Snake River Plain FORGE: Site Characterization Data

                                            [
  "019:20"
]
                                        

                                            {
  "fn": "Robert Podgorney",
  "@type": "vcard:Contact",
  "hasEmail": "mailto:robert.podgorney@inl.gov"
}
                                        

                                            true
                                        

                                            [
  {
    "@type": "dcat:Distribution",
    "title": "Anders et al 2014 paper on geologic history of Snake River Plain",
    "format": "HTML",
    "accessURL": "https://doi.org/10.1002/2013JB010483",
    "mediaType": "text/html",
    "description": "Anders et al, 2014. "A fixed sublithospheric source for the late Neogene track of the Yellowstone hotspot: Implications of the Heise and Picabo volcanic fields""
  },
  {
    "@type": "dcat:Distribution",
    "title": "Smith et al 1996 paper on extensional structures and volcanic terrains",
    "format": "HTML",
    "accessURL": "https://doi.org/10.1029/95JB01393",
    "mediaType": "text/html",
    "description": "Smith et al, 1996. "Paleoseismology and seismic hazards evaluations in extensional volcanic terrains." Extensional structures in volcanic terrains are the surface expression of shallow dike intrusion and can be misinterpreted as structures associated with major tectonic faults..."
  },
  {
    "@type": "dcat:Distribution",
    "title": "Peng and Humphreys 1998 paper on crustal velocity structure of SRP",
    "format": "HTML",
    "accessURL": "https://doi.org/10.1029/97JB03615",
    "mediaType": "text/html",
    "description": "Peng and Humphreys, 1998. "Crustal velocity structure across the eastern Snake River Plain and the Yellowstone swell.""
  },
  {
    "@type": "dcat:Distribution",
    "title": "Smith et al 1978 paper on Snake River Plain seismic profiling experiment",
    "format": "HTML",
    "accessURL": "https://doi.org/10.1029/JB087iB04p02583",
    "mediaType": "text/html",
    "description": "Smith et al, 1978. "Yellowstone-Eastern Snake River Plain Seismic Profiling Experiment: Crustal structure of the Yellowstone Region and experiment design.""
  },
  {
    "@type": "dcat:Distribution",
    "title": "Sparlin et al 1982 paper on Crustal structure of the Snake River Plain",
    "format": "HTML",
    "accessURL": "https://doi.org/10.1029/JB087iB04p02619",
    "mediaType": "text/html",
    "description": "Sparlin et al, 1982. "Crustal structure of the Eastern Snake River Plain determined from ray trace modeling of seismic refraction data.""
  },
  {
    "@type": "dcat:Distribution",
    "title": "Panakratz and Ackerman 1982 paper on Seismic Refraction of SRP",
    "format": "HTML",
    "accessURL": "https://doi.org/10.1029/JB087iB04p02676",
    "mediaType": "text/html",
    "description": "Panakrazt and Ackerman, 1982. "Structure along the northwest edge of the Snake River Plain interpreted from seismic refraction." "
  },
  {
    "@type": "dcat:Distribution",
    "title": "Payne at al 2008 snake river plain strain rates paper",
    "format": "1",
    "accessURL": "https://doi.org/10.1130/G25039A.1",
    "mediaType": "application/octet-stream",
    "description": ""Strain rates and contemporary deformation in the Snake River Plain and surrounding Basin and Range from GPS and seismicity", Suzette J. Payne, Robert McCaffrey and Robert W. King, 2008."
  },
  {
    "@type": "dcat:Distribution",
    "title": "Leeman et al 2008 paper on Snake River Plain - Yellowstone volcanism",
    "format": "12",
    "accessURL": "https://doi.org/10.1144/sp304.12",
    "mediaType": "application/octet-stream",
    "description": "Leeman et al, 2008. "Snake River Plain - Yellowstone silicic volcanism: implications
for magma genesis and magma fluxes" "
  },
  {
    "@type": "dcat:Distribution",
    "title": "3D Model snapshot no outflow.png",
    "format": "png",
    "accessURL": "https://gdr.openei.org/files/793/3D%20Model%20snapshots1.png",
    "mediaType": "image/png",
    "description": "A snapshot of the INL site 3D model from JewelSuite showing progressively younger stratigraphic surfaces of the two structural grids derived from the no outflow scenario. "
  },
  {
    "@type": "dcat:Distribution",
    "title": "3D Petrel no outflow model.zip",
    "format": "zip",
    "accessURL": "https://gdr.openei.org/files/793/3D%20Petrel%20no%20outflow%20model.zip",
    "mediaType": "application/zip",
    "description": "3D model of the INL site.  Original Petrel model, no outflow."
