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APPENDIX 10
West VirginiaGeological Survey
West Virginia Mine Pool Atlas
WEST VIRGINIA
1
West Virginia Mine Pool Atlas
Final Project Reportfor the project period
January 1, 2010 through December 31, 2011
Submitted to:
West Virginia Department of Environmental Protection601 57th Street SE
Charleston, WV 25304
Submitted by:
West Virginia Geological and Economic Survey1 Mont Chateau Road
Morgantown, WV 26508-8079
Principal InvestigatorJane S. McColloch, Senior Geologist
Co-InvestigatorsRichard D. Binns, Jr., GIS Database AdministratorBascombe M. Blake, Jr., Manager, Coal Programs
Michael T. Clifford, GIS AnalystSarah E. Gooding, Geologist and GIS Cartographer
May 2012
Inter-Agency Agreement Number 036
i
ACKNOWLEDGMENTS
This study was greatly facilitated by the ongoing work of the Coal Bed Mapping Program (CBMP) staff. In addition, several individuals provided information, technical expertise, and technical support during the course of the project. Notable among these:
•WilliamC.Borth,WestVirginiaDepartmentofEnvironmentalProtection •A.NickSchaer,WestVirginiaDepartmentofEnvironmentalProtection •WilliamJ.Toomey,WestVirginiaBureauforPublicHealth •MaryC.Behling,WestVirginiaGeologicalandEconomicSurvey •GayleH.McColloch,WestVirginiaGeologicalandEconomicSurvey •EdwardI.Loud,WestVirginiaGeologicalandEconomicSurvey •BettyL.Schleger,WestVirginiaGeologicalandEconomicSurvey •SusanE.Pool,WestVirginiaGeologicalandEconomicSurvey •SamanthaJ.McCreery,WestVirginiaGeologicalandEconomicSurvey
ii
ABSTRACT
TheWestVirginiaMinePoolAtlasprojectwasatwo-yearstudybytheWestVirginiaGeologicalandEconomicSurvey(WVGES)toevaluateabandonedcoalminesaspotentialgroundwatersources.ThisstudywasfundedbytheWestVirginiaDepartmentofEnvironmentalProtection(WVDEP).AlthoughWestVirginiareceivesanaverageof44.31inchesofprecipitationperyear(SERCC,2011)andisconsideredtohaveanabundantsupplyofwater,muchofWestVirginia’sprecipitationrunsoffandleavesthestatebywayofitsmanystreams.Theremainderinfiltratesthegroundsurface,butonlyasmallfractionofthiswaterrechargesgroundwateraquifers.Onecurrentlyunderutilizedandfrequentlyoverlookedsourceofstoredgroundwaterisabandonedcoalmines.Recently,inthesearchforlargewatersuppliestofacilitatevariousprocesses,suchasaquaculture,publicsupply,coal-to-liquidhydrocarbons,hydraulicfracturingwaterforgaswells,andpowerplantcooling,arealizationhasdeveloped that these underground mine pools may be more of an asset than previously assumed.
This study, which addressed the potential for large volumes of groundwater storage based on mine void volume, was designed to facilitate prospecting for large volumes of water by identifying underground coal mines thathavethepotentialtostorelargequantitiesofgroundwater,especiallythoseminesthatarelocatedbeloworneardrainage.ThisstudyprovidesaninitialattempttolocateallofthelargeminepoolsinWestVirginiastratigraphicallyandgeographicallyandtoestimatetheirpotentialvolumesbasedonWVGESCoalBedMappingProgram(CBMP)GISdatacurrentlybeingdevelopedtoprovideamodern,up-to-datepictureoftheState’scoalresource base for various uses. These data include many mine maps that have been collected by the CBMP for many years.
Significantundergroundmininghastakenplacein69of73ofWestVirginia’smineablecoalbeds.Variousinformationforthe69coalbeds,includingminepolygons,coalcropline,structurecontouroftheelevation,andscannedminemaps,werevisuallyexaminedtoestablishwhichareashadadequatedatatodeterminethepositionof each mine relative to major drainage and to develop a tool to predict which mines could be partially or totally filledwithgroundwater.
Coalbedscontainingundergroundminesthatwere500acresorlargerinareaandlocatednearorbelowdrainagewereconsideredmajorseamsinthisstudy,and19suchseamswereidentified.Coalandmininginformation from the CBMP were used to generate maps and statistics about potential mine pools in these seams fortheMinePoolAtlas.AstheindividualCBMPdatalayersaredynamicratherthanstatic,allresultspresentedinthis report are preliminary and are undergoing constant updating.
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EXECUTIVE SUMMARY
TheMinePoolAtlasprojectwasatwo-yearstudyfundedbytheWestVirginiaDepartmentofEnvironmentalProtection(WVDEP)toevaluateabandonedcoalminesaspotentialgroundwatersources.AlthoughWestVirginiareceivesanaverageof44.31inchesofprecipitationperyear(SERCC,2011)andisconsideredtohaveanabundantsupplyofwater,muchofWestVirginia’sprecipitationrunsoffandleavesthestatebywayofitsmanystreams.Theremainderinfiltratesthegroundsurface,butonlyasmallfractionofthiswaterrechargesgroundwateraquifers.Onecurrentlyunderutilizedandfrequentlyoverlookedsourceofstoredgroundwaterisabandonedcoalmines.Recently,inthesearchforlargewatersuppliestofacilitatevariousprocesses,suchasaquaculture,publicsupply,coal-to-liquidhydrocarbons,hydraulicfracturingforgaswells,andpowerplantcooling,arealizationhasdeveloped that these underground mine pools may be more of an asset than previously assumed.
This study, which addressed the potential for large volumes of groundwater storage based on mine void volume, was designed to facilitate prospecting for large volumes of water by using available Coal Bed Mapping Program(CBMP)productstoidentifyundergroundcoalminesthathavethepotentialtostorelargequantitiesofgroundwater, especially those mines that are located below or near drainage. This study provides an initial effort tolocateallofthelargeminepoolsinWestVirginiastratigraphicallyandgeographicallyandtoestimatetheirpotentialvolumesbasedontheWVGESCoalBedMappingProgram(CBMP)GISdatacurrentlybeingdevelopedtoprovideamodern,up-to-datepictureoftheState’scoalresourcebaseforvarioususes.Thesedataincludemanymine maps that have been collected by the CBMP for many years.
Significantundergroundmininghastakenplacein69of73ofWestVirginia’smineablecoalbeds.Variousinformationforthese69coalbeds,includingminepolygons,coalcropline,structurecontouroftheelevation,andscannedminemaps,werevisuallyexaminedtoestablishwhichareashadadequatedatatodeterminethepositionof each mine relative to major drainage and to develop a tool to predict which mines could be partially or totally filledwithgroundwater
Coalbedscontainingundergroundmineslocatednearorbelowdrainagethatwere500acresorlargerinareaandlocatednearorbelowdrainagewereconsideredmajorcoalbedsinthisstudy,and19suchcoalbedswereidentified.CBMPcoalandmininginformationwereusedtogeneratemapsandstatisticsaboutpotentialminepoolsinthesecoalsfortheMinePoolAtlas.
The results of this investigation are summarized in this report; and maps and statistics potential mine pools ofmajorcoalbedsreflectthestatusofCBMPworkduringthestudy.AstheindividualCBMPdatalayersaredynamic rather than static, all results presented in this report are preliminary and are undergoing constant updating.
TheMinePoolAtlascontains:
• Generaldescriptionsofmajorcoalbedswithineachformation. • Stratigraphiccolumnsshowingthepositionofallcoalbedswithineachformation • Tablesshowingthedistributionofpotentialtotallyandpartiallyfloodedminesineachseambymine
footprint area and position with respect to drainage • Tablesshowingthedistributionofpotentialpartiallyfloodedareasofaboveandneardrainage
underground mines by coal bed • Mapsofcoalbedsinwhichpotentialpartialand/ortotalfloodingwaspresentinminesthathadareasof
500acresorgreater ▪ Structurecontourofelevation ▪ Isopach(totalbedthickness) ▪ Seamoverview ▪ Extentofpotentialtotalflooding ▪ Extentofpotentialpartialflooding • Overviewtablesforseamsinwhichpotentialpartialand/ortotalfloodingwerepresentinmineslessthan
500acresinarea
MuchoftheundergroundminingintheWestVirginiahasoccurredabovedrainage.Examinationof9,539minepolygonsin69coalbedsdeterminedthat8,907minesareabovedrainage;325neardrainage,178arebelowdrainage,and129arecurrentlyundetermined.
iv
Studyresultsshowedthat99mines,whichexceed500acresinarea,aregenerallylocatedbelowdrainageandarepotentiallytotallyflooded.Theseminesarelocatedin14majorcoalbeds:
• PittsburghcoalinOhio,Marshall,Monongalia,Marion,andHarrisoncounties • UpperFreeportcoalinPrestonCounty • MiddleKittanningcoalinPrestonandBarbourcounties • CoalburgcoalinWayneandLincolncounties • PeerlesscoalinKanawha,Nicholas,andMingocounties • Number2GascoalinLogan,Mingo,Boone,andKanawhacounties • PowelltoncoalinBoone,Logan,andMingocounties • LowerPowelltoncoalinMingoCounty • EaglecoalinNicholas,Fayette,Kanawha,Boone,Logan,andMingocounties • SewellcoalinNicholas,Fayette,Raleigh,andWyomingcounties • BeckleycoalinFayette,Raleigh,andWyomingcounties • PocahontasNo.6coalinRaleighCounty • PocahontasNo.4coalinMcDowellCounty • PocahontasNo.3coalinWyoming,McDowell,andRaleighcounties
Fivehundredthirty-twominesexceeding500acresinareaarepotentiallypartiallyflooded;and147oftheseminesarelocatedneardrainageand385minesareabovedrainage.Theseminesarein19majorcoals.Fourteenofthesecoalsalsohaveminesthatarepotentiallytotallyfloodedandhavebeendescribedabove.Thesefivecoalbedshavepotentiallypartiallyfloodedmines:
• SewickleycoalinMonongaliaandMarioncounties • BakerstowncoalinPreston,Grant,andTuckercounties • Number5BlockcoalinBraxton,Nicholas,Clay,Kanawha,Boone,Lincoln,Mingo,andWayne
counties • StocktoncoalinBraxton,Nicholas,Kanawha,Boone,Logan,Lincoln,andMingocounties. • PocahontasNo.2coalinRaleighCounty.
Althougheffortsaremadetousethebestavailabledataandlocateminesasaccuratelyaspossible,minelocationsshouldbeconsideredapproximate.Theactualextentofminingmaybeunknownbecausefinalminemaps at the time of mine closure are not always available and not all underground mining has been documented by minemaps.Thequalityofminemapsishighlyvariableintheamountofdetailandinformationpresented.Someof the newer mine maps are available in digital form; however, many older mine maps have been photographically reduced from dimensionally unstable paper copies. Photographic reduction also introduced distortion due to lens geometry.Also,coalcorrelationsmaychangewithadditionalinformation.Activeminesarenotdifferentiatedfrom recently closed mines in the CBMP database.
Theextentofpotentialminefloodingisdependentonseveralfactors,includingmineorientation,mineentrylocation,proximitytootherundergroundmines,anddirectionofgroundwaterflow.Groundwaterpumpingtoenableundergroundminingcanaffectwaterlevelsinadjacentundergroundmines.Thegroundwaterfloodingpotential for underground mines in one coal bed also may be affected by underground mining in stratigraphically lowercoals.Ingeneral,oncepumpingceases,theminesbegintoflood. Theresultsofthisstudyshouldbeconsidereda“snapshot”ratherthanafinishedproduct.NewminescontinuallyopeninWestVirginiaandinadjoiningstatesneartheState’sborders.Inaddition,newlyobtainedminingcoveragesarebeingconstantlyupdatedintheCBMPGISasnewinformationbecomesavailable.Allofthesefactorsreinforcetheneedfordetailedsite-specificstudiestodeterminethepresenceofadequatewaterresources.
