09, 0.30 milligram per
kilogram (mg/kg)] and one of the leaching beds (IW15, 0.265 mg/kg).
FW15 also contained trinitrobenzene at a concentration of 1.08 mg/kg.
RDX was found in FW09 at 2.88 mglkg. The measured concentrations of
nitroaromatic compounds end RDX and their spatial distributions are
shown in Figure 4-1.
The Lake Xnudson surface water sample contained 8.9 microgram per liter
(ug/1) chromium, end the groundwater sample contained antimony at
47 Ugll. Oil end grease was detected in the sediment at 750 mg/kg.
The groundwater sample contained elevated levels of nitrate plus nitrite
[8 milligrams per liter (mg/1)] and sulfate (2,460 ❑g/1) relative to the
upgradient surface water (nitrate plus nitrite = 0.011 mg/l; sulfate =
308 ❑g/1).
4.1.2 DEMOLITION AREA
Samples taken at the Demolition Area consisted of three surface water
samples (FW18, Fw23, and FW37), four sediment samples (FW18, FW22, Fw23,
and FW24), and the four soil samples. The remaining surface water sites
and the single well were dry.
The samples were free of measurable levels of GC/MS volatiles, GC/MS
acids, GC/FfSbasefneutrals, picric acid, RDX, tetryl, white phosphorus,
and oil and grease.
Surface water Sample FW37 was collected from a metal storage tank end
contained high levels (2,000 ug/1) of zinc.
-,85
0
0 5 1 KMUFIU
SOURCESss,lssl .
Figure 4-1 ENViRONMENTAL SURVEY
DETAIL MAP OF ADMINISTRATION AND Ft. Wingata Dapot ACthlit’y
Ammunition WORKSHOP AREA Gaiiup, Now MaxicoCONTAMINATION
U.S. AmIyToxic and Hazardous Materiais Agency
Abardaan Proving Ground, Matyland
-.
-
.-
.-
—
..-
86
usATsAMAFR.l /wIN/ms.39/17/81
Endosulfan sulfate and Arocolor
at concentrations of 3 microgram
respectively.
016 were detected in soil sample FIJ32
per kilogram (ug/kg) and 30 ug/kg,
Nitroaromatic compounds were found in three of the four soil samples.
The spatial arrangement of the sample sites and their respective concen-
trations are shown in Figure 4-2. In addition, sediment Sample FW20
contained trinitrotoluene at a concentration of 1.94 mg/kg.
Soil Sample FW20 contained nitrate plus nitrite and total phosphate
levels that were significantly higher than other soil samples taken in
the Demolition Area.
4.1.3 OTHER AREAS
The deep well, used as a source of water for drilling operations, was
free of all measured parameters except sulfate, which waa present at
688 ❑gll.
Samples collected in the background areas contained less than detectable
levels of GC/MS volatiles, GC/MS acids, GC/MS base/neutrals, metals,
nitrOarOM.StiC.8, picric acid, tetryl, RDX, fiite phos
grease.
Sediment Sample FW02 contained
tioas of 1 ugikg and 20 uglkg,
4.2 GEOHYDROLOGY
The water resources report for
dieldrin and Aroclor
respectively.
lhorus, and oil and
016 at concentra-
FWDA (USGS, 1971) indicated that
unconsolidated alluvial sediments (sand, silt, and clay) would be
expected to a depth of approximately 30 ft. Bedrock beneath this
alluvium consists of rocks of the Chinle Formation. Ground water could
possibly have been present as a perched water table within the alluv’ial
sediments.
87
I// 17’
FWI~( TNT = 0.663 mgfkg
Ii
II i\
0
30 mglkg II//
W22●
IIIIIIII
IIII\\
II \\
!{
. lW oNo s t~
20URC12E!SE,19S1
Figure 4-2 ENWRONMENTAL SURVEY
DEMOLITION AREA CONTAMINATION Ft. Wlngata Dapot AoIhdty
Gallup, Now Maxiw
U.S. ArmyToxic and Hazardous Matadals Agancy
Abrdaan Proving Ground, Maryland
88
usATHAMAFR.l /wxN/REs.49/17/81
Ground water was not encountered in the majority of the borings/wells at
FWDA . Many borings penetrated material that appears capable of
transmitting ground water if and when it is present. As a result, it is
difficult to make definitive statements about the geohydrology of FWDA
aa a whole.