  },
  {
    "@type": "dcat:Distribution",
    "title": "3D Petrel outflow model.zip",
    "format": "zip",
    "accessURL": "https://gdr.openei.org/files/793/3D%20Petrel%20outflow%20model.zip",
    "mediaType": "application/zip",
    "description": "3D Model of the INL site.  Original Petrel outflow model."
  },
  {
    "@type": "dcat:Distribution",
    "title": "3D model snapshot outflow.png",
    "format": "png",
    "accessURL": "https://gdr.openei.org/files/793/3D%20model%20snapshots2.png",
    "mediaType": "image/png",
    "description": "JewelSuite showing progressively younger stratigraphic surfaces of the two structural grids derived from the outflow scenario. "
  },
  {
    "@type": "dcat:Distribution",
    "title": "3D-JewelSuite-Model1.wrl.zip",
    "format": "zip",
    "accessURL": "https://gdr.openei.org/files/793/3D-JewelSuite-Model1.wrl.zip",
    "mediaType": "application/zip",
    "description": "3d Model of the INL site.  Model 1 shows a system of nested calderas directly beneath the GRRA and is based largely on correlations of rhyolitic deposits in the mountains north of the ESRP and worldwide relationships between caldera subsidence, diameter, and eruptive volumes. In this model, the boundary between the volcanics and the Paleozoic rocks is steep (~40 to 80 degrees) and the thickness of the volcanic units increases rapidly with distance from the range front."
  },
  {
    "@type": "dcat:Distribution",
    "title": "3D-JewelSuite-Model2.wrl.zip",
    "format": "zip",
    "accessURL": "https://gdr.openei.org/files/793/3D-JewelSuite-Model2.wrl.zip",
    "mediaType": "application/zip",
    "description": "3D model of the INL site. Model 2 shows the same system of calderas shifted to the south, beyond the boundaries of the GRRA. Here we assume that the boundary between volcanics and Paleozoic rocks is defined by a flexural surface that was formed in response to the emplacement of a dense mid-crustal sill beneath the ESRP. This model is supported by the attitudes of ancient fold hinges within the mountains north of the plain. Fold hinges near the boundary of the plain plunge towards the plain at around 30 degrees. North of the plain, the plunge angles decrease in a more or less uniform manner. Thus, in this model, the base of the volcanic system is defined by a planar feature dipping 30 degrees to the south."
  },
  {
    "@type": "dcat:Distribution",
    "title": "Isostatic Residual Gravity ESRP.png",
    "format": "png",
    "accessURL": "https://gdr.openei.org/files/793/ESRP_ResidGrav.png",
    "mediaType": "image/png",
    "description": "Raster map showing the isostaic residual gravity of the eastern Snake River Plain from the Idaho Department of Water Resources."
  },
  {
    "@type": "dcat:Distribution",
    "title": "Magnetics ESRP.png",
    "format": "png",
    "accessURL": "https://gdr.openei.org/files/793/ESRP_magnetics.png",
    "mediaType": "image/png",
    "description": "Raster map of NRM Aero magnetics of the Easter Snake River Plain"
  },
  {
    "@type": "dcat:Distribution",
    "title": "Rodgers et al 2002 paper on extension in Eastern Snake River Plain.pdf",
    "format": "pdf",
    "accessURL": "https://gdr.openei.org/files/793/Extension_and_Subsidence_of_the_Eastern_Snake_Rive.pdf",
    "mediaType": "application/pdf",
    "description": "Rodgers et al, 2002. "Extension and Subsidence of the Eastern Snake River Plain, Idaho." The deformational history of the eastern Snake River Plain (SRP) is interpreted from rocks, structures, and landforms within and adjacent to it. Crustal extension is manifested by west-dipping normal faults that define a halfgraben fault style along the north and south margins of the plain. "
  },
  {
    "@type": "dcat:Distribution",
    "title": "Wannamaker et al 2016 paper on re-inversion of MT data over SRP FORGE.doc",
    "format": "doc",
    "accessURL": "https://gdr.openei.org/files/793/Forge-SRP_UUtah-MTreinvt.doc",
    "mediaType": "application/msword",
    "description": "Phillip Wannamaker and Virginie Maris, 2016. "Re-Inversion of Long-Period MT Data over the Eastern Snake River Plain, Idaho, In Support of Phase I of the Idaho National Laboratory FORGE Project." Paper outlines a powerful new MT inversion technique based on deformable edge finite elements and all direct solvers, applied to the ESRP in support of the Snake River FORGE project.