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TABLE OF CONTENTS
Acknowledgments ..........................................................................................................................................................i
Abstract ........................................................................................................................................................................ ii
ExecutiveSummary .................................................................................................................................................... iii
Introduction ...................................................................................................................................................................1
Purpose .......................................................................................................................................................................1
PreviousWork ............................................................................................................................................................1
Methodology .................................................................................................................................................................2
Scope ..........................................................................................................................................................................2
MiningData ...............................................................................................................................................................2
GISModels ................................................................................................................................................................2
MinePoolEvaluationProcess ...................................................................................................................................3
GISAttributeTables ...................................................................................................................................................3
MinePoolVolumetricCalculationMethod ...............................................................................................................4
Deliverables ...............................................................................................................................................................4
DeliverableDataLayersDescription .........................................................................................................................4
StructureoftheReport ...............................................................................................................................................5
RegionalEvaluation ......................................................................................................................................................5
SeamAnalysesbyFormation/Group ............................................................................................................................6
DunkardGroup ..........................................................................................................................................................6
MonongahelaGroup ..................................................................................................................................................6
ConemaughGroup .....................................................................................................................................................7
AlleghenyFormation .................................................................................................................................................7
KanawhaFormation ...................................................................................................................................................9
NewRiverFormation ..............................................................................................................................................13
PocahontasFormation ..............................................................................................................................................14
Discussion ...................................................................................................................................................................16
Conclusions .................................................................................................................................................................17
References ...................................................................................................................................................................18
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LIST OF FIGURESMinePoolAtlasFigures..............................................................................................................................................19
Figure1.CoalBedMappingProgram(CBMP)ProgressasofJune30,2011 ......................................................20
Figure2.PotentialUndergroundMinePools—AllSeams .....................................................................................21
Figure3.WatershedModel .....................................................................................................................................22
Figure4.MajorDrainageModel ............................................................................................................................23
Figure5.PerennialDrainageModel .......................................................................................................................24
Figure6a.StratigraphicchartofPennsylvaniancoal-bearingstratainWestVirginia ...........................................25
Figure6b.StratigraphiccolumnsoftheDunkardandMonongahelaGroups ........................................................25
Figure6c.StratigraphiccolumnoftheConemaughGroup ....................................................................................25
Figure6d.StratigraphiccolumnoftheAlleghenyFormation ................................................................................26
Figure6e.StratigraphiccolumnoftheKanawhaFormation ..................................................................................26
Figure6f.StratigraphiccolumnsoftheNewRiverandPocahontasFormations ...................................................26
Figure7a.Percentestimatedstorageinpotentialtotallyandpartiallyfloodedmines ...........................................27
Figure7b.Percentestimatedstorageinpotentialtotallyfloodedmines ................................................................28
Figure7c.Percentestimatedstorageinpotentialpartiallyfloodedmines .............................................................29
Figure8.SelectedMajorStructuresofWestVirginia ............................................................................................30
Figure9a.SewickleyMinePools—StructureContour ..........................................................................................31
Figure9b.SewickleyMinePools—Isopach ..........................................................................................................32
Figure9c.SewickleyMinePools—SeamOverview .............................................................................................33
Figure9d.SewickleyMinePools—PotentialTotalFlooding ...............................................................................34
Figure9e.SewickleyMinePools—PotentialPartialFlooding .............................................................................35
Figure10a.PittsburghMinePools—StructureContour .........................................................................................36
Figure10b.PittsburghMinePools—Isopach .........................................................................................................37
Figure10c.PittsburghMinePools—SeamOverview ............................................................................................38
Figure10d.PittsburghMinePools—PotentialTotalFlooding ...............................................................................39
Figure10e.PittsburghMinePools—PotentialPartialFlooding ............................................................................40
Figure11a.BakerstownMinePools—StructureContour ......................................................................................41
Figure11b.BakerstownMinePools—Isopach ......................................................................................................42
Figure11c.BakerstownMinePools—SeamOverview .........................................................................................43
Figure11d.BakerstownMinePools—PotentialTotalFlooding ............................................................................44
Figure11e.BakerstownMinePools—PotentialPartialFlooding ..........................................................................45
Figure12a.UpperFreeportMinePools—StructureContour .................................................................................46
Figure12b.UpperFreeportMinePools—Isopach .................................................................................................47
Figure12c.UpperFreeportMinePools—SeamOverview ....................................................................................48
Figure12d.UpperFreeportMinePools—PotentialTotalFlooding ......................................................................49
Figure12e.UpperFreeportMinePools—PotentialPartialFlooding ....................................................................50
Figure13a.MiddleKittanningMinePools—StructureContour ............................................................................51
Figure13b.MiddleKittanningMinePools—Isopach ............................................................................................52
Figure13c.MiddleKittanningMinePools—SeamOverview ...............................................................................53
Figure13d.MiddleKittanningMinePools—PotentialTotalFlooding .................................................................54
Figure13e.MiddleKittanningMinePools—PotentialPartialFlooding ...............................................................55
Figure14a.No.5BlockMinePools—StructureContour ......................................................................................56
Figure14b.No.5BlockMinePools—Isopach ......................................................................................................57
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Figure14c.No.5BlockMinePools—SeamOverview .........................................................................................58
Figure14d.No.5BlockMinePools—PotentialTotalFlooding ............................................................................59
Figure14e.No.5BlockMinePools—PotentialPartialFlooding .........................................................................60
Figure15a.StocktonMinePools—StructureContour ...........................................................................................61
Figure15b.StocktonMinePools—Isopach ...........................................................................................................62
Figure15c.StocktonMinePools—SeamOverview ..............................................................................................63
Figure15d.StocktonMinePools—PotentialTotalFlooding ................................................................................64
Figure15e.StocktonMinePools—PotentialPartialFlooding ..............................................................................65
Figure16a.CoalburgMinePools—StructureContour .........................................................................................66
Figure16b.CoalburgMinePools—Isopach .........................................................................................................67
Figure16c.CoalburgMinePools—SeamOverview.............................................................................................68
Figure16d.CoalburgMinePools—PotentialTotalFlooding ...............................................................................69
Figure16e.CoalburgMinePools—PotentialPartialFlooding .............................................................................70
Figure17a.PeerlessMinePools—StructureContour ...........................................................................................71
Figure17b.PeerlessMinePools—Isopach ...........................................................................................................72
Figure17c.PeerlessMinePools—SeamOverview ..............................................................................................73
Figure17d.PeerlessMinePools—PotentialTotalFlooding .................................................................................74
Figure17e.PeerlessMinePools—PotentialPartialFlooding ...............................................................................75
Figure18a.No.2GasMinePools—StructureContour ........................................................................................76
Figure18b.No.2GasMinePools—Isopach ........................................................................................................77
Figure18c.No.2GasMinePools—SeamOverview ...........................................................................................78
Figure18d.No.2GasMinePools—PotentialTotalFlooding ..............................................................................79
Figure18e.No.2GasMinePools—PotentialPartialFlooding ............................................................................80
Figure19a.PowelltonMinePools—StructureContour ........................................................................................81
Figure19b.PowelltonMinePools—Isopach ........................................................................................................82
Figure19c.PowelltonMinePools—SeamOverview ...........................................................................................83
Figure19d.PowelltonMinePools—PotentialTotalFlooding ..............................................................................84
Figure19e.PowelltonMinePools—PotentialPartialFlooding ............................................................................85
Figure20a.LowerPowelltonMinePools—StructureContour .............................................................................86
Figure20b.LowerPowelltonMinePools—Isopach .............................................................................................87
Figure20c.LowerPowelltonMinePools—SeamOverview ................................................................................88
Figure20d.LowerPowelltonMinePools—PotentialTotalFlooding ..................................................................89
Figure20e.LowerPowelltonMinePools—PotentialPartialFlooding ................................................................90
Figure21a.EagleMinePools—StructureContour ...............................................................................................91
Figure21b.EagleMinePools—Isopach ...............................................................................................................92
Figure21c.EagleMinePools—SeamOverview ..................................................................................................93
Figure21d.EagleMinePools—PotentialTotalFlooding .....................................................................................94
Figure21e.EagleMinePools—PotentialPartialFlooding ...................................................................................95
Figure22a.SewellMinePools—StructureContour .............................................................................................96
Figure22b.SewellMinePools—Isopach .............................................................................................................97
Figure22c.SewellMinePools—SeamOverview ................................................................................................98
Figure22d.SewellMinePools—PotentialTotalFlooding ...................................................................................99
Figure22e.SewellMinePools—PotentialPartialFlooding ...............................................................................100
Figure23a.BeckleyMinePools—StructureContour .........................................................................................101
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Figure23b.BeckleyMinePools—Isopach .........................................................................................................102
Figure23c.BeckleyMinePools—SeamOverview ............................................................................................103
Figure23d.BeckleyMinePools—PotentialTotalFlooding ...............................................................................104
Figure23e.BeckleyMinePools—PotentialPartialFlooding .............................................................................105
Figure24a.PocahontasNo.6MinePools—StructureContour ..........................................................................106
Figure24b.PocahontasNo.6MinePools—Isopach ..........................................................................................107
Figure24c.PocahontasNo.6MinePools—SeamOverview .............................................................................108
Figure24d.PocahontasNo.6MinePools—PotentialTotalFlooding ................................................................109
Figure24e.PocahontasNo.6MinePools—PotentialPartialFlooding ..............................................................110
Figure25a.PocahontasNo.4MinePools—StructureContour ..........................................................................111
Figure25b.PocahontasNo.4MinePools—Isopach ..........................................................................................112
Figure25c.PocahontasNo.4MinePools—SeamOverview .............................................................................113
Figure25d.PocahontasNo.4MinePools—PotentialTotalFlooding ................................................................114
Figure25e.PocahontasNo.4MinePools—PotentialPartialFlooding ..............................................................115
Figure26a.PocahontasNo.3MinePools—StructureContour ..........................................................................116
Figure26b.PocahontasNo.3MinePools—Isopach ..........................................................................................117
Figure26c.PocahontasNo.MinePools—SeamOverview ................................................................................118
Figure26d.PocahontasNo.3MinePools—PotentialTotalFlooding ................................................................119
Figure26e.PocahontasNo.3MinePools—PotentialPartialFlooding ..............................................................120
Figure27a.PocahontasNo.2MinePools—StructureContour ..........................................................................121
Figure27b.PocahontasNo.MinePools—Isopach .............................................................................................122
Figure27c.PocahontasNo.2MinePools—SeamOverview .............................................................................123
Figure27d.PocahontasNo.2MinePools—PotentialTotalFlooding ................................................................124
Figure27e.PocahontasNo.2MinePools—PotentialPartialFlooding ..............................................................125
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LIST OF TABLES
MinePoolAtlasTables .............................................................................................................................................126
Table1.SummaryofPotentiallyTotallyFloodedUndergroundMinesbyCoalSeam .......................................127
Table2.SummaryofPotentiallyPartiallyFloodedUndergroundMinesbyCoalSeam ....................................128
Table3.PotentialTotallyandPartiallyFloodedMinesbyDrainagePositionandMineFootprintArea ...........129
Table4.PotentialExtentofPartialFloodinginAboveDrainageMines<500AcresinArea .............................130
Table5.PotentialExtentofPartialFloodinginAboveDrainageMines>500AcresinArea .............................131
Table6.PotentialExtentofPartialFloodinginNearDrainageMines<500AcresinArea ...............................132
Table7.PotentialExtentofPartialFloodinginNearDrainageMines>500AcresinArea ...............................133
TableA–1.MethodComparison ........................................................................................................................... A-3
APPENDICES
MinePoolAtlasAppendixA.................................................................................................................................... A-1
AppendixA.TestResultsofMiningAbove/BelowDrainageGISModels ........................................................ A-2
MinePoolAtlasAppendixB ....................................................................................................................................B-1
AppendixB.PotentialTotallyFloodedUndergroundMines>500AcresinArea ...............................................B-2
MinePoolAtlasAppendixC ....................................................................................................................................C-1
AppendixC.PotentialPartiallyFloodedUndergroundMines>500AcresinArea .............................................C-2
MinePoolAtlasAppendixD ................................................................................................................................... D-1
AppendixD.OverviewsofMinorSeams ........................................................................................................... D-2
1
INTRODUCTION
Purpose
TheMinePoolAtlasprojectwasatwo-yearstudyfundedbytheWestVirginiaDepartmentofEnvironmentalProtection(WVDEP)toevaluatethepotentialofabandonedundergroundcoalminestoserveasasourceoflargevolumesofgroundwater.AlthoughWestVirginiareceivesanaverageof44.31inchesofprecipitationperyear(SERCC,2011)andisconsideredtohaveanabundantsupplyofwater,muchofWestVirginia’sprecipitationrunsoffandleavesthestatebywayofitsmanystreams.Theremainderinfiltratesthegroundsurface,butonlyafractionofthiswaterrechargestogroundwateraquifers.Onecurrentlyunderutilizedandfrequentlyoverlookedsource of stored groundwater is abandoned coal mines. This study, which addressed the potential for large volumes of groundwater storage based on mine void volume, is designed to facilitate prospecting for large amounts of water byidentifyingundergroundcoalminesthathavethepotentialtostorelargequantitiesofgroundwater,especiallythoseminesthatarelocatedbeloworneardrainage.Recently,inthesearchforlargewatersuppliestofacilitatevariousprocesses,suchasaquaculture,publicsupply,coal-to-liquidhydrocarbons,hydraulicfracturingwaterforgas wells, and power plant cooling, a realization has developed that these underground mine pools may be more of an asset than previously assumed.
This study, which addressed the potential for large volumes of groundwater storage based on mine void volume, was designed to facilitate prospecting for large volumes of water by identifying underground coal mines thathavethepotentialtostorelargequantitiesofgroundwater,especiallythoseminesthatarelocatedbeloworneardrainage.ThisstudyprovidesaninitialattempttolocateallofthelargeminepoolsinWestVirginiastratigraphicallyandgeographicallyandtoestimatetheirpotentialvolumesbasedontheWestVirginiaGeologicalandEconomicSurvey(WVGES)CoalBedMappingProgram(CBMP)GISdatacurrentlybeingdevelopedtoprovideamodern,up-to-datepictureoftheState’scoalresourcebaseforvarioususes.Thesedataincludemanymine maps that have been collected by the CBMP for many years.
Previous Work
The initial concept for this project was developed from a map showing estimated mine pool data for the PocahontasNo.3andPocahontasNo.4seamsinsouthernWestVirginiapreparedbyWestVirginiaDepartmentofEnvironmentalProtection(WVDEP,2008).Severalrecentreports(ZiemkiewiczandVandivort,2004,Ziemkiewiczetal.,2004,andDonovan,2004a,2004b)havestudiedtheextentofMonongahelaBasinminepoolfloodingbasedonwater-levelmeasurementswithinspecificminesofthePittsburghcoalinnorthernWestVirginiaandsouthwesternPennsylvania.ThehydrogeologyoffloodedandunfloodedundergroundcoalminesintheUpperFreeportseaminnorthernWestVirginiaandwesternMarylandhasbeenreportedinareconnaissancemappingstudybyMorrisetal.(2008).