4.2.1 AMMUNITION WORKSHOP AREA
Two wells (FW08 and FW1O) were drilled to a depth of 50 ft upgradient of
the Aaununition Workshop Area. Both wells were dry, and bedrock was not
encountered. The clay materials encountered in Well FW08 below a depth
of 39 ft required water rotary drilling techniques rather than hollow-
stem auger because of their hardness. The well casing was filled with
drilling water upon completion, but by the time of sampling (January
1981), only 1 ft of water remained in the well, the rest having been
absorbed by the subsurface materials or lost to the atmosphere through
evaporation. It is not believed that any ground water exists at this
site.
Wells Fw08 and FW1O, presumed to be upgradient of the Ammunition
Workshop Area, and Well FW07 contained silty, very fine sand in the
first 20 to 30 ft of drilling. Below this depth, dry to slightly moist
massive clays dominated the subsurface.
Wells FWll, FW12, and FW13, which surround the leaching beds, exhibited
subsurface profiles consisting of silty, very fine sand to 20 or 30 ft,
underlain by massive clays. It appears that the silty, very fine sands
would be capable of transmitting water laterally during wet seasons;
however, all of these wells were dry during the drilling (November 1980)
and sampling (January 1981) phases of this study.
Monitor Well FW35, the only well where significmt amounts of ground
water were encountered during drilling, exemplifies the water-bearing
capabilities of the silty and/or clayey very fine sands which are couuaon
at the northern end of FWDA. Located downgradient of Lake Knudson, Well
FW35 receives ground water from the lake bed via a sandy clay zone
89
usATNAMAFR .1/wIN/REs.59117/81
encountered in the boring at a depth of approximately 15 ft. The soils
immediately above and below this zone were only slightly moist,
indicating that the thin bed at the 15-ft depth may be the source of the
ground water. It should be noted that at this site, the subsurface
materials are predominately clays. The existence of a small sand
component to the clay, in combination with the driving head of Lake
Knudson, allowed ground water to flow downgradient.
At the time of drilling (November 1980), there was 2 ft of mud at the
bottom of the hole upon completion of the boring. The caaing was filled
with water during the sampling trip in January 1981.
4.2.2 DEMOLITION AREA
Within the Demolition Area itself, no wells were installed; however,
Well FW24 was installed just downgradient of the area boundary to
collect a groundwater sample adjacent to the waah which drains the area.
The wash was slightly damp, but no water waa encountered during well
installation. During the sampling phase, less than 1 ft of water was
present in the well.
Silt and weathered rock fragments were encountered in the upper 10 ft of
the boring, followed by dense clay until bedrock was reached at 23 ft.
The relative coarseness of the materials at this site reflects the
proximity of unweathered source materials.
A clay-rich weathered bedrock surface was encountered during drilling at
a depth of approximately 21.5 ft. The water in the well could possibly
represent the potentiometric level of the shallow bedrock aquifer. In
addition, the source of this water may be the subsurface downgradient
flow of water which infiltrates the ground in the Demolition Area
arroyo. Surface water flows in this arroyo disappear underground
several hundred yards upgradient of Well FW24. The clayey soils at this
well site appeared slightly moist in contrast to the extremely dry soils
encountered in the Amunition Workshop Area, indicating that SOme.
subsurface mvement of water may occur in this area.
,.
.-
90
— —
- .
usATHAMAFR. 1/wIN/us.69/17/81
4.2.3 ADMINISTRATION AREA
During the drilling of Wells Fw26 and FW29 (November 1980), materials
similar to those found in the subsurface at the Ammunition Workshop Area
were encountered. The vertical distribution was distinctly different,
however, with beds of clay and silty, fine sanda alternating contin-
uously from the surface to the bottom of the borings. These borings
record the effects of sheetwash, anastomosing, and~or braided stre~
channela which spread out over the flat basin floor during times of
heavy rainfall, depositing mostly fine-grained materials with occasional
coarse-grained pockets developed during infrequent high-intensity
events.