"
  },
  {
    "@type": "dcat:Distribution",
    "title": "INL Seismic Monitoring stations.pdf",
    "format": "pdf",
    "accessURL": "https://gdr.openei.org/files/793/INL%20Seismic%20Monitoring%20stations.pdf",
    "mediaType": "application/pdf",
    "description": "Map shows the locations of INL seismic stations and stations monitored by INL that are operated by other institutions in the eastern Snake River Plain."
  },
  {
    "@type": "dcat:Distribution",
    "title": "INL Seismic events 1972 - 2012.pdf",
    "format": "pdf",
    "accessURL": "https://gdr.openei.org/files/793/INL%20Seismic%20events%201972%20-%202012.pdf",
    "mediaType": "application/pdf",
    "description": "Map of seismic events on the eastern Snake River Plain between Jan. 1st, 1972 and Dec. 31st, 2012."
  },
  {
    "@type": "dcat:Distribution",
    "title": "INL Seismic events 2011.pdf",
    "format": "pdf",
    "accessURL": "https://gdr.openei.org/files/793/INL%20Seismic%20events%202011.pdf",
    "mediaType": "application/pdf",
    "description": "Map of seismic events on the eastern Snake River Plain between Jan. 1st and Dec. 31st, 2011."
  },
  {
    "@type": "dcat:Distribution",
    "title": "INL Seismic events 2012.pdf",
    "format": "pdf",
    "accessURL": "https://gdr.openei.org/files/793/INL%20Seismic%20events%202012.pdf",
    "mediaType": "application/pdf",
    "description": "Map of seismic events on the eastern Snake River Plain between Jan. 1st and Dec. 31st, 2012."
  },
  {
    "@type": "dcat:Distribution",
    "title": "Mabey 1978 paper on gravity and magnetic anomalies in the ESRP.pdf",
    "format": "pdf",
    "accessURL": "https://gdr.openei.org/files/793/Mabey%201978%20Regional%20gravity%20and%20magnetic%20anomalies%20in%20the%20eastern%20Snake%20River%20Plain%20Idaho.pdf",
    "mediaType": "application/pdf",
    "description": "Mabey, 1978. "Regional gravity and magnetic anomalies in the eastern Snake River Plain, Idaho."  from the Journal of Research of the U.S. Geological Survey (USGS).  "
  },
  {
    "@type": "dcat:Distribution",
    "title": "McLing et al 2002 Chemical characteristics of thermal water beneath ESRP.pdf",
    "format": "pdf",
    "accessURL": "https://gdr.openei.org/files/793/McLing%20et%20al%202002%20Chemical%20characteristics%20of%20thermal%20water%20beneath%20the%20eastern%20Snake%20River%20Plain.pdf",
    "mediaType": "application/pdf",
    "description": "McLing et al, 2002.  "Chemical characteristics of thermal water beneath the eastern Snake River Plain." The eastern Snake River Plain aquifer is among the largest and most productive aquifers in the United States.