2
METHODOLOGY
Undergroundmininghasoccurredin69of73ofWestVirginia’smineablecoals.Coalbedandmininginformation for these beds including mine polygons, coal cropline, structure contour of the elevation, and scanned imagesofminemaps(WVGES,2011)wereexaminedtoestablishwhereadequatedataexistedtodeterminethepositionofeachminerelativetomajordrainagewherethepotentialforeachminetobepartiallyortotallyfilledwith groundwater to be determined.
Toaidinunderstandingthepotentialofthiswatersourcefordevelopment,availableWVGESCBMPdataandmodelswereusedtodeterminewhichseamshaveminevoidscapableofstoringlargequantitiesofgroundwater.Adynamic,interactiveGeographicInformationSystem(GIS)wascreatedtoportraythelocationofminepoolsthatmightprovidelargevolumesofwaterforvariousprivate,public,andindustrialuses.ThisGISprovidedtoolstoestimateminepoolvolumes.Figure1showsthestatusofworkbeingconductedbyCBMP(B.M.Blake,unpub.data,2011).
Scope
The scope of the project was limited to the following tasks: • Evaluationofeachcoalseambyregiontodeterminewhichpartsoftheseamareabove,near,andbelow
major drainage. • EstimatemaximumminepoolvolumeofeachseamassuminganaveragethicknessbasedonWVGES
CBMPGISdataanda50percentextractionrate—collapsedanduncollapsedmineswouldhaveessentially the same volume because additional voids are created in the crushed pillars and fractured overburden of collapsed mines.
• DevelopmaptemplatesforuseinthePDFatlas. • PreparemapsofeachmajorminepoolforPDFreport.
Theoriginalscopeincludedcollectionandevaluationofavailablewaterqualitydata.Unfortunately,muchoftheavailablewaterqualitydatawerefromtreatedminewater,andtheseanalyseswerenotusefulindeterminingin-situwaterquality.
Mining Data
DataavailablefromtheongoingCBMPusedinthisstudyinclude:minepolygonsofapproximately9,500underground mines; coal bed croplines; structure contours of the base of each coal bed; coal bed elevation raster data;andcoalisopachs.Astheindividualdatalayersaredynamicratherthanstaticandaresubjecttointermittentupdating as new data warrant, all results presented in this report are preliminary and subject to change.
CBMP has digitized footprints of mine maps, and these mine polygons have been compiled to document the extentofundergroundmineworks(Figure2).Althougheffortsaremadetousethebestavailabledataandlocatemines as accurately as possible, mine locations should be considered approximate. The actual extent of mining may beunknownbecausefinalminemapsatthetimeofmineclosurearenotalwaysavailableandnotallundergroundmininghasbeendocumentedbyminemaps.Thequalityofminemapsishighlyvariableintheamountofdetailandinformationpresented.Someofthenewerminemapsareavailableindigitalform;however,manyolderminemaps have been photographically reduced from dimensionally unstable paper copies. Photographic reduction also introduceddistortedduetolensgeometry.Also,coalbedcorrelationsmaychangewithadditionalinformation.ActivemineswerenotdifferentiatedfromrecentlyclosedminesintheCBMPdatabase.
GIS Models
GISmodelswereusedinthisstudytoassistindeterminingthepositionofeachminewithrespecttodrainage,theamountofpotentialgroundwaterflooding,anddirectionofgroundwaterflow.
TheWatershedModel,whichwasusedtodeterminegroundwaterflowdirection,isastandardEsri© ArcMap™10.0geoprocessingmodelthatusestheSpatialAnalyst™HydrologytoolsettoconverttheCBMPcoalbedelevationrasterdataintopredictivehydrologicflowdirectionandflowaccumulationrasters.Fromthesegenerated datasets the model outputs generalized “stream” features which can be used to predict the direction of groundwater movement through mine voids relative to the coal outcrop. This model was run for all coal beds to aidindeterminingtheextentofpotentialfloodinginundergroundmines.AnexampleofmodeloutputfortheSewellcoalseamisshowninFigure3.
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TheMiningAbove/BelowDrainageModel(MABD),whichisageoprocessingmodel(aseriesofstandardArcGIS™ tools executed in a certain order), was developed for this study to determine the position of mines with respecttodrainagebasedonperennialstreamelevations.TwoversionsoftheMABDModel,theMajorDrainageElevationModel(MDEM)andthePerennialDrainageElevationModel(PDEM),weregeneratedbyassigningUSGS7.5-minutequadrangleelevationstopointsselectedfromtheNationalHydrographyDataset(NHD).TheMDEMselectedpointslocatedwithindigitizedperennialstreampolygons;thePDEMselectedpointslocatedalongdigitizedperennialstreamlines.Theresolutionofthesedigitalelevationmodels(DEMs)weregeneratedto10meterstomatchtheCBMPseamelevationrasterdata.ThecoalelevationDEMwassubtractedfromtheMDEMandthePDEMtoindicateregionsofthecoalbedthatlieaboveandbelowmajordrainage,theseresultswereindividuallyoverlaidwiththeminefootprinttoobtainthetwoversionsofthefinalGISlayerofpotentiallyfloodedmineareas(Figures4and5).
TheeffectivenessoftheMDEMandPDEMmodelswastestedbycomparingthemodeloutputfor472minesintheSewellcoalseamlocatedinsouthernWestVirginiawiththeresultsofthevisualstructurecontour/croplineexaminationofthesameundergroundmines(McCollochetal.,2011).Thevisualstructurecontour/croplineexaminationisthemosteffectivemethodofidentifyingdrainagepositionandpotentialextentoffloodinginmines.TheMDEMprovedineffectiveinpredictingminepositionwithrespecttodrainageandpotentialextentofmineflooding.ThePDEMisafairpredictivetool,butitismosteffectiveinidentifyingpotentialfloodingbelowdrainage.ThedetailsofthiscomparisonarepresentedinAppendixA.
Mine Pool Evaluation Process
• Establishwhichareashavestructurecontourandcoalcroplinecoveragessothatthepositionofeachunderground mine with regard to major drainage (above, near, or below), which allows the potential for eachminetobepartiallyortotallyfilledwithgroundwater
• Evaluatepositionandlikelihoodoffloodingformineslocatedinareaswhichhaveadequatecoverages • Visuallyexamineeachminepolygonbyseamandassignattributesaccordingtominepooltype,position
with respect to drainage, availability of structure contour, availability of cropline, and potential extent of partialflooding
GIS Attribute Tables
Tofacilitatedataanalysesandmapgeneration,sixfieldswereaddedtotheCBMPGISattributetablesofthe69coalbedsthathavebeenminedbyundergroundmethods:
• Minepooltypebasedonextentofpotentialflooding:0=undetermined;1=flooded;2=notflooded;and3=partiallyflooded
▪ Undeterminedrepresentsundergroundmineslocatedinareaswithnostructurecontourand cropline coverages
▪ Floodedrepresentsundergroundminesthatarelocatedbelowdrainage,andthesemineshavethe potentialtobetotallyfilledwithgroundwater
▪ Notfloodedrepresentsminesthatareprobablyfreedraining ▪ Partiallyfloodedrepresentsundergroundminesthathaveaconfigurationthatwouldpermitthe accumulationofgroundwaterinspecificareasthatcanrangefromverysmalltoverylarge andthesedeterminationsarequalitativeratherthanquantitative • Positionwithrespecttodrainage(0=undetermined;A=above;N=near;andB=below ▪ Undeterminedrepresentsundergroundmineslocatedinareaswithnostructurecontourand cropline coverages • Availabilityofstructurecontour(1=Yes;2=No) • Availabilityofcroplinedata(1=Yes;2=No) • Potentialextentoffloodingforpartiallyfloodedundergroundminesbasedonqualitativeratherthan
quantitative ▪ 1=verysmallpotentiallyfloodedarea(s) ▪ 2=smallpotentiallyfloodedarea(s) ▪ 3=intermediatepotentiallyfloodedarea(s) ▪ 4=largepotentiallyfloodedarea(s) ▪ 5=verylargepotentiallyfloodedarea(s) • Commentfield
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Mine Pool Volumetric Calculation Method
TheCBMPTotalBedThicknessrasterlayer(totbed)isa10meterGRIDlayerthatwasthebasisforverticalvoidmeasureestimates.ThislayerisproducedusinganInverseDistanceWeightedalgorithmthatinterpolatesgridvaluesbetweenactualcoalbedthicknessdataasdescribedbyWoodetal.(1983).CBMP’sminefootprintlayerwas the base used to determine the area covered by each mine void.
ArcMap™’sSpatialAnalystextensionZonalStatisticstoolwasemployedto“sum”each10metercellwithin a given mine polygon to calculate the total volume of the mine void. These data were output into a .dbf table (zonalstat).
The following mathematical formulas were used:
• ConversionoftheZonalStatisticresultfrominches/meterstocubicfeet:((SUM/12)*32.808399)*32.808399
• Conversionofcubicfeettoacrefeet:cubic_ft/43560
• Conversionofcubicfeettogallons:cubic_ft*7.48051948
• Storagegallonswerecalculatedashalfoftheestimatedvoidgallons:(cubic_ft*7.48051948)*0.5
• Theaveragethicknessofthecellsintersectedbytheminefootprintpolygonwerecalculatedbytakingthesum of the cell values divided by the count of cell selected.
Deliverables
Thedeliverablesincluded:afinalWestVirginiaMinePoolAtlasreportinelectronicformat;GISgeodatabasesofWVGES’sCBMPseamandminingcoverages;andGISmaptemplates.Thisreportincludes:general description of major coal beds within each formation; the distribution of potential totally and partially floodedminesineachcoalbedbyminefootprintareaandpositionwithrespecttodrainage;estimatedvolumeofgroundwatercontainedineachminepool;afive-mapseriesforeachofthe19majorcoalbedsidentifiedbythis study consisting of a structure contour map, an isopach map, a seam overview map, a map showing extent ofpotentialtotalflooding,andamapshowingextentofpartialflooding;andoverviewtablesforminorcoalbedshavingpotentialminevoidflooding.
Deliverable Data Layers Description
thickness_measures_location(points)—XYcoordinatesofcoalmeasurelocation thickness_measures_area(polygon)—3milebufferofmeasurelocationusedtodetermine“mapped”area ofthecoalbedasdescribedinUSGSCircular891(Woodetal.,1983) structure(line)—coalelevation40’contours outcrop(polygon)—originalcoalresourceareaascurrentlymapped mines(polygon)—undergroundminefootprints •Apcard(poly_ID) •MineName •CompanyName •StatePermit# •WVGESComment •SeamCodes •StratigraphicOrder •Acres mine_pool(polygon)—undergroundmineandzonalstatisticstablesconcatenated idwTotalBed(raster)—totalbedthicknessininches10meterGRID zonalstat(table)—volumetriccalculationresults •Apcard(polyID) •Count—countofcellsintersectedbymine •Area—totalsquaremetersofintersectedcells •Sum—totalofcellthicknessesininches •VoidCubicFoot •VoidAcreFoot •VoidGallons •StorageGallons •Avgthk—averagethicknessofcellsintersectedbythepolygon
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Structure of the Report
Followingevaluation,19majorseamswereidentifiedforinclusioninthemapsectionofthereport.Thesearecoalbedsinwhichundergroundminesoccurthathavefootprintsequaltoorgreaterthan500acresinareaandarenearorbelowdrainage.Anareaof500acreswaschosenasthelowerlimitforinclusioninthisreportfortworeasons:itwouldprovideadequatepotentialstoragetoaccommodatealargevolumeofgroundwater;andthemine polygons printed on the map would be large enough to show annotation by attribute. Maps and statistics for each major mine pool presented in this report are limited to the coal and mining information available from the WVGES’sCBMPduringtheperiodofthisstudy.
TheAtlascontains:
• Ageneraldescriptionofprincipalcoalbedswithinthegrouporformation • Stratigraphiccolumnsshowingthepositionofthemainnamedcoalbedswithineachformationorgroup • Tableshowingthedistributionofpotentialtotallyandpartiallyfloodedminesineachseambymine
footprint area and position with respect to drainage • Mapsofcoalbedsthatminesinwhichpotentialpartialand/ortotalfloodingispresentinminesexceeding
in500acresinarea. ▪ Structurecontourofthebaseofeachcoalbed ▪ Isopach(totalcoalbedthicknesses) ▪ Seamoverview ▪ Extentofpotentialtotalflooding ▪ Extentofpotentialpartialflooding • Overviewtablesforseamsinwhichpotentialpartialand/ortotalfloodingispresentinminesthatareless
than500acresinarea
REGIONAL EVALUATION
Dataforseamswerereportedbyformationinstratigraphicorderfromyoungesttooldest.AstratigraphicchartofPennsylvaniancoal-bearingstrataisshowninFigure6a.StratigraphiccolumnsofPennsylvaniangeologicunitsinFigures6b–fshowthestratigraphicpositionofnamedcoalbedswithineachformationorgroup.Thecoalbednamesshowninthesefiguresarecolorcoded:thoseinbluedenotemajorseamsinwhichpotentialtotallyandpartiallyfloodedundergroundminesexceeding500acresinareaarepresent;thoseinorangecorrespondtoothermineableseamsinWestVirginia;andthoseinblackrepresentunminedcoalbeds.