All subsurface materiala encountered during drilling appeared to be dry.
During the sempling period, less than 1 ft of water was present in
Well FW29, located downgradient of STP. The clay-rich weathered bedrock
surface (predominately sandatone, with ,a few limestone fragments)
probably acts as a confining layer. The construction of the well
partially penetrated this confining zone, allowing water to seep upward
into the well during the 2 months between well construction and
sampling. No water quality samples were taken from this well because of
the lack of a sufficient quantity of ground water. A weathered bedrock
surface waa reached during drilling at the 20-ft depth. The water level
in the well is probably the result of ground water in the bedrock
because all materials above the bedrock ahowed no signs of significant
moisture. l%e bedrock is recharged by outcrops in the Zuni Mountains or
in the ridges present throughout lTJDA and possibly by downward
percolation of water from the STP evaporation-infiltration lagoon.
4.2.4 OTHER AREAS
The upgradient well on the Eaat Patrol Road near Ft. Wingate School,
FW31, was partially filled with water during the sampling trip in
January 1981. Water was not expected in Well FW31 because only slightly
moist masaive clay to a depth of 50 ft was encountered during well
drilling operations. The source of this water, though not known
91
specifically, is most probably a thin, slightly
USATHAMAFR.1/WINfRES. 79/17f81
permeable zone within
the clay, hydraulically connected to a water-bearing rock unit at the
base of the Zuni Mountains. Review of the boring log of this site
indicates that the materials at a depth of 30 to 40 ft are the most
likely source of the water. Small, discrete pockets of water were
present in the clay samples. The fact that there was water in the well
during January 1981 suggests that these pockets may be interconnected.
The rate of groundwater movement and, therefore, potential contaminant
movement in this type of material, would be very low.
Wells FW27 and EW28,
exhibited subsurface
samples collected at
located along the northern boundary of FWDA,
profiles very similar to Wells Fw26 and FW29. All
these sites appeared to be dry.
—
—
.-
92
usATHAMAFR.2/wIN/coNcL. 19/17/81
5.0 CONCLUSIONS
Wells installed at FWDA suggest that
discontinuous and low-yield at best.
discontinuity is temporal as well as
recharge areas of the major confined
the water table aquifer at WDA is
It is also evident that the
spatial. In areas near the
aquifers, the water table aquifer
is more pronounced, being fed by both precipitation and infiltration
from surface runoff. The Demolition Area and several igloo areas of
FWDA are located in this type of geohydrologic setting.
With the exception of Well FW31, the water table is almost nonexistent
in the broad valley areas, which contain igloo areas, the tiunition
Workshop Area, and the Administration Area. The study documented the
existence of the water table only in two areas which had surface water
impoundments in proximity. These two examples indicate that the fine-
grained clay-rich soils of FWDA can transmit minor tnoounts of ground
water if a source is available.
Considering the low permeability of the natural subsurface materials,
dry climate, and location of sources of potential contamination within
FWDA, it is unlikely that significant groundwater contamination is
possible via the water table aquifer.
The four potentially contaminated media-- ground water, surface water,
sediment, and soil--were sampled and analyzed for suspect compounds.
The sampling was concentrated in three main areas of FWDA:
1. Ammunition Workshop Area,
2. Demolition Area, and
3. Northern property boundary.
93
USATHAMAFR. 2/WIN/CONCL. 29/17/81
Groundwater samples were obtained from three wells at FWDA: FW31, FW35,
and the deep production well (Fw36, FwOOGW). The samples were
essentially free of contaminants.
The analytical results also indicate that there ia no significant
contamination of the surface
With the exception of Sample
contaminant. FW22, located
water of FWDA.
Fw22, all sediment samples were free
in the Demolition Area, contained
of
trinitrotoluene at a concentration of 1.94 mg/kg. Two sediment sampling
sites immediately downgradient of FW22 did not show trinitrotoluene
contamination. This contaminant seems to be contained within a small
area close to ite source.