doi: 10.1130/0-8137-2353-1.205"
  },
  {
    "@type": "dcat:Distribution",
    "title": "McQuarrie et al 1998 paper on Snake River Plain volcanic basin.pdf",
    "format": "pdf",
    "accessURL": "https://gdr.openei.org/files/793/McQuarrie_Rodgers_Tect1998.pdf",
    "mediaType": "application/pdf",
    "description": "Nadine McQuarrie and David Rogers, 1998. "Subsidence of a volcanic basin by flexure and crustal flow: The eastern Snake River Plain, Idaho." "
  },
  {
    "@type": "dcat:Distribution",
    "title": "In-Situ Stress and Natural Fracturing.pdf",
    "format": "pdf",
    "accessURL": "https://gdr.openei.org/files/793/Moos%20and%20Barton%201990%20In-situ%20Stress%20and%20Natural%20Fracturing%20at%20the%20INEL%20Site%20Idaho_EGG-NPR-10631.pdf",
    "mediaType": "application/pdf",
    "description": "Paper characterizing stress and natural fracturing on the INEL site.  Moos and Barton, 1990. "In-situ Stress and Natural Fracturing at the INEL Site", Idaho_EGG-NPR-10631"
  },
  {
    "@type": "dcat:Distribution",
    "title": "Podgorney et al 2013 GRC paper on EGS potential of the ESRP.pdf",
    "format": "pdf",
    "accessURL": "https://gdr.openei.org/files/793/Podgorney%20et%20al%202013%20EGS%20Potential%20for%20Sites%20on%20the%20ESRP%20Idaho.pdf",
    "mediaType": "application/pdf",
    "description": "Podgorney et al, 2013. "Enhanced Geothermal system Potential for sites on the Eastern snake river Plain, Idaho." from the 37th Geothermal Resource Council Annual Meeting.  The Snake River volcanic province overlies a thermal anomaly that extends deep into the mantle and represents one of the highest heat flow provinces in North America..."
  },
  {
    "@type": "dcat:Distribution",
    "title": "Resistivity data SRP Zohdy and Stanley 1973.pdf",
    "format": "pdf",
    "accessURL": "https://gdr.openei.org/files/793/Resistivity%20data%20SRP%20Zohdy%20and%20Stanley%201973.pdf",
    "mediaType": "application/pdf",
    "description": "Geoelectric section across the Snake River Plain from Blackfoot to Arco, Idaho, from Zohdy and Stanley 1973."
  },
  {
    "@type": "dcat:Distribution",
    "title": "Resistivity map SRP Zohdy and Stanley 1973.pdf",
    "format": "pdf",
    "accessURL": "https://gdr.openei.org/files/793/Resistivity%20map%20SRP%20Zohdy%20and%20Stanley%201973.pdf",
    "mediaType": "application/pdf",
    "description": "Map of data points from Zohdy and Stanley 1973 resisitivty survey of the Snake River Plain from Blackfoot to Arco, Idaho."
  },
  {
    "@type": "dcat:Distribution",
    "title": "Resistivity section SRP Zohdy and Stanley 1973.pdf",
    "format": "pdf",
    "accessURL": "https://gdr.openei.org/files/793/Resistivity%20section%20SRP%20Zohdy%20and%20Stanley%201973.pdf",
    "mediaType": "application/pdf",
    "description": "Zohdy and Stanley, 1973. "Preliminary Interpretation of Electrical Sounding Curves Obtained Across the Snake River Plain from Blackfoot to Arco, Idaho."  Original report, contains raw sounding curves."
  },
  {
    "@type": "dcat:Distribution",
    "title": "Snake River Plain well heads.xlsx",
    "format": "xlsx",
    "accessURL": "https://gdr.openei.org/files/793/well%20heads.xlsx",
    "mediaType": "application/vnd.openxmlformats-officedocument.spreadsheetml.sheet",
    "description": "A list of well heads in the proposed FORGE site area of the Eastern Snake River Plain.  The spreadsheet contains names, coordinates, target depth, and elevation for each of the well heads."
  },
  {
    "@type": "dcat:Distribution",
    "title": "Well Data for USGS-142",
    "format": "HTML",
    "accessURL": "https://gdr.openei.org/submissions/790",
    "mediaType": "text/html",
    "description": "Collection of data on the USGS-142 well amassed by the SRGC for Snake River Plain FORGE."
  },
  {
    "@type": "dcat:Distribution",
    "title": "Well Data for WO-2",
    "format": "HTML",
    "accessURL": "https://gdr.openei.org/submissions/791",
    "mediaType": "text/html",
    "description": "Collection of data on the WO-2 well amassed by the SRGC for Snake River Plain FORGE."