StudydatahavebeencompiledandsummarizedinTables1through7.Namesofmajorcoalbedscontainingminesthathavesignificantgroundwaterpotentialandexceed500acresinareaareshowninboldfacethroughoutthetextandinTables1through7.StatisticaldataaboutpotentialtotallyfloodedminesandpotentiallypartiallyfloodedminesarepresentedinTables1and2,respectively.Table3hasinformationaboutpotentialtotallyandpartiallyfloodedminesbypositionwithrespecttodrainageandbyminearea.Tables4through7provideinformationaboutpotentialextentofpartialfloodinginaboveandneardrainageminesbyminefootprintarea.AppendixBpresentsinformationaboutthe99potentialtotallyfloodedundergroundminesthatexceed500acresinarea.Informationabout532potentiallypartiallyfloodedundergroundmineshavingareasgreaterthan500acresispresentedinAppendixC.Overviewsof53coalbedsthatdidnotmeetthedrainagepositionandareacriteriaforinclusioninthemapatlasarepresentedinAppendixD.
Thepercentageofestimatedmaximumstorageinmilliongallons(MMGal)ofpotentiallytotallyandpartiallyfloodedundergroundminesofselectedseamsisshowninFigures7a–c,respectively.
Elevationsofthebaseofcoalbedscommonlyserveasthebasisfordefiningfoldsandfaultsincoal-bearingrockworldwide.Figure8showsthelocationofmajorstructuralfeaturesintheState.
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Coal Bed Analyses by Formation/Group
Dunkard Group
ThemainlyUpperPennsylvanianDunkardGroup(Figures6a,b)contains14namedcoalbeds.Noneofthese coals have been mined by underground methods, and therefore, are excluded from further discussion.
Monongahela Group
TheUpperPennsylvanianMonongahelaGroup(Figures6a,b)includesninenamedcoalbedsofwhichfour,theWaynesburg,Sewickley,RedstoneandPittsburgh, have been mined by underground methods. Coal beds that have the potential to contain large volumes of groundwater in mine voids are the Pittsburgh and Sewickley coals.
Waynesburg:ThefourundergroundminesinthisseamarelocatedinMonongaliaCounty.Allfourminesarelocatedabovedrainageandarepotentiallypartiallyfloodedbygroundwater.Thesemineshavelimitedpotentialfor supplying water resources due to their small size and location above drainage.
Sewickley: This coal bed generally dips to the northwest in the area in which it is mined, and the minimum elevationofthiscoalislocatedintheNinevehSynclineinWetzelandMarshallcounties(Figure9a).TheisopachmapindicatestheSewickleybed(Figure9b)rangesfrom0to144inchesinthickness,withthethickestcoallocated in central Marion County. In areas where underground mining has occurred, this bed generally ranges in thicknessfrom36to96inches.
Seventy-sixundergroundSewickleyminesarelocatedinMarionandMonongaliacounties.Fifty-threeminesareabovedrainage,13areneardrainage,andtenarebelowdrainage(Figure9c).Nobelowdrainageminesgreaterthan500acresinareacurrentlyoccurinthisseam(Figure9d).Sixneardrainageminesexceeding500acresinareahavepotentialpartialflooding(Figure9e).Averagebedthicknessesoftheseminesrangefrom59.00to75.00inches.MapsandstatisticalinformationaboutpotentialgroundwaterfloodingofminesinthisseamareshowninFigures9c–e.
ThepresenceofsignificantgroundwaterresourcesinundergroundSewickleyminesmaybeaffectedbyunderground mining in the stratigraphically lower Pittsburgh coal.
PotentiallypartiallyfloodedundergroundminesintheSewickleyprovide100percentoftheestimated22,809.16milliongallons(MMGal)ofpotentialstorage,andtheseSewickleyminescontain1.65percentoftotalpotentialstorageand2.23percentofpotentialpartialstorageinundergroundminesofmajorcoals(Figures7a,c).
Redstone:ThisseamhasbeenminedbyundergroundmethodsinBarbour,Harrison,Lewis,Mason,Monongalia,andUpshurcounties.Ofthe218undergroundminesinthisseam,207arelocatedabovedrainage,fiveminesare located near drainage, and six mines are located below drainage. These mines have limited potential to store significantvolumesofgroundwater.
Pittsburgh:Theelevationofthebaseofthiscoaldefinesaseriesofsouth-southwesttonorth-northeasttrendinganticlinesandsynclinesinnorthernWestVirginia,andthelowestelevationsofthePittsburgharefoundintheNineveh,Burchfield,andRobinsonsynclines(Figures8and10a).
ThePittsburghbedrangesinthicknessfrom0tomorethan144inches,anditgenerallyexceeds48inchesinthicknessinmanyareas(Figure10b).AlthoughFigure10bshowstotalcoalbedthicknessesofgreaterthan144inchesinseveralsmallareasofeasternGilmerCounty,morerecentstudyindicatesthisinformationiserroneous.Inareaswhereundergroundmininghasoccurred,thethicknessofthisbedgenerallyrangesfrom:72to120inchesinnorth-centralWestVirginia;48to84inchesinthenorthernpanhandleofWestVirginia;and36to84inchesinthe western part of the state.
ThiscoalhasbeenextensivelyminedbyundergroundmethodsinBarbour,Braxton,Brooke,Gilmer,Hancock,Harrison,Kanawha,Lewis,Marion,Marshall,Mason,Monongalia,Ohio,Preston,Putnam,Taylor,Upshur,andWetzelcounties.ThePittsburghhasalimitedoccurrenceinMineralCountyintheState’seasternpanhandle where it has been removed through several generations of underground and surface mines. Mine polygonsof806mineswereexamined,and683minesareabovedrainage,79areneardrainage,and44arebelowdrainage(Figure10c).Twenty-twobelowdrainageminesandoneneardrainagemineexceed500acresinarea
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andarepotentiallytotallyflooded(Figure10d).Theaveragebedthicknessesoftheseminesrangefrom56.00to98.42inches.Thirty-oneneardrainageminesexceed500acresinareaandhavepotentialpartialflooding(Figure10e).Theaveragecoalbedthicknessesoftheseminesrangefrom49.00to101.63inches.MapsandstatisticalinformationaboutpotentialgroundwaterfloodingofminesinthePittsburgharepresentedinFigures10c–e.
PotentiallypartiallyandtotallyfloodedundergroundminesinthePittsburghcoalprovideanestimated423,453.52MMGalofpotentialstorage;andthepotentiallypartiallyfloodedundergroundPittsburghminescontain51.87percentofthispotentialstorage.PotentialstorageinundergroundPittsburghminesaccountsfor30.60percentoftotalpotentialstorageinundergroundminesofmajorseams(Figure7a).ThepercentageofpotentialstorageinpotentiallytotallyandpartiallyfloodedundergroundPittsburghminesrepresents56.52and21.47percent,respectively,ofthetotalcombinedpotentialstorageofminesinmajorcoalbeds(Figures7b,c).
Conemaugh Group
TheUpperPennsylvanianConemaughGroup(Figures6a,c)includes22namedcoalbeds.Threeofthesecoals,theElkLick,Bakerstown and Mahoning, have been mined by underground methods. The Bakerstown coal istheonlyConemaughGroupbedwithsignificantpotentialtocontainlargevolumesofgroundwaterinmine.
ElkLick: ThisseamhasbeenminedbyundergroundmethodsinGrant,Lewis,Mineral,andUpshurcounties,and18minesarepresentinthisseam.All18minesarelocatedabovedrainage.Theminesinthisseamaregenerallysmall in area and occur above local streams, offering limited potential for supplying water resources.
Bakerstown:Elevationsofthebaseofthiscoaldefineaseriesofsouth-southwesttonorth-northeasttrendinganticlinesandsynclinesinthewesternpartoftheeasternpanhandleandnorth-centralareasofWestVirginia(Figure11a).MostundergroundBakerstownminesarelocatedinPreston,Barbour,Tucker,andGrantcountieswhereithasbeenpreservedfromerosionintheLigonier,Belington,Kingwood,andNorthPotomacsynclines(Figures8and11a).ThetotalbedthicknessoftheBakerstowngenerallyrangesfrom24to84inches,andthethickestpartofthecoalbedislocatedinnorthernTuckerCounty(Figure11b).
Sixty-sevenminesarelocatedabovedrainage,and52oftheseminesarepotentiallypartiallyfloodedbygroundwater(Figures11c,e).Mostoftheseminesaresmallandhavelimitedpotentialforsupplyingwaterresources.Nominesarelocatedbelowdrainage(Figure11d).OneneardrainageminelocatedinTuckerCountyexceeds500acresinareaandispotentiallypartiallyflooded(Figure11e).Theaveragebedthicknessforthismineis70.00inches.StatisticalinformationaboutpotentialgroundwaterfloodinginthisseamispresentedinFigures11c–e.
Potentialfloodingofundergroundminesinthisseammaybeaffectedbyundergroundmininginthestratigraphicallylowercoalssuchas:theUpperFreeportinnortheasternTucker,northwesternGrant,andwesternPrestoncounties;andtheMiddleKittanninginwesternPrestonCounty.
PotentiallypartiallyfloodedundergroundBakerstownminesprovideanestimated4,600.06MMGaloftotalpotentialstorage,andtheseminesaccountfor0.33percentoftotalpotentialgroundwaterstorageand0.45percentofpotentialpartialstorageinundergroundminesofmajorseams(Figures7a–c).
Mahoning:ThefiveundergroundminesinthisseamarelocatedinMineralCounty,andallfiveminesareabovedrainage. These mines have limited potential to provide water supplies because of their small size and position above drainage.
Allegheny Formation
TheMiddlePennsylvanianAlleghenyFormation(Figures6a,d)includes14namedcoalbeds;ninewhichhave been mined by underground methods. The seams that have the greatest potential for containing large volumes of groundwater in mine voids are the Upper Freeport and Middle KittanningcoalsinnorthernWestVirginiaandthe Number 5 BlockcoalinsouthernWestVirginia.
Upper Freeport:Thiscoalbedhasbeenfoldedintoaseriesofsouth-southwesttonorth-northeasttrendinganticlinesandsynclinesinthewesternpartoftheeasternpanhandleandinnorth-centralWestVirginia(Figures8and12a).ErosionalremnantsoftheUpperFreeportoccuralongtheChestnutRidge,Preston,andBlackwater
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anticlines. Most underground mines in this coal are located in Preston, Barbour, and Tucker counties, preserved in theLigonier,Kingwood,MountCarmel,andNorthPotomacsynclines.InsoutheasternMarion,centralUpshur,andnorthernBarbourcounties,bedrockgenerallydipstothenorthwest(Figure12a).AvailabledataindicatetheUpperFreeportrangesinthicknessfrom24to144inches(Figure12b).Thethickestpartofthecoalbedislocatedin eastern Preston County.
Analysisofthe285undergroundminesintheUpperFreeport(Figure12c)showthat237minesarelocatedabove drainage, ten are located near drainage, three are located below drainage, and 35 are located in areas with no structurecontourandcroplinecoverages(Figure12c).OnebelowdrainagemineinsouthwesternPrestonCountyexceeds500acresinarea(Figure12d).Averagebedthicknessofthismineis49.00inches.Onehundredninety-twoabovedrainageand11neardrainageminesarepotentiallypartiallyflooded(Figure12e).Intermediatetoverylargeareasoftenabovedrainageminesthatexceed500acresinareaarepotentiallyflooded.Sevenpotentiallypartiallyfloodedneardrainageminesexceed500acresinarea.Theaveragebedthicknessesoftheseminesrangefrom51.00to97.24inches.StatisticalinformationaboutpotentialgroundwaterfloodinginthisseamispresentedinFigures12c–e.
GroundwaterfloodinginafewnearandbelowdrainageminesinPrestonCountymaybeaffectedbyundergroundmininginthestratigraphicallylowerMiddleKittanningandLowerFreeportcoalbeds.Currently,potentialforgroundwaterfloodinghasnotbeendeterminedforundergroundUpperFreeportminesinBarbourandUpshurcounties.AfewoftheseminesarelocatedaboveundergroundmininginthestratigraphicallylowerMiddleKittanningandLowerFreeportcoals.
PotentiallypartiallyandtotallyfloodedundergroundminesintheUpperFreeportcoalprovideanestimated45,708.19MMGaloftotalpotentialstorage.Estimatedpotentialpartialstorageis97.42perentofpotentialtotalstorageinthesemines.Totalpotentialstorageinthiscoalbedrepresents3.30percentoftotalpotentialstorageinundergroundminesofmajorseams(Figure7a).EstimatedstorageinpotentialtotallyandpartiallyfloodedUpperFreeportminesrepresent0.33percentand4.35percentstorage,respectively,ofmajorseams(Figures7b,c).
Middle Kittanning:Thiscoalbedhasbeenfoldedintoaseriesofsouth-southwesttonorth-northeasttrendinganticlinesandsynclinesinnorth-centralWestVirginia(Figure13a).ErosionalremnantsoftheMiddleKittanningoccuralongtheChestnutRidgeAnticline(Figure13a).Intheareaswherebedthicknessdataareavailable,thiscoalbedgenerallyrangesinthicknessfrom0tomorethan144inches(Figure13b).InsouthwesternPrestonCounty,undergroundminesinthiscoalarelocatedintheLigonierSynclinewherethecoalbedgenerallyrangesinthicknessfrom24to108inches(Figures8and13a–b).Elsewhere,bedthicknessinminedareasrangesfrom24to72inchesinBarbourandTaylorcountiesandfrom48to72inchesinMarionCounty.
Ofthe43undergroundminesinthisseam,22areinareaswherestructurecontourand/orcroplinedataareavailable.Elevenminesarelocatedabovedrainage,sixminesareneardrainageand,fiveminesarebelowdrainage(Figure13c).Thebelowdrainageminesarepotentiallytotallyfloodedbygroundwater(Figure13d);twooftheseminesexceed500acresinareaandhaveaveragebedthicknessesof51.00and74.50inches.Tenabovedrainageandsixneardrainageminesarepotentiallypartiallyflooded(Figure13e).Threeneardrainageminesexceed500acresinareaandhaveaveragebedthicknessesthatrangefrom46.00to58.98inches.StatisticalinformationaboutpotentialgroundwaterfloodinginthisseamispresentedinFigures13c–e.