Analysis of soil
contamination in
A series of
FW19, FW20,
FW20 having
samples collected at FWDA revealed elevated levels of
proximity to the source areas.
samples was collected in Fenced-Up Horse Valley. Samples
and FW21 had high concentrations of trinitrotoluene, with
the highest value (4.94 mg/kg). In addition, FW20 had a
high concentration of 2,4-dinitrotoluene (8.08 mg/kg). The high
trinitrotoluene levels recorded at sediment site FIJ22may be the result
of runoff from the burning ground in the vicinity of site FW20.
The soil obtained immediately downgradient of the sanitary landfill,
FWO1, contained a suite of pesticides at low to moderate concentrations.
The Ammunition Workshop Area haa several specific sites which have been
found to be contaminated (Figure 4-1). The acid disposal pit, FW06,
contained low to moderate concentrations of a variety of pesticides and
PCB-1260. It appears that this pit has been used to dispose of small
quantities of these organic chemicals.
.-
.-
.
94
.
USA~R. 2/WIN /CONCL. 3
9/17/81
Samples taken from the washout leaching system contain moderately high
levels of trinitrotoluene (range 0.548 mg/kg to 8.29 mg/kg). In
addition, FW09 contained 2,4-dinitrotoluene (0.3 mg/kg) and RDX
(10.2 mgfkg), and FW15 contained 2,4-dinitrotoluene (0.265 mg/kg) and
l,3,5-trinitrobenzene (7.83 mg/kg). FW16, located in a ditch which
receives overflow from the leaching system, had no detectable contamina-
tion. This site is within 50 yards of the highly contaminated leaching
beds and indicates the restricted distribution of existing
contamination.
FWOO, the background soil station , was located less than 100 yards
upgradient of the contaminated area and did not contain detectable
contamination.
Soil samples Fw33 and FW34, located at the northern property boundary of
FWDA, did not contain detectable levels of any of the compounds selected
for analysis.
95
usATHAMAFR.2/wIN/REF .19/16/81
..
6.0 REFERENCES
Hubaux and Vos. 1970. Analytical Chemistry, Volume 42.
United States Environmental Protection Agency. 1980. Part 122:Consolidated Permit Regulations. Federal Register, 45(98):33418-33455.
U.S. Army Toxic and Hazardous Materials Agency. 1980. RecordEvaluation Report No. 136, Installation Asaeasment of Ft. WingateArmy Depot Activity. Aberdeen Proving Ground, Maryland.
U.S. Army Toxic and Hazardous Materials Agency. 1980. QualityAssurance Program for Field Laboratories. Aberdeen Proving Ground,Maryland.
U.S. Geological Survey, Water Resources Division. 1971. Water
Resources of Fort Wingate Army Depot and Adjacent Areas, McKinleyCounty, New Mexico. Albuquerque, New Mexico.
U.S. Geological Survey. 1975. Evaluation and Proposed Study ofPotential Ground-Water Supplies, Gallup Area, New Mexico.Report 75-522. Albuquerque, New Mexico.
.-
96
APPENDIX A—WELL PROFILES
—
.
USATHAMAFR.2/WIN/AFPA.19/17/81
APPENDIX A
WELL PROFILES
Well profiles mapped by the Installation Restoration Data Management
System (USATHA14A)Profile program are included. Each well is plotted
for USCS soil classification and lithology. The profiles are grouped by
each plot type.
A-1
ALVM
BSLT
GLCL
LMSN
SDGL
SDSL
SNDS
VLCC
WSNDS
v
USATHAMAFR.2/wIN/APPA.29f17/81
LITHOLOGY--LEGEND
Alluvium
Basalt
Glacial--undifferentiated
Limeatone
Sand and gravel
Sandstone and shale
Sandstone
Volcanic--undifferentiated
Weathered sandstone
Water level
A-2
F1/SfISl
I I
BtHM
WH-!
7
I6700t
}6690
166806670
k6660I
Figure A-1. Schematic presentation of FW08, FW07, and FW35 well profileswith lithology plotted vs. elevation above MSL in feet.