  },
  {
    "@type": "dcat:Distribution",
    "title": "Well Data for INEL-1",
    "format": "HTML",
    "accessURL": "https://gdr.openei.org/submissions/792",
    "mediaType": "text/html",
    "description": "Collection of data on the INEL-1 well amassed by the SRGC for Snake River Plain FORGE."
  },
  {
    "@type": "dcat:Distribution",
    "title": "INL Seismic Monitoring 2010 Annual Report",
    "format": "pdf#search=INL%20Seismic%20Monitoring%202010%20Annual%20Report",
    "accessURL": "https://inldigitallibrary.inl.gov/sites/STI/STI/5094594.pdf#search=INL%20Seismic%20Monitoring%202010%20Annual%20Report",
    "mediaType": "application/octet-stream",
    "description": "2010 annual report detailing seismic events in the Snake River Plain and within a 100 mile radius of the Idaho National Lab (Intended to supplement the broken link associated with "INL Seismic Monitoring 2010 Annual Report - UNAVAILABLE")"
  },
  {
    "@type": "dcat:Distribution",
    "title": "INL Seismic Monitoring 2011 Annual Report",
    "format": "pdf#search=INL%20Seismic%20Monitoring%202010%20Annual%20Report",
    "accessURL": "https://inldigitallibrary.inl.gov/sites/STI/STI/5626366.pdf#search=INL%20Seismic%20Monitoring%202010%20Annual%20Report",
    "mediaType": "application/octet-stream",
    "description": "2011 annual report detailing seismic events in the Snake River Plain and within a 100 mile radius of the Idaho National Lab (Intended to substitute the broken link in "INL Seismic Monitoring 2011 Annual Report - UNAVAILABLE")"
  },
  {
    "@type": "dcat:Distribution",
    "title": "INL Seismic Monitoring 2012 Annual Report",
    "format": "pdf#search=INL%20Seismic%20Monitoring%202010%20Annual%20Report",
    "accessURL": "https://inldigitallibrary.inl.gov/sites/STI/STI/6360445.pdf#search=INL%20Seismic%20Monitoring%202010%20Annual%20Report",
    "mediaType": "application/octet-stream",
    "description": "2012 annual report detailing seismic events in the Snake River Plain and within a 100 mile radius of the Idaho National Lab (Intended to substitute the broken link in "INL Seismic Monitoring 2012 Annual Report - UNAVAILABLE")"
  },
  {
    "@type": "dcat:Distribution",
    "title": "Morse 2002 Thesis INL Site Characteristics Paper",
    "format": "HTML",
    "accessURL": "https://isu.app.box.com/v/Morse-2002",
    "mediaType": "text/html",
    "description": "Paper detailing SRP characteristics including detailed information on several wells in the INL area, including INEL-1, WO-2, and USGS-142. "Basalt alteration and authigenic mineralization near the effective base of the SRP aquifer at the INEEL, Idaho." by Lee H. Morse."
  },
  {
    "@type": "dcat:Distribution",
    "title": "Snake River Plain Geothermal Region",
    "format": "HTML",
    "accessURL": "https://openei.org/wiki/Snake_River_Plain_Geothermal_Region",
    "mediaType": "text/html",
    "description": "OpenEI webpage with background information about the Snake River Plain Geothermal Region "
  },
  {
    "@type": "dcat:Distribution",
    "title": "Bakshi et al 2016 SGW paper on geomechanical characterization of SRP FORGE core",
    "format": "HTML",
    "accessURL": "https://pangea.stanford.edu/ERE/db/IGAstandard/record_detail.php?id=26380",
    "mediaType": "text/html",
    "description": "Bakshi et al, 2016. "Geomechanical Characterization of Core from the Proposed FORGE Laboratory on the
Eastern Snake River Plain, Idaho." from the 41st Stanford Geothermal Workshop.  This paper presents the  results of a geomechanical characterization of cores from a well in the Eastern Snake River Plain, Idaho, near the proposed site for a FORGE EGS Laboratory."