Currently,potentialforgroundwaterfloodingcannotbedeterminedforundergroundMiddleKittanningminesinBarbourandUpshurcountiesastheCBMPproductsarenotcomplete.AfewminesinthisseamareaboveundergroundmininginthestratigraphicallylowerClarioncoalbedinpartsofnorth-centralBarbourCountyandtheLowerKittanninginpartsofcentralUpshurCounty.
PotentiallypartiallyandtotallyfloodedundergroundminesintheMiddleKittanningprovideanestimated15,669.16MMGaloftotalpotentialstorage(Figure7a).EstimatedstorageinpotentiallytotallyfloodedMiddleKittanningminesis50.72percent.PotentialstorageinMiddleKittanningminesaccountsfor1.13percentoftotalpotentialstorageinundergroundminesofmajorseams.Thiscoalrepresents2.20percentand0.75percentstorageinpotentialtotallyandpartiallyfloodedmines,respectively,ofmajorseams(Figures7b,c).
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No. 5 Block:Thiscoalbedhasbeenfoldedintoseveralsouthwest-northeasttrendinganticlinesandsynclines(Figures8and14a).ErosionalremnantsoftheNo.5Blockarepreservedalongthesouthwest-northeasttrendingWarfieldAnticlineinsouthwesternWestVirginia(Figure14a).SoutheastandnorthwestoftheWarfieldAnticline,manyundergroundminesinthiscoalarelocatedintheHandleySynclineandtwounnamedsynclinesinWayneandLincolncounties.Thethicknessofthisbedrangesfrom0tomorethan132inches,andthethickestcoalisfoundinNicholasCounty(Figure14b).Bedthicknessinareasofundergroundmininggenerallyrangesfrom24tomorethan132inches(Figure14b).
TheNo.5BlockhasbeenminedbyundergroundmethodsinsouthwesternandcentralWestVirginia.Minepolygonsforthe429undergroundminesinthisseamwereexamined,and416oftheseminesarelocatedabovedrainageand13neardrainage(Figure14c).
Nopotentialtotallyfloodedundergroundminesarepresentinthiscoalbed(Figure14d).Threehundredforty-oneoftheabovedrainageminesand12oftheneardrainageminesarepotentiallypartiallyflooded.Onepotentiallypartiallyfloodedneardrainagemine,whichislocatedineasternLincolnCounty,exceeds500acresinarea(Figure14e).Averagebedthicknessinthismineis69.00inches.AdditionalinformationaboutpotentialgroundwaterfloodinginthisseamispresentedinFigures14c–e.
PotentialgroundwaterfloodingofabovedrainageundergroundminesinthiscoalintheHandleySynclinemaybeaffectedbyundergroundminingofstratigraphicallylowercoalsassignedtotheunderlyingKanawhaFormation.InnorthernNicholas,southernBraxton,andwesternWebstercounties,undergroundminingintheStocktonlowersplit2,Coalburg,andWinifredecoalsmayaffectgroundwaterfloodinginafewNo.5Blockmines.
PotentiallypartiallyfloodedundergroundminesintheNo.5Blockcoalprovideanestimated19,562.68MMGaloftotalpotentialstorage,andtheseminesaccountfor1.41percentoftotalpotentialgroundwaterstorageand1.91percentofpotentialpartialstorageinundergroundminesofmajorseams(Figures7a,c).
Kanawha Formation
TheLowertoMiddlePennsylvanianKanawhaFormation(Figures6a,e)includes42namedcoalbeds,and31 have been mined by underground methods. The seven seams having the greatest potential to have mine voids containing large volumes of groundwater are the Stockton, Coalburg, Peerless, Number 2 Gas, Powellton, Lower Powellton, and Eaglecoals.Ninehundredthirty-fourmineshavebeenidentifiedinlowerKanawhaFormationcoalbedsinsouthernWestVirginia(Figure6e),theMiddleWarEagle,BensCreek,LowerWarEagle,GlenalumTunnel,Gilbert,andDouglas.Forthemostpart,theseminesaresmallinarea,occurabovedrainage,andcontain limited potential water supplies.
Stockton:Severalsouthwest-northeasttrendinganticlinesandsynclinesaredefinedbythestructurecontourofthebaseofthiscoal(Figures8and15a).ErosionalremnantsoftheStocktonarepreservedalongthesouthwest-northeasttrendingWarfieldAnticlineinsouthwesternWestVirginia(Figure15a).ManyundergroundminesinthisbedarelocatedtothesoutheastoftheWarfieldAnticlineintheHandleySynclineandafewarelocatedonthenorthwestlimboftheWarfieldAnticline(Figure15a).TheStocktonrangesfrom0tomorethan144inchesinbedthickness,anditobtainsitsthickestdevelopmentinsouth-centralLoganCounty(Figure15b).Whereithasbeenundergroundmined,theStocktongenerallyrangesfrom24to144inchesthick(Figure15b).
ThiscoalhasbeenminedbyundergroundmethodsinsouthwesternandcentralWestVirginia.Ofthe160minesinthisseam,157arelocatedabovedrainageandthreearelocatedneardrainage(Figure15c).Nominesarelocatedbelowdrainage,andnominesarepotentiallytotallyflooded(Figure15d).Onehundredthirty-twooftheabovedrainageminesandthreeneardrainageminesarepotentiallypartiallyflooded(Figure15e).Onepotentiallypartiallyfloodedneardrainagemine,whichislocatedineasternKanawhaCounty,exceeds500acresinarea.Atthislocation,averagebedthicknessis64.00inches.Althoughpotentialfloodingisgenerallylimitedtosmallareasinmanyofthesmallermines,intermediatetolargeareasofseverallargerminescouldbeflooded.AdditionalinformationaboutpotentialgroundwaterfloodinginthisseamispresentedinFigures15c–e.
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PotentialfloodingparticularlyinaboveandneardrainageStocktonminesintheHandleySynclinemaybeaffectedbymanyundergroundminesinstratigraphicallylowercoalsbedsassignedtotheKanawhaformation(Figure6e).InpartsofwesternBoone,southernBraxton,andnorthernNicholascounties,undergroundminingintheCoalburgwilllikelyaffectpotentialfloodinginStocktonmines.
PotentiallypartiallyfloodedundergroundminesintheStocktoncoalprovideanestimated29,161.59MMGaloftotalpotentialstorage,andtheseminesaccountfor2.11percentoftotalpotentialgroundwaterstorageand2.85percentofpotentialpartialstorageinundergroundminesofmajorseams(Figures7a,c).
Coalburg:Severalsouthwest-northeasttrendinganticlinesandsynclinesaredefinedbythestructurecontourofthebaseofthiscoal(Figures8and16a).ErosionalremnantsoftheCoalburgoccuralongthesouthwest-northeasttrendingWarfieldAnticlineinsouthwesternWestVirginia(Figure16a).Thebedrangesinthicknessfrom0tomorethan144inches,reachingamaximumthicknessinnorthernMingoCounty(Figure16b).Availablebedthicknessdatainareasofundergroundmininggenerallyrangefrom24tomorethan144inches(Figure16b).
UndergroundminesintheCoalburgoccuracrossmostofsouthernWestVirginia(Figure16c).Dataanalysiswascompletedforthe298minesforthisseam;287minesarelocatedabovedrainage,tenminesareneardrainage,andonemineisbelowdrainage(Figure16c).Oneneardrainagemineandonebelowdrainageminearepotentiallytotallyflooded.Twohundredsixty-fiveoftheabovedrainageminesandnineoftheneardrainageminesarepotentiallypartiallyflooded.
Mostpotentialtotallyorpartiallyfloodedbelowandneardrainageminesthatexceed500acresinareaarelocatedineasternWayneandwesternLincolncounties(Figure16d,e).Onepotentiallytotallyfloodedbelowdrainagemineexceeds500acresinarea.Theaveragebedthicknessofthismineis66.57inches(Figure16d).Twopotentiallypartiallyfloodedneardrainageminesaregreaterthan500acresinarea,andtheaveragebedthicknessesoftheseminesare58.00and62.00inches.Visualanalysisindicatesthatlargeareasoftheseminesarepotentiallyflooded(Figure16e).AdditionalinformationaboutpotentialgroundwaterfloodinginthisseamispresentedinFigures16c–e.
PotentialgroundwaterfloodingofundergroundCoalburgminesmaybeaffectedinsomeareasbyundergroundminingofstratigraphicallylowercoalsfromtheEagletotheWinifredeintheHandleySyncline;theWinifredeandSewellcoalsinwesternWebsterCounty;andtheWinifredeandEagleontheeastlimboftheMannMountainAnticlineinwesternNicholasCounty.
PotentiallypartiallyandtotallyfloodedundergroundminesintheCoalburgcoalprovideanestimated68,114.13MMGalofpotentialstorage;88.44percentofthisestimatedstorageisinpotentiallypartiallyfloodedmines.Thispotentialstorageaccountsfor4.92percentoftotalpotentialstorageinundergroundminesofmajorseams(Figure7a).Thiscoalrepresents2.18percentand5.89percentstorageinpotentialtotallyandpartiallyfloodedmines,respectively,ofmajorseams(Figures7b,c).
Winifrede:ThiscoalhasbeenwidelyminedbyundergroundmethodsinBoone,Fayette,Kanawha,Logan,Mingo,Nicholas,Raleigh,Webster,andWyomingcounties.Minepolygonsforthe283minesinthisseamwereexamined,and281minesarelocatedabovedrainageandtwominesareneardrainage.Thetwoneardrainageminesarelessthan500acreasinarea.Twohundredforty-fouroftheabovedrainageminesandthetwoneardrainageminesarepotentiallypartiallyflooded.Thetwoneardrainageminesarelessthan500acresinarea.Althoughpotentialfloodingwouldbelimitedtosmallareasinmostofthesemines,intermediatetolargeareasofseveralofthelargerminescouldbeflooded.
Peerless: Thiscoalgenerallydipstothenorthwestexceptinthevicinityofthesouthwest-northeasttrendingfoldsincludingtheWarfieldAnticlineandtheHandleySynclineandthenorth-northwesttrendingMannMountainAnticline(Figures8and17a).ThePeerlesscropsoutonhillsidesalongtheaxisoftheWarfieldAnticline.ManyundergroundminesinthiscoalarelocatedsoutheastoftheWarfieldAnticline,andmostoftheseminesarelocatedabovedrainage.Ranginginthicknessfrom0tomorethan132inches,thiscoalisthickestinsouthernLoganCounty(Figure17b).Availablebedthicknessdatainareasofundergroundmininggenerallyrangefrom24to132inches(Figure17b).
UndergroundmininginthisseamispresentinsouthernandcentralWestVirginia(Figure17c)ThePeerlessoftenmergeswiththeunderlyingNo.2Gascoalwhichcomplicatesanalysis.Minepolygonsfor284mineswereexamined,and229minesarelocatedabovedrainage,12neardrainage,fivebelowdrainage,and38inareaswherecroplineandstructurecontourmapshavenotbeencompleted(Figure17c).Threeminesabovedrainage,three
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minesneardrainage,andfiveminesbelowdrainagearepotentiallytotallyflooded(Figure17d).Threepotentiallytotallyfloodedbelowdrainageminesexceed500acresinarea.Theaveragebedthicknessesoftheseminesrangefrom23.00to49.00inches.Twohundredtwoaboveandnineneardrainageminesarepotentiallypartiallyflooded.Onepotentiallypartiallyfloodedneardrainagemineexceed500acresinarea,andithasanaveragebedthicknessof38.00inches.Visualanalysisindicatesthatintermediatetoverylargeareasofseverallargeabovedrainageminesmaybeflooded(Figure17e).AdditionalinformationaboutpotentialgroundwaterfloodinginthisseamispresentedinFigures17c–e.
PotentialgroundwaterfloodingofundergroundPeerlessminesmaybeaffectedinsomeareasbyundergroundminingofstratigraphicallylowercoalsincluding:theNo.2Gas,Powellton,LowerPowellton,andEagleinpartsofsouthernLoganandMingocountiesandtheNo.2Gas,Powellton,LowerPowellton,Eagle,andLittleEagleinpartsofeasternmostBoone,southernmostKanawha,westernFayette,andnorthwesternRaleighcounties.
PotentiallypartiallyandtotallyfloodedundergroundminesinthePeerlesscoalprovideanestimated53,219.45MMGalofpotentialstorage;97.16percentofthisestimatedstorageisinpotentiallypartiallyfloodedmines.Thispotentialstorageaccountsfor3.85percentoftotalpotentialstorageinundergroundminesofmajorseams(Figure7a).Thiscoalrepresents0.42percentand5.05percentstorageinpotentiallytotallyandpartiallyfloodedmines,respectively,ofmajorseams(Figures7b,c).
No. 2 Gas:Thiscoalgenerallydipstothenorthwestexceptinthevicinityofthesouthwest-northeasttrendingfoldsincludingtheWarfieldAnticlineandtheHandleySynclineandthenorth-northwesttrendingMannMountainAnticline(Figures8and18a).TheNo.2GascropsoutonhillsidesalongtheaxisoftheWarfieldAnticline.Asnotedabove,theNo.2GasandPeerlessbedsoftenmergeandareminedconcurrently.ManyundergroundminesinthiscoalarelocatedintheHandleySyncline,andmostoftheseminesarelocatednearorbelowdrainage.Ranginginthicknessfrom0tomorethan144inches,thiscoalisthickestinnorthernWyoming,westernRaleigh,andsouthernBoonecounties(Figure18b).Bedthicknessinareasofundergroundmininggenerallyrangesfrom24to132inches(Figure18b).