A-3
-.
--lk= ‘RVMR VM
RI VM
R VM
I
R v!”!
-6700
-6690
-6680
-6670
-6660
Figure A-2. Schematic presentation of FW1O and FW13 well profiles withlithology plotted vs. elevation abwe MSL in feet.
A-4—
QI Vr”l
+
Flv
E
aFM/
3tHMI
Figure A-3. Schematiclithology
presentation of FW12 and FW1l wellplotted vs. elevation above MSL in
A-5
-6700
-6690
-6680
6670
profilesfeet.
with
Figure A-4.
4 ‘VMVM
Flv
VM
-6660
-6650
-6640
-6630
Schematic presentation of FW26 and FW29 well profiles withlithology plotted vs. elevation above MSL in feet.
.
A-6
I
F AJ?8Q VMR VMR VM
VMVM
R VM
I
4
-+
2 ‘/M
21 ‘1?
-6660
-6650
6640
6630
-6620/ 1 1
Figure A-5. Schematic presentation of FW28 and EW27 well profiles withlithology plotted vs. elevation above MSL in feet.
A-7
USATHAMAFR.2/WIN/APPA.39/17/81
CH Fat clay, inorganic clay of high plasticity
CL Lean clay, sandy clay, silty clay, of low to medium pla!
GC Clayey gravel, gravel-sand-clay mixtures
GM Silty gravel, gravel-sand-silt mixtures
ML Silt and very fine sand, silty or clayey fine sand or c:
silt with slight plasticity
OH Organic clays of medium to high
Sc Clayey sand, sand-clay mixtures
sPl Silty-sand, sand-silt mixtures
ticity~
ayey
plasticity, organic silts
SP Sand, poorly-graded, gravelly sands
v Water Level
(, ISM-SC
CI& P
c1
GM-GCCM–(2.T
“6660
6650
6640
-6630
Figure A-6. Schematic presentation of FW26 and FW29 well profileswith USCS codes plotted vs.
A-9
elevation above MSL in feet.
—.
T -cl :P—
“6660
6650
6640
6630
.
“6620
Figure A-7. Schematic presentation of FW28 and FW27 well profiles withUSCS codes plotted vs elevation above MSL in feet.
A-10
I6 9 5 0
1-6900
f6850
-6800[ , vI I
Figure A-8. Schematic presentation of FW31 and FW24 well profiles withusCs codes plotted vs. elevation above MSL in feet.
A-II
—
APPENDIX B—SURVEY SEPORT
-.
—
-,
-.
5.-,,
-’
-,
1
2
-7
-.
-1
-’
-i.
1
REPORT OF SURVEY
FORT WINGATE DEPOT ACTIVITY
GALLUP, NEW MEXICO
ENVIRONMENTAL
FOR
SCIENCE &
By agreement with John Morse
instructions from the army it was
ENGINEERING, INC.
and for lack of specific
decided to use the State
Plane Coordinate System as the basis of survey. It has been
our experience that the Army Corps of Engineers have usually
worked from these values.
The State Plane Coordinate grid reduces survey bearings
and distances to a plane cutting the surface of the earth
at such a position that the maxiumum error due to the cum-
ature will not exceed one in ten thousand parts. Sea level
is the basis of elevations and any survey readings taken
are reduced by proportioning to sea level values. This
sea level factor combined with the scale factor provides
a total reduction of the measured values to the plane grid
intersecting the earth’s surface. By this means, surveys
made at great differences in elevation can be mathametically
closed and the positions obtained at maximum precision.
U.S. National Ocean and Atmospheric Survey Department
published control points were rather scarce in this area
and our contacts with the Geological Suney yielded little
B-1
---
additional information. However, the triangulation station
ERIC had been established in 1966 near the water tank. A
telephone call to Washington produced the needed information
and this data is recorded in the field notes. The single
reference point was used as the point from which the sunreys
were done.
Most of the drill hole locations were located directly
from this station. The balance of the holes, namely FW 31
and FW 24 were located by open traverse. Meaning that a
closure was not made back upon either the starting point
or a point of known coordinate values. An Askania Theodolite
Model 2 E was used for angular values, this instrument reads
directly to one second of arc. Distances were obtained by a
Model 6 A geodimeter manufactured by the Swedish firm of AGA.
Angles were turned direct and inverse with three sets and the
values averaged for the final result.
Duplicate sets of readings were taken with the distance
measuring device to ensure against errors of reading and
calculation. Care was taken in checking the original notes
against the computer input. The information thus obtained
was fed into our in-house computer program called CAINAD
which accepts first the coordinates values and the elevations
of the starting point, then the bearing, slope distance and
vertical angle of the initial course. Following this,
the right horizontal angle, slope distance and vertical angle
of the succeeding course and courses are given. The scale
—
—
—
. .
B-2
factor is introduced as the first card and with the use
of the vertical angles an average elevation is computed
for each course of the traverse, the scale factor together
with the computed elevation of the line is used by the
program to determine the horizontal grid distance. This
value together with the bearings develo~d by the program
from the right horizontal angle values determines the
coordinate values of the points established. - noted on
the computer printout
the average sea level
convert from the grid
is also reported.
which is made a part of this report,
value is given and
distances given to
In conjunction and at the direction
Ehe correction to
ground distance
of Mr. John Morse
it was decided to set permanent control points in the form
of 5/8” X 18” reinforcing bars close to where the drill
holes would be eventually put. Coordinates given for the
various numbered control points are to these 5/8” steel
bars. And also elevations are given to the tops of these
bars. The drill holes were
by taking a compass bearing
means of a string level the
generally set by ESE personnel
from the survey point and by
elevation of the collar of the
drill hole was also determined by the ESE people. The ele-
vations given on the computer printout are not to be accepted
as the elevations of the point,theprintoutstatesthatthese elevations are only for the purpose for
the sea level correction.
B-3
determining
Elevation values were based on a series of bench marks
as depicted on a map provided to us by Fort Wingate personnel.
The source of this level information is not given but values
seemed reliable when checks were made between adjacent
stations.
Level circuits were
level and a Philadelphia
run with a wild model N - 3 precise
type level rod. As a field checking
procedure against error of reading, each reading was taken
with the rod erect and then a reading with the rod inverted,
the rod being either fully extended or fully retracted. The
sum of the erect and inverted readings is always a constant
value which is the total length of the rod. The instrument
man can immediately make a mental addition and if the two
readings do not form this constant total he can reject his
readings to obtain a more satisfactory result, this method
is also valuable in clarifying an unclear notation such as
a two being mistaken for a seven or some other coincidence
of similarity. No standards were established for closure
errors however all level circuits were closed back either
upon themselves or some other point of known elevation to
guarantee against major blunders. If these circuits were to
be described they would be third order precision which
seemed to be of sufficient accuracy for this project and
could be accomplished within the cost projections.
of
The recipient of this report may wonder at the purpose
our establishing two bench marks close together, this is
B-4
done so that a level circuit can be started at one of the
bench marks and closed back upon the other. This removes
the possibility of error from causes such as transposing
figures in copying the values of one of the bench marks,
taking off from the wrong bench mark, and other possible
confusion that could result from using one bench mark and
closing back upon that
of some value that can
field crew in checking
the level circuit does
same bench mark. The TBM is a station
be identified by this particular
back upon themselves or in the event
not close and must be rerun, it is
then possible to segment the level circuit in order to
isolate the error.
B-5
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B-6
STATION
Fw 07
FW 08
Fw 10
Fw 11
m 12
Fw 13
Fw 24
FW 26
FW 27
.FW28
W 29
Fw 31
Fw 35
STITZER & ASSOCIATES
JOB 591212-5-80
DRILL HOLE LOCATIONS & ELEVATIONS
FORT WINGATE ARMY DEPOT
EAST COORD
275,162.83
275,228.51
276,028:14
276,214.51
276,127.03
275,928.64
268,556.84
274,159.90
271,491.94
270,149.29
274,775.35
282,298.39
280,113.91
B-7
NORTH COORD
1,640,776.24
1,640,508.03
1,640,786.02
1,641,268.66
1,641,546.40
1,641,628.50
1,622,656.64
1,643,789.70
1,646,401.25
1,646,522.74
1,645,744.05
1,631,132.34
1,641,829.19
ELEV
6706.86
6710>02
6704.10
6697.84
6696.90
6697.56
6993.91
6669.05
6652.70
6652.55
6666.16
6827.71
6706.46
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SURVEYFIELD NOTES HITZER & ASSOCIATES, INC.