ThisseamhasbeenminedextensivelyacrosssouthernWestVirginia(Figure18c),ofteninconjunctionwiththesuperjacentPeerlesswhenthetwobedsmerge.Theexaminationofminepolygonsforthe565undergroundminesinthisseamindicates506minesarelocatedabovedrainage,39neardrainage,and15belowdrainage(Figure18c).Sixminesaboveorneardrainageand15minesbelowdrainagearepotentiallytotallyflooded(Figure18d).InMingo,Logan,Boone,andKanawhacounties,twonearandeightbelowdrainagemines,whichexceed500acresinarea,arepotentiallytotallyflooded.Theaveragebedthicknessesoftheseminesrangefrom42.08to76.00inches.Visualanalysissuggests460mineslocatedaboveorneardrainagearepotentiallypartiallyflooded(Figure18e).Twenty-threepotentiallypartiallyfloodedneardrainageminesexceed500acresinarea.Theaveragebedthicknessesoftheseminesrangefrom19.00to77.93inches.Althoughpotentialfloodingwouldbelimitedtosmallareasinmostofabovedrainagemines,intermediatetolargeareasofseverallargeminescouldbeflooded.StatisticalinformationaboutpotentialgroundwaterfloodinginthisseamispresentedinFigures18c–e.
PotentialgroundwaterfloodingofNumber2Gasminesmaybeaffectedinsomeareasbyundergroundminingofstratigraphicallylowercoalsincluding:theEagle,Powellton,andLowerPowelltoninpartsofLogan,Mingo,Wyoming,Boone,andMcDowellcounties;theLower2Gas,Eaglelowersplit1,LittleFireCreekinsouthernmostLoganCounty;theEagle,EagleA,andBensCreekinnorthwesternRaleighCounty;andthePowellton,Eagle,andLittleEagleinwesternFayetteandNicholascounties.
PotentiallypartiallyandtotallyfloodedundergroundminesintheNo.2Gascoalprovideanestimated163,753.70MMGalofpotentialstorage;89.78percentofestimatedstorageisinpotentiallypartiallyfloodedmines.Thispotentialstorageaccountsfor11.84percentoftotalpotentialstorageinundergroundminesofmajorseams(Figure7a).Thiscoalrepresents4.64percentand14.37percentstorageinpotentialtotallyandpartiallyfloodedmines,respectively,ofmajorseams(Figures7b,c).
Powellton: Thiscoalgenerallydipstothenorthwestexceptinthevicinityofthesouthwest-northeasttrending foldsincludingtheWarfieldAnticlineandtheHandleySynclineandthenorth-northwesttrendingMannMountainAnticline(Figures8and19a).ThePowelltoncropsoutonhillsidesalongtheaxisoftheWarfieldAnticline.ManyundergroundminesinthiscoalarelocatedintheHandleySyncline,andmostoftheseminesarelocatedbeloworneardrainage.Bedthicknessofthiscoalrangesfrom0tomorethan120inches(Figure19b).Thethickestpartofthe coal bed is in southeastern Mingo County. In areas of underground mining, this bed thickness generally ranges from24to96inches.
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ThisseamhasbeenminedwidelyacrosssouthernWestVirginia(Figure19c).Minepolygonsforthe321minesinthisseamhavebeenexamined,and305minesarelocatedabovedrainage,sevenneardrainage,sixbelowdrainage, and three are not determined. One near drainage mine and the six below drainage mines are potentially totallyflooded,andalloftheseminesexceed500acresinarea(Figures19c,d).Averagebedthicknessesoftheseminesrangefrom46.00to69.00inches.Twohundredsixty-oneaboveandsixneardrainageminesarepotentiallypartiallyflooded.Largetoverylargeareasoftwopotentiallypartiallyfloodedneardrainagemines,whichexceed500acresinarea,maybeflooded(Figure19e).Averagebedthicknessesofthesetwominesare39.00and42.00inches.StatisticalinformationaboutpotentialgroundwaterfloodinginthisseamispresentedinFigures19c–e.
PotentialgroundwaterfloodingofPowelltonminesmaybeaffectedinsomeareasbyundergroundminingofstratigraphicallylowercoalsincluding:theLowerPowellton,Eagle,andEaglelowersplit1inpartsofMingo,Logan,Boone,andwesternKanawhacounties;andtheLowerPowellton,Eagle,LittleEagle,BensCreek,andGlenalumTunnelinnorthwesternRaleigh,westernFayette,andsouthernKanawhacounties.
PotentiallypartiallyandtotallyfloodedundergroundminesinthePowelltoncoalprovideanestimated36,180.12MMGalofpotentialstorage;and67.89percentofestimatedstorageisinpotentiallypartiallyfloodedmines.Thispotentialstorageaccountsfor2.61percentoftotalpotentialstorageinundergroundminesofmajorseams(Figure7a).Thiscoalrepresents3.22percentand2.40percentstorageinpotentialtotallyandpartiallyfloodedmines,respectively,ofmajorseams(Figures7b,c).
Lower Powellton: Thiscoalgenerallydipstothenorthwestexceptinthevicinityofthesouthwest-northeasttrendingfoldsincludingtheWarfieldAnticlineandtheHandleySynclineandthenorth-northwesttrendingMannMountainAnticline(Figures8and20a).TheLowerPowelltoncropsoutalongtheflanksoftheWarfieldAnticline.Ranginginthicknessfrom0tomorethan132inches,thisbedisthickestinsoutheasternLoganandnorthwesternWyomingcounties(Figure20b).Bedthicknessinareasofundergroundmininggenerallyrangesfrom24to84inches(Figure20b).
ThiscoalhasbeenminedwidelyacrosssouthernWestVirginia(Figure20c).Examinationofthe119minepolygonsforthisseamshows112minesarelocatedabovedrainage,fiveneardrainage,andtwobelowdrainage(Figure20c).Oneabovedrainageandtwobelowdrainageminesarepotentiallytotallyflooded(Figure20d).Twopotentiallytotallyfloodedbelowdrainageminesthataregreaterthan500acresinareaarelocatedinMingoCounty.Theaveragebedthicknessesoftheseminesare29.84and41.00inches.Visualanalysissuggests103mineslocatedaboveorneardrainagearepotentiallypartiallyflooded(Figure20e).Althoughpotentialfloodingwould be limited to small areas in most of these mines, large areas of two near drainage mines in Mingo County thatexceed500acresinareacouldbeflooded.Theaveragebedthicknessesofthesetwominesare34.00and46.00inches.StatisticalinformationaboutpotentialgroundwaterfloodinginthisseamispresentedinFigures20c–e.
PotentialgroundwaterfloodingofLowerPowelltonminesmaybeaffectedinsomeareasbyundergroundminingofstratigraphicallylowercoalssuchas:theEagleinpartsofFayette,Kanawha,Logan,Mingo,Raleigh,andWyomingcounties;theLittleFireCreekinsoutheasternLoganCounty;andtheEaglelowersplit1,MiddleWarEagle,andBensCreekinnorthwesternWyomingCounty.
PotentiallypartiallyandtotallyfloodedundergroundminesintheLowerPowelltoncoalprovideanestimated10,062.01MMGalofpotentialstorage;87.71percentofestimatedstorageisinpotentiallypartiallyfloodedmines.Thispotentialstorageaccountsfor0.73percentoftotalpotentialstorageinundergroundminesofmajorseams(Figure7a).Thiscoalrepresents0.34percentand0.86percentstorageinpotentiallytotallyandpartiallyfloodedmines,respectively,ofmajorseams(Figures7b,c).
Eagle:Dipdirectionofthiscoalisgenerallytothenorthwestexceptinthevicinityofthesouthwest-northeasttrendingfolds(Figures8and21a).TheEaglecropsoutonhillsidesalongtheflanksoftheWarfieldAnticline.ManyundergroundminesinthiscoalarelocatedinsynclinesnorthwestandsoutheastoftheWarfieldAnticline,andmostoftheseminesarelocatedbeloworneardrainage.Thisbedrangesfrom0tomorethan132inchesinthickness,anditisthickestinsouthernBooneCounty(Figure21b).Bedthicknessinareasofundergroundmininggenerallyrangesfrom24to96inches(Figure21b).
ThisseamhasbeenminedwidelyacrosssouthernWestVirginia(Figure21c).Minepolygonsforthe494minesinthisseamhavebeenexamined,and414minesareabovedrainage,46neardrainage,16belowdrainage,and18areundetermined(Figure21c).Fourminesabovedrainage,fiveminesneardrainage,and16minesbelowdrainagearepotentiallytotallyflooded(Figure21d).Elevenbelowdrainageandtwoneardrainage
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minesexceeding500acresinareaarepotentiallytotallyflooded.Therangeofaveragebedthicknessesoftheseminesrangefrom33.31to62.00inches.Threehundredsixty-threeaboveandneardrainageminesarepotentiallypartiallyflooded,andvisualanalysissuggestslargeareasof22oftheseminescouldbeflooded(Figure21e).Fifteenneardrainagemines,whicharepotentiallypartiallyflooded,aregreaterthan500acresinareaandtheaveragebedthicknessesrangefrom30.00to75.00inches.StatisticalinformationaboutpotentialgroundwaterfloodinginthisseamispresentedinFigures21c–e.
PotentialgroundwaterfloodingofEagleminesmaybeaffectedinlimitedareasbyundergroundminingofstratigraphicallylowercoalbedssuchas:theLittleEagle,GlenalumTunnel,BensCreek,andBeckleyinpartsofwesternFayetteandnorthwesternRaleighcounties;theEaglelowersplit1andBensCreekinnorthwesternWyomingCounty;andtheMiddleWarEagleandLowerWarEagleinpartsofsoutheasternMingoandnorthwesternMcDowellcounties.
PotentiallypartiallyandtotallyfloodedundergroundminesintheEaglecoalprovideanestimated105,126.15MMGalofpotentialstorage;and77.64percentofestimatedstorageisinpotentiallypartiallyfloodedmines.Thispotentialstorageaccountsfor7.60percentoftotalpotentialstorageinundergroundminesofmajorseams(Figure7a).Thiscoalrepresents6.52percentand7.98percentstorageinpotentiallytotallyandpartiallyfloodedmines,respectively,ofmajorseams(Figures7b,c).
New River Formation
TheLowerPennsylvanianNewRiverFormation(Figures6a,f)includes20namedcoalbeds,and14havebeen mined by underground methods. The Sewell and Beckley seams have the greatest potential for containing totallyorpartiallyfloodedminevoids.Minesintheothercoalbedstendtobesmall,aregenerallyabovedrainage,andthereforecontainlimitedpotentialforstoringsignificantvolumesofgroundwater.
Sewell:Thiscoalbedgenerallydipstothenorthwestexceptinthevicinityofthesouthwest-northeasttrendingPinevilleandMullensanticlines,thenorth-northwest-south-southeasttrendingMannMountainAnticline,andthesouth-southwest-north-northeasttrendingWebsterSpringsAnticline(Figures8and22a).Bedthicknessrangesfrom0tomorethan120inches,andthethickestpartofthiscoalbedisinnorth-centralRaleighCounty(Figure22b).Availablebedthicknessdatainareasofundergroundmininggenerallyrangefrom24to84inches(Figure22b).
ThisseamhasbeenminedbyundergroundmethodsinMcDowell,Wyoming,Raleigh,Fayette,Nicholas,Greenbrier,andWebstercounties.ThelargeminesintheSewell,especiallytheonesbelowdrainage,offerhighpotential for supplying water resources. The down dip areas of some of the large mines located near or above drainagealsohavepotentialforsupplyingwaterresources.Ofthe599minesinthisseam,415arelocatedinareaswherestructurecontourandcroplinedataareavailable.Threehundredsixty-eightoftheseminesareabovedrainage,31neardrainage,and16belowdrainage(Figure22c).Oneneardrainagemineand16belowdrainageminesarepotentiallytotallyflooded(Figure22d);and240abovedrainageminesand28neardrainageminesarepotentiallypartiallyflooded(Figure22e).Twelvepotentiallytotallyfloodedbelowdrainageminesexceed500acresinareaandaveragebedthicknesses37.00to57.00inches.Thirteenpotentiallypartiallyfloodedneardrainageminesexceed500acresinarea,andaveragebedthicknessesfortheseminesrangefrom27.00to57.00inches.Largeareasofseveralabovedrainageminesexceeding500acresinareamaybeflooded.StatisticalinformationaboutpotentialgroundwaterfloodinginthisseamispresentedinFigures22c–e.
PotentialgroundwaterfloodingofundergroundSewellminesmaybeaffectedbyundergroundminingofstratigraphicallylowercoalbedsincluding:theBeckleyinpartsofRaleighandNicholascounties;theWelch,Beckley,FireCreek,andPocahontas3inpartsofcentralMcDowellCounty;theBeckleyandPocahontas3inpartsofeasternWyomingCounty;andtheFireCreekinpartsofeasternFayette,westernGreenbrier,andsoutheasternWebstercounties.
PotentiallypartiallyandtotallyfloodedundergroundminesintheSewellcoalprovideanestimated70,722.33MMGalofpotentialstorage;and71.73percentofestimatedstorageisinpotentiallypartiallyfloodedmines. This potential storage accounts for 5.11 percent of total potential storage in underground mines of major seams(Figure7a).Thiscoalrepresents5.54percentand4.96percentstorageinpotentiallytotallyandpartiallyfloodedmines,respectively,ofmajorseams(Figures7b,c).