Client Date —Jab na. _Party chief Instrument Hel per
Stat Ion Her. angle01fference
Vert. engle Slope dlst.Reduced
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SURVEY F I ELI) NOTES STITZER & ASSOCIATES, INC.
Client Date —Job no.__,
Patiy &ief Instmment Helper-1=
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SURVEY F I U NOTES =ITZER & ASSOCIATES, INC.
Client Date Job no.,_.
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SURVEY F I El-O NOTES =ITZER & ASSOCIATES, INC.
Cl ient Date -Jab no.,_
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B-35
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APPENDIX C--CEEMICAL DATA
—
._
.
USATHAMAPR. 2/WIN/APPC .1
9/17/81
APPENDIX C
The chemical data for the FWDA survey are presented in ESE report
format. The data are also stored in USATIiAMA format.
c-1
ESE Report of IWDA Chemical Data Ground Water
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APPENDIX D--SUPPORTING REPORTS AND DOCUMENTS
—
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. ..
- 4’
usATHAnAFR.2/wIN/APPD. 19117i81
-,
-J
APPENDIX D
SUPPORTING REPORTS AND DOCUMENTS
The following reports were each submitted to USATHAM by ESE inpartial fulfillment of Contract DAAX 11-80+-0096 for the Ft. WingateDepot Activity (FWDA).
1.
2.
3.
4.
Volume 1: Detailed Sampling and Analysis Plan
10 November 1980
This plan defined and integrated the tasks required to conduct anEnvironmental Survey of FWDA by ESE. The objective of theEnvironmental Survey was to determine if hazardous materials frompast depot activities were migrating beyond depot boundaries orthreatening groundwater supplies.
Volume 2: Data Management Plan10 November 1980
This plan described the integration of the ESE and the InstallationRestoration Data Management System (IR-DMS) and the data acquisition-and control activities associated with s~ple collection, laboratoryanalysis, quality control, and data reduction.
Volume 3: Quality Control Plan10 November 1980
This plan described Project Quality Control required for samplingand analysis in this Environmental Survey. The specific objectivesof the plan were to describe in detail the process for controllingthe validity of the data generated in the sampling and analysiseffort, the methods and criteria for detection of out-of-controlsituations, what steps would be taken to provide timely correctiveaction, and how such actions would be reported and documented. Thisplan also supported the Data Management Plan.
Volume 4: Accident Prevention Safety Program10 November 1980
The primary purposes of this program were to ensure the personalsafety of all ESE personnel and persons retained by ESE who wereinvolved in the project and to prevent any activities which mightcreate adverse environmental impact. The secondary purpose was tomonitor the labeling, shipping, and control of hazardous or
potentially hazardous samples.
D-1
USATHAMAPR. 21wINIAPPD. 29/17/81 ?
5. Technical Report Quality Control Part I8 December 1980
This document presented the analytical methods and correspondingcertification data for analyses to be conducted in the exploratoryphase of the Environmental Survey.
6. Technical Report Quality Control Part I (Supplement 1)16 December 1980
This document presented three additional analytical methods andcorresponding certification data for analyaes to be conducted in the
exploratory phase of the Environmental Survey.
7. Letter to Contract Officer’s Representative (COR) Dr. Robert York
from Jack Sosebee 24 December 1980
This letter included three attachments:1. Responses to USATNAMA couments on the Quality Control Plans
for both FWDA and NDA,2. Responses to USATHAMA comments on the NDA Detailed Sampling
and Analysis Plan, and3. Responses to USATHAMA connnents on the FWDA Detailed
Sampling and Analysia Plan.
8. Well logs submitted to COR in November 1980.
—
. .
D-2