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Beckley:Thiscoalgenerallydipstowardthenorthwest(Figure23a).Coalbedthicknessrangesfrom0tomorethan144inches,andthiscoalbedisthickestinwesternRaleighCounty,northernWyomingCounty,andcentralMcDowellCounty(Figure23b).Inareaswhereundergroundmininghastakenplace,bedthicknessgenerallyrangesfrom24to84inches(Figure23b).
UndergroundminesintheBeckleyarelocatedinRaleigh,Wyoming,McDowell,Mercer,andGreenbriercounties(Figure23c).Ofthe271minesinthisseam,112arelocatedinareaswherecroplinedataarecurrentlyavailable.Ninety-sixofthese112minesarelocatedabovedrainage,tenneardrainage,andsixbelowdrainage.Thesixbelowdrainagemines,whicharelocatedinRaleighCounty,arepotentiallytotallyflooded;andfiveexceed500acresinarea(Figure23d).Averagebedthicknessesfortheseminesrangefrom49.00to70.75inches.Seventy-sevenabovedrainageminesandtenneardrainageminesarepotentiallypartiallyflooded.Fourpotentiallypartiallyfloodedneardrainageminesaregreaterthan500acresinarea;oneislocatedinnorth-centralRaleighCountyandthreeareinsouthernMcDowellCounty(Figure23e).Averagebedthicknessesfortheseminesrangefrom35.00to54.00inches.StatisticalinformationaboutpotentialgroundwaterfloodinginthisseamispresentedinFigures23c–e.
PotentialgroundwaterfloodingofundergroundBeckleyminesmaybeaffectedbyundergroundminingofstratigraphicallylowercoalbedsincluding:theFireCreekandPocahontasNos.7,6uppersplit1,6,4and3inpartsofRaleighCounty;theFireCreekandPocahontasNos.6,4,and3inpartsofeasternWyomingCounty;theFireCreek,LittleFireCreekandPocahontasNos.6,4,and3inpartsofMcDowellCounty;andtheFireCreekand Pocahontas No. 3 in westernmost Mercer County.
PotentiallypartiallyandtotallyfloodedBeckleyseamundergroundminesprovideanestimated25,975.14MMGalofpotentialstorage;51.88percentofestimatedstorageisinpotentiallypartiallyfloodedmines.Thispotentialstorageaccountsfor1.88percentoftotalpotentialstorageinundergroundminesofmajorseams(Figure7a).Thiscoalrepresents3.47percentand1.32percentstorageinpotentiallytotallyandpartiallyfloodedmines,respectively,ofmajorseams(Figures7b,c).
FireCreek:UndergroundminesinthisseamarelocatedinMcDowell,Mercer,Wyoming,Raleigh,Fayette,Greenbrier,Pocahontas,andWebstercounties.Ofthe459minesinthisseam,411arelocatedinareascurrentlywithoutcompletedstructurecontourandcroplinemaps.Fourhundredtenoftheseminesareabovedrainage,noneneardrainage,andonebelowdrainage.Thebelowdrainagemineislessthan500acresinarea.Theseminesaremostly small and have limited potential to store large volumes of groundwater.
Pocahontas Formation
TheLowerPennsylvanianPocahontasFormation(Figures6a,f)includes12namedcoalbedsofwhicheighthavebeenminedbyundergroundmethods.Theseamshavingthegreatestpotentialfortotallyandpartiallyfloodedmine voids are the Pocahontas No. 2, Pocahontas No. 3, Pocahontas No. 4, and Pocahontas No. 6.
PocahontasNo.6uppersplit1:UndergroundminingofthisseamhastakenplaceinWyoming,Raleigh,andMercercounties.Ofthese65mines,45minesarelocatedinareasinwhichCBMPmappinghasbeencompleted.Forty-fourofthese45minesarelocatedabovedrainage,andonemineislocatedneardrainage.Twenty-threeabovedrainageminesandone115.09-acreneardrainageminearepotentiallypartiallyfilledbygroundwater.
Pocahontas No. 6: Thiscoalgenerallydipstothenorthwest;however,thesouthwest-northeasttrendingMullensandPinevilleanticlinesinWyomingCountyandtheBoggsKnobAnticlineandanunnamedsynclinelocallyaffectdipdirectionineasternmostFayetteCounty(Figures8and24a).WheredataareavailableinpartsofFayette,Raleigh,andWyomingcounties,rangesfrom0tomorethan96inches(Figure24b).Intheareaswhereundergroundmininghasoccurred,thiscoalbedisgenerally24to72inchesthick(Figure24b).
The262undergroundminesinthisseamarelocatedinsouthernWestVirginia(Figure24c).Forty-onemines are located in areas where no structure contour and cropline coverages are currently available. One hundred ninety-nineminesarelocatedabovedrainage,16neardrainage,andfourbelowdrainage(Figure24c).Thefourbelowdrainageminesandtwosmallabovedrainageminesarepotentiallytotallyfloodedbygroundwater(Figure24d),andoneoftheseminesexceeds500acresinarea.Theaveragebedthicknessofthismineis31.00inches.Onehundredtwelveabovedrainageminesand16neardrainageminesarepotentiallypartiallyfloodedbygroundwater(Figure24e).Eightofthepotentiallypartiallyfloodedneardrainageminesaregreaterthan500acresinareaandaveragebedthicknessesoftheseminesrangefrom27.00to37.00inches.StatisticalinformationaboutpotentialgroundwaterfloodinginthisseamispresentedinFigures24c–e.
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AreallyextensiveundergroundminesinthestratigraphicallylowerPocahontasNo.3coalmayaffectgroundwaterfloodinginPocahontasNo.6undergroundminesinsouthernRaleigh,westernMercer,easternWyoming,easternMcDowell,andnorthernSummerscounties.
PotentiallypartiallyandtotallyfloodedundergroundminesinthePocahontasNo.6provideanestimated19,883.69MMGalofpotentialstorage;and94.32percentofestimatedstorageisinpotentiallypartiallyfloodedmines. This potential storage accounts for 1.44 percent of total potential storage in underground mines of major seams(Figure7a).Thiscoalrepresents0.31percentand1.83percentstorageinpotentiallytotallyandpartiallyfloodedmines,respectively,ofmajorseams(Figures7b,c).
PocahontasNo.5:ThiscoalhasbeenminedbyundergroundmethodsinMcDowell,Mercer,andRaleighcounties.Ofthe26minesinthisseam,25arelocatedinareasinwhichstructurecontourandcroplinedataarecurrentlyavailable.Allundergroundminesinthisseamarealocatedabovedrainage,and15ofthemarepotentiallypartiallyfloodedbygroundwater.ThedowndipareasoffouroftheseminesarepartlylocatedinVirginiawherepotentialfloodingismorelikelytooccur.
Pocahontas No. 4: Thiscoalgenerallydipstothenorthwest;however,thesouthwest-northeasttrendingPineville,Mullens,andDryForkanticlineslocallyaffectdipdirectioninareasofRaleigh,Wyoming,andMcDowellcounties(Figure25a).ErosionalremnantsofthePocahontasNo.4occuralongthesouthwest-northeasttrendingDryForkAnticlineinsoutheasternMcDowellCounty.Availabledataindicatebedthicknessrangesfrom0tomorethan144inches,andthethickestpartofthecoalbedisinsoutheasternMcDowellCountywhereithasbeenminedbasicallytoexhaustion.Intheareaswhereundergroundmininghasoccurred,thiscoalbedisgenerally24to108inchesthick(Figure25b).
UndergroundmininginthisseamhastakenplaceinMcDowellandWyomingcounties(Figure25c).Ofthe58minesinthisseam,55arelocatedinareaswherestructurecontourandcroplinedatahavebeencompleted.Thirty-nineminesarelocatedabovedrainage,nineneardrainage,andsevenbelowdrainage(Figure25c).Sevenbelowdrainageminesarepotentiallytotallyflooded,andsixofthesearegreaterthan500acresinarea(Figure25d).Thesesixmineshaveaveragebedthicknessesrangingfrom28.50to67.47inches.Thirty-oneoftheabovedrainageminesand9oftheneardrainageminesarepotentiallypartiallyflooded(Figure25e).Fourpotentiallypartiallyfloodedneardrainageminesexceed500acresinarea,andlargetoverylargeareasoftheseminescouldbeflooded.Theaveragebedthicknessesofthesefourminesrangefrom45.28to78.27inches.StatisticalinformationaboutpotentialgroundwaterfloodinginthisseamispresentedinFigures25c–e.
InpartsofcentralandsoutheasternMcDowellCountyandeasternWyomingCounty,groundwaterfloodingof underground mines in the Pocahontas No. 4 will likely be affected in areas where underground mines in the PocahontasNo.3arepresentlessthat100feetbelow.
PotentiallypartiallyandtotallyfloodedundergroundminesinthePocahontasNo.4coalprovideanestimated50.432.56MMGalofpotentialstorage;and64.42percentofestimatedstorageisinpotentiallypartiallyfloodedmines.Thispotentialstorageaccountsfor3.64percentoftotalpotentialstorageinundergroundminesofmajorseams(Figure7a).Thiscoalrepresents4.98percentand3.18percentstorageinpotentiallytotallyandpartiallyfloodedmines,respectively,ofmajorseams(Figures7b,c).
Pocahontas No. 3:Thiscoalgenerallydipstothenorthwest;however,thesouthwest-northeasttrendingPineville,Mullens,andDryForkanticlineslocallyaffectdipdirectioninareasofRaleigh,Wyoming,andMcDowellcounties(Figure26a).ErosionalremnantsofthePocahontasNo.3occuralongthesouthwest-northeasttrendingDryForkAnticlineinsoutheasternMcDowellCounty.IsopachmapsforthePocahontasNo.3werenotavailableatthetimeofthiswriting.However,dataindicatethatthePocahontasNo.3rangesinthicknessfrom0tomorethan120inches.
ThisseamhasbeenminedextensivelybyundergroundmethodsinWyoming,McDowell,Raleigh,Mercer,andSummerscounties(Figure26c).Ofthe299minesinthisseam,280arelocatedinareasinwhichstructurecontour maps are currently available; however, cropline data are available for the areas in which these mines arelocated.Twohundredthirty-twooftheseminesarelocatedabovedrainage,35neardrainage,and13belowdrainage(Figure26c).Inareaswherestructurecontourcoveragesareavailable,visualanalysisindicates13belowdrainageminesarepotentiallytotallyflooded(Figure26d)and178abovedrainageminesand33neardrainageminesarepotentiallypartiallyfilledbygroundwater(Figure26e).Twelvepotentiallytotallyfloodedminesexceed500acresinarea,andaveragebedthicknessesoftheseminesrangefrom35.00to67.00inches.Twenty-twopotentiallypartiallyfloodedneardrainageminesexceed500acresinarea,andaveragebedthicknessesoftheseminesrangefrom38.08to80.58inches.StatisticalinformationaboutpotentialgroundwaterfloodedinthisseamispresentedinFigures26c-e.
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PotentiallypartiallyandtotallyfloodedundergroundminesinthePocahontasNo.3coalprovideanestimated161,086.42MMGalofpotentialstorage80.14percentofestimatedstorageisinpotentiallyfloodedmines.Thispotentialstorageaccountsfor11.64percentoftotalpotentialstorageinundergroundminesofmajorseams(Figure7a).Thiscoalrepresents8.87percentand12.62percentstorageinpotentialtotallyandpartiallyfloodedmines,respectively,ofmajorseams(Figures7b,c).
Pocahontas No. 2: Thiscoalbeddipstothenorthwest(Figure27a).Wheredataareavailable,thisbedisgenerally24to36inchesthick(Figure27b),anditisthickestinsouthernRaleighCounty.Inareaswhereundergroundmininghastakenplace,bedthicknessgenerallyrangesfrom24tomorethan36inches(Figure23b).
The15undergroundminesinthisseamarelocatedinMcDowell,Mercer,andRaleighcounties(Figure27c).Fourteenminesarelocatedabovedrainage,andonemineislocatedneardrainage(Figure27c).Nopotentiallytotallyfloodedbelowdrainageminesarepresentinthiscoalbed(Figure27d).Sixofthese14abovedrainagemineshaveverysmalltosmallareasthatarepotentiallypartiallyfilledbygroundwater.Largeareasofthepotentiallypartiallyfloodedneardrainagemine,whichexceeds500acresinarea,islocatedinsouthernRaleighCounty.Theaveragecoalbedthicknessofthismineis31.00inches(Figure27e).StatisticalinformationaboutpotentialgroundwaterfloodinginthisseamispresentedinFigures27c–e.
PotentiallypartiallyfloodedundergroundminesinthePocahontasNo.2coalprovideanestimated947.09MMGaloftotalpotentialstorage,andtheseminesaccountfor0.09percentoftotalpotentialgroundwaterstorageand2.85percentofpotentialpartialstorageinundergroundminesofmajorseams(Figures7a–c).
DISCUSSION
Inthisstudy8,907ofthe9,539minepolygonsexaminedrepresentedabovedrainageundergroundmines.Thepotentialfortotalorpartialfloodingintheseminesislesscertainthanitisfornearandbelowdrainagemines.Theseabovedrainageminesareincoalbedsthatcropoutonhillsidesandhilltops.Perchedaquifersabovelocaldrainagehaveamorelimitedarealextentthantheunconfinedandconfinedaquifersassociatedwithnearandbelowdrainagemines.Thedegreeofcertaintyaboutextentofpotentialfloodingofminevoidsisgreatestinbelowdrainage mines and least in above drainage mines.
Althoughbelowandneardrainagemineshaveagreaterpotentialforflooding,storageinabovedrainageminesshouldnotbeoverlooked.Statewidepublicwatersupplydatawasanalyzedaspartofthisstudytodeterminewhichwatersourceswereassociatedwithundergroundmines.Twenty-sevenpublicwatersupplies,whicharelocatedinBoone,Kanawha,Logan,Mingo,Fayette,Greenbrier,McDowell,Raleigh,andWyomingcounties,wereidentifiedasbeingassociatedwithundergroundminesintheseninecoalbeds:Stockton;Winifrede;FireClay;No.2Gas;Sewell;Beckley;FireCreek;PocahontasNo.4;andPocahontasNo.6.Tenofthesepublicwatersuppliesarespringsformedwhereoldworkscropoutand17arewellsdrilledintooldmines.Twenty-twoarelocatedabovedrainageandfourarelocatedneardrainage,mostlyinpotentialpartiallyfloodedmines;andoneis located below drainage.
AnimportantfindingofthisstudyistherecognitionthattotalestimatedpotentialstorageinthePittsburghminepoolssurpassesthatofminepoolsineachoftheothermajorcoalbedsincludingtheNo.2Gas,PocahontasNo.3,Eagle,andSewell.Thisfactisduetothewidearealextentofthiscoalbed,itspositionwithrespecttomajor drainage, and its greater average thickness.
This study addressed the potential for large volumes of groundwater storage in underground mines based on minevoidvolume.Determiningtheactualextentofgroundwaterfloodinginspecificundergroundminesrequiresmoreindepthstudies.RecentstudiesoftheextentofminepoolfloodingiintheMonongahelaBasin,whicharebasedonwater-levelmeasurementswithinspecificminesofthePittsburghcoalbedinnorthernWestVirginiaandsouthwesternPennsylvania(ZiemkiewiscandVandivort,2004,Ziemkiewiscetal.,2004,andDonovan,2004a,2004b),haveprovidedinsightintotheformationofminepools.Ziemkiewiscetal.(2004)notedthattheamountofhydraulic connection between adjacent mines was affected by barrier pillar geometry and thickness and the leakage ratethroughbarrierpillars.Donovan(2004a)reportedinstancesinwhichgroundwaterpumpingininactiveorclosed mines adjacent to an active mine was used to control mine pool elevations to minimize leakage into the activemine.Theassumptionthatallinactivebelowdrainageminesarefloodedcanbemisleading.Donovan(2004b,p.38)notedthattheValleyCamp1mine,whichisabelowdrainagemineinthePittsburghcoalinBrookeCounty,“...hasbeenclosedforover20years,thefactthatthemineisdryindicatesthatthereisverylittleinflowtothis mine ....”
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Multipleseamminingmayalsoaffectgroundwaterfloodinginundergroundmines.IntheMonongahelaBasinminefloodingstudy,Donovan(2004a,p.98)reportedthat“verticalinfiltrationtoundergroundminesofthePittsburghcoalseamisinfluencedbythreeprincipalfactors:(a)depth,(b)thepresenceorabsenceofoverlyingSewickleymining,and(c)statusofflooding.”UndergroundminingofmultiplecoalbedshasoccurredinmanyareasoftheState.Forexample,undergroundminesarepresentin14KanawhaFormationcoalbedsintheHandleySynclineinsouthwesternWestVirginia,andminesinmultipleseamsoverlapinseveralareas.Manyoftheundergroundminesinthisareacouldbetotallyorpartiallyflooded,butfracturingofoverburdeninoverlappingminesmayaffectpotentialflooding,especiallyinminesoftheuppercoalbeds.Thehydrologicinteractionbetween mines in more than one seam is beyond the scope of this project, and actual determination of mine floodingshouldbeinvestigatedonacasebycasebasis.
CONCLUSIONS
ThetotalpotentialstorageinthePittsburghseamsurpassesthatofothermajorseamssuchastheNumber2Gas,PocahontasNo.3,Eagle,andSewell.Themainreasonsarethewidelateralextentofthisseamanditsgreateraverage thickness.
MuchoftheundergroundminingintheWestVirginiahasoccurredabovedrainage.Theexaminationof9,539minepolygonsofminingin69seamsdetermined8,907minesareabovedrainage;325areneardrainage,178arebelowdrainage,and129arecurrentlyundetermined.
Ninety-nineminesin14majorseamsarepotentiallytotallyfloodedandaregenerallylocatedbelowdrainage. These mines are located in these seams in the following counties:
▪ PittsburghseaminOhio,Marshall,Monongalia,Marion,andHarrisoncounties ▪ UpperFreeportseaminPrestonCounty ▪ MiddleKittanningseaminPrestonandBarbourcounties ▪ CoalburgseaminWayneandLincolncounties ▪ PeerlessseaminKanawha,Nicholas,andMingocounties ▪ No.2GasseaminLogan,Mingo,Boone,andKanawhacounties ▪ PowelltonseaminBoone,Logan,andMingocounties ▪ LowerPowelltonseaminMingoCounty ▪ EagleseaminNicholas,Fayette,Kanawha,Boone,Logan,andMingocounties ▪ SewellseaminNicholas,Fayette,Raleigh,andWyomingcounties ▪ BeckleyseaminFayette,Raleigh,andWyomingcounties ▪ PocahontasNo.6seaminRaleighCounty ▪ PocahontasNo.4seaminMcDowellCounty ▪ PocahontasNo.3seaminWyoming,McDowell,andRaleighcounties
Potentialpartialfloodingwaspresentin532mines;147minesarelocatedneardrainageand385areabovedrainage.Nineteenseamscontainpotentiallypartiallyfloodedmines;theseseamsincludethe14listedabovethatalsohavepotentiallytotallyfloodedmines.Potentialpartiallyfloodedminespresentinthefiveotherseamsarelocated in these counties:
▪ SewickleyseaminMonongaliaandMarioncounties ▪ BakerstownseaminPreston,Grant,andTuckercounties ▪ No.5BlockseaminBraxton,Nicholas,Clay,Kanawha,Boone,Lincoln,Mingo,andWaynecounties ▪ StocktonseaminBraxton,Nicholas,Kanawha,Boone,Logan,Lincoln,andMingocounties. ▪ PocahontasNo.2seaminRaleighCounty.
Althougheffortsaremadetousebestavailabledataandlocateminesasaccuratelyaspossible,minelocationsshouldbeconsideredapproximate.Theactualextentofminingmaybeunknownbecausefinalminemaps at the time of mine closures are not always available and not all underground mining has been documented by minemaps.Thequalityofminesmapsishighlyvariableintheamountofdetailandinformationpresented.Someof the newer mine maps are available in digital form; however, many older mine maps have been photographically reduced from dimensionally unstable paper copies. Photographic reduction also introduced distortion due to lens geometry.Also,coalcorrelationsmaychangewithadditionalinformation.Activeminesarenotdifferentiatedfrom recently closed mines in the CBMP database.
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Theextentofpotentialminefloodingisdependentonseveralfactors,includingmineorientation,locationsofmineentries,proximitytootherundergroundmines,anddirectionofgroundwaterflow.Groundwaterpumpingtoenableundergroundminingcanaffectwaterlevelsinadjacentundergroundmines.Minefloodinginoneseamalso may be affected by underground mining in stratigraphically lower coals. In general, once pumping ceases, the minesbegintoflood.
Theresultsofthisstudyshouldbeconsidereda“snapshot”ratherthanafinishedproduct.NewminescontinuallyopeninWestVirginiaandinadjoiningstatesneartheState’sborders.Inaddition,newlyobtainedminingcoveragesarebeingconstantlyupdatedintheCBMPGISasnewinformationbecomesavailable.Allofthesefactorsreinforcetheneedfordetailedsite-specificstudiestodeterminetheactualpresenceofadequatewaterresources.
REFERENCES
Donovan,Joseph,2004a,IntegratedModeling,inZiemkiewicz,Paul,andVandivort,Tamara,WV173PhaseIIIEPARegionIIIMinePoolProject:WestVirginiaWaterResearchInstitute,p.41-100,http://wvwri.nrcce.wvu.edu/programs/mbmpp/publications/FinalReport_PhaseIII.pdf(accessedFebruary23,2012).
Donovan,Joseph,2004b,Fieldcharacterization/mappingstudies,inZiemkiewicz,Paul,Donovan,Joseph,Stiles,James,Leavitt,Bruce,andVandivort,Tamara,WV173PhaseIVEPARegionIIIMinePoolProject:WestVirginiaWaterResearchInstitute,p.8-48,http://wvwri.nrcce.wvu.edu/programs/mbmpp/publications/FinalReport_PhaseIV.pdf(accessedFebruary27,2012).
McColloch,J.S.,Binns,R.D.,Jr.,Blake,B.M.,Jr.,andMcColloch,G.H.,Jr.,2011,WestVirginiaMinePoolAtlas
Project—AWorkinProgress:http://ngmdb.usgs.gov/Info/dmt/DMT11presentations.html(accessedMarch29,2012).
Morris,A.J.,Donovan,J.J.,andThies,J.E.,2008,ReconnaissanceSpatialAnalysisoftheHydrogeologyofClosedUndergroundCoalMines:EnvironmentalGeosciences,v.15,no.4,p.183-197.
SoutheastRegionalClimateCenter(SERRC),2011,WestVirginiaStateAveragedPrecipitationData:http://www.sercc.com/climateinfo_files/monthly/West%20Virginia_prcp.html(accessedOctober20,2011).
WestVirginiaDepartmentofEnvironmentalProtection(WVDEP),2008,AnnualReporttotheJointLegislativeOversightCommissiononStateWaterResources:ImplementationProgressWestVirginiaWaterResourcesProtectionandManagementAct:WestVirginiaDepartmentofEnvironmentalProtection,DivisionofWaterandWasteManagement,WaterUseSection,p.22.
WestVirginiaGeologicalandEconomicSurvey(WVGES),2010a,WestVirginiaCoalBedMapping:http://ims.wvgs.wvnet.edu/All_Coal/viewer.htm(accessedMay20,2011).
———2011,WestVirginiaMineMapRepository:http://downloads.wvgs.wvnet.edu/minemaps/(accessedMay20,2011).
Wood,G.H.,Jr.,Kehn,T.M.,Carter,M.D.,andCulbertson,W.C.,1983,CoalresourceclassificationsystemoftheU.S.GeologicalSurvey:U.S.GeologicalSurveyCircular891,65p.
Ziemkiewicz,Paul,andVandivort,Tamara,2004,WV173PhaseIIIEPARegionIIIMinePoolProject:WestVirginiaWaterResearchInstitute,144p.,http://wvwri.nrcce.wvu.edu/programs/mbmpp/publications/FinalReport_PhaseIII.pdf(accessedFebruary23,2012).
Ziemkiewicz,Paul,Donovan,Joseph,Stiles,James,Leavitt,Bruce,andVandivort,Tamara,2004,WV173PhaseIVEPARegionIIIMinePoolProject:WestVirginiaWaterResearchInstitute,395p.,http://wvwri.nrcce.wvu.edu/programs/mbmpp/publications/FinalReport_PhaseIV.pdf(accessedFebruary27,2012).
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MINE POOL ATLAS
FIGURES
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Figure 1. Status of coal bed mapping by the WVGES CBMP as of June 30, 2011 (B.M. Blake, unpub. data, 2011)
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Figure 2. Footprints of all documented underground mines in West Virginia coal seams delineate areas of potential mine pools (WVGES, 2010).
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Figure 3. Watershed model output shows predicted direction of groundwater flow through mine voids in the Sewell coal bed on the Fayetteville 7.5-minute topographic quadrangle and surrounding area. The blue watershed area represents water flow from mines contributing to surface water flow. Red arrows show flow direction. This model was run for all coal beds having available input data to aid in determining extent of potential flooding in underground mines.
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Figure 4. Major Drainage–Mining Above/Below Drainage (MABD) model output shows areas of the Sewell coal bed that lie above and below major drainage on the Fayetteville 7.5-minute topographic quadrangle and surrounding area. This model, which was developed to determine mine position with respect to drainage based on perennial stream elevations, generated a Major Drainage Elevation Model (MDEM) by assigning USGS 7.5-minute quadrangle elevations to points selected from the National Hydrography Dataset (NHD) that are located within digitized perennial stream polygons.
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Figure 5. Perennial Drainage –Mining Above/Below Drainage model output shows areas of the Sewell coal bed that lie above and below perennial drainage on the Fayetteville 7.5-minute topographic quadrangle and surrounding area. This model, which was developed to determine mine position with respect to drainage based on perennial stream elevations, generated a Perennial Drainage Elevation Model (PDEM) by assigning USGS 7.5-minute quadrangle elevations to points selected from the National Hydrography Dataset (NHD) that are located along digitized perennial stream lines.
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Figure 6b
Figure 6c
Figure 6. Stratigraphic chart and columns of the Pennsylvania coal-bearing strata in West Virginia: (a) stratigraphic chart shows age and stratigraphic position of groups/formations; (b) stratigraphic column of the Dunkard and Monongahela Groups; (c) stratigraphic column of the Conemaugh Group; (d) stratigraphic column of the Allegheny Formation; (e) stratigraphic column of the Kanawha Formation; and (f) stratigraphic column of the New River and Pocahontas Formations. The names of the 19 major seams identified in this report, mineable coal beds, and named unmined coal beds are shown in blue, orange, and black, respectively.
Figure 6a
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