  },
  {
    "@type": "dcat:Distribution",
    "title": "Grana et al 2016 SGW Paper on Rock Physics Modeling Snake River Plain FORGE",
    "format": "HTML",
    "accessURL": "https://pangea.stanford.edu/ERE/db/IGAstandard/record_detail.php?id=26424",
    "mediaType": "text/html",
    "description": "Grana et al, 2016. "Rock Physics Modeling for the Potential FORGE Site on the Eastern Snake River Plain, Idaho" by Dario Grana, Sumit Verma, and Robert Podgorney, at the 2016 Stanford Geothermal Workshop."
  },
  {
    "@type": "dcat:Distribution",
    "title": "McCurry et al SGW 2016 paper on geologic setting of INL Geothermal Research Area",
    "format": "pdf",
    "accessURL": "https://pangea.stanford.edu/ERE/pdf/IGAstandard/SGW/2016/Mccurry.pdf",
    "mediaType": "application/pdf",
    "description": "McCurry et al, 2016. "Geologic Setting of the Idaho National Laboratory Geothermal Resource Research Area."  From the 2016 Stanford Geothermal Workshop.  The Idaho National Laboratory (INL) has designated ~100 km2 of the Eastern Snake River Plain (ESRP), along the track of the Yellowstone Hot Spot, as a Geothermal Resource Research Area (GRRA)."
  },
  {
    "@type": "dcat:Distribution",
    "title": "Plummer et al 2016 SGW Paper Modeling Heat Flow in ESRP Aquifer",
    "format": "pdf",
    "accessURL": "https://pangea.stanford.edu/ERE/pdf/IGAstandard/SGW/2016/Plummer3.pdf",
    "mediaType": "application/pdf",
    "description": "Plummer et al, 2016. "Modeling Heat Flow in the Eastern Snake River Plain Aquifer." from the 41st Stanford Geothermal Workshop.  The Eastern Snake River Plain (ESRP) in southern Idaho is a region with significant potential as a geothermal energy resource."
  },
  {
    "@type": "dcat:Distribution",
    "title": "Welhan et al 2016 SGW Paper on the Thermal and Geochemical Anomalies in the ESRP",
    "format": "pdf",
    "accessURL": "https://pangea.stanford.edu/ERE/pdf/IGAstandard/SGW/2016/Welhan1.pdf",
    "mediaType": "application/pdf",
    "description": "Welhan et al, 2016. "Thermal and Geochemical Anomalies in the Eastern Snake River Plain Aquifer: Contributions to a Conceptual Model of the Proposed FORGE Test Site." from the 41st Stanford Geothemal Workshop.  Data from the U.S. Geological Survey’s National Water Information System (NWIS) database reveal the existence of a number of thermally anomalous areas on the eastern Snake River Plain (ESRP) aquifer, most of them near its margins, and NWIS temperature and chemistry data provided conclusive evidence that thermal waters originating in the hot rhyolitic rocks underlying the ESRP basalts inject heat and solute mass into the overlying ESRP aquifer. "
  },
  {
    "@type": "dcat:Distribution",
    "title": "Furlong 1979 analytical stress model paper",
    "format": "HTML",
    "accessURL": "https://www.sciencedirect.com/science/article/abs/pii/0040195179903081",
    "mediaType": "text/html",
    "description": ""An analytic stress model applied to the Snake River Plain (Northern Basin and Range province U.S.A.)" Kevin P. Furlong, 1979."
  },
  {
    "@type": "dcat:Distribution",
    "title": "DeNosaquo et al 2009 paper on Snake River Plain density models",
    "format": "HTML",
    "accessURL": "https://www.sciencedirect.com/science/article/abs/pii/S0377027309003242?fr=RR-2&ref=pdf_download&rr=895d6f018bd5cfe5",
    "mediaType": "text/html",
    "description": "DeNosaquo et al, 2009. "Density and lithospheric strength models of the Yellowstone–Snake River Plain
volcanic system from gravity and heat flow data." The structure and composition of the Yellowstone–Snake River Plain (YSRP) volcanic system were analyzed
using gravity data taken at over 30,000 stations in the YSRP and surrounding region."
  },
  {
    "@type": "dcat:Distribution",
    "title": "Leeman et al 2009 paper on thermal structure beneath Snake River Plain",
    "format": "HTML",
    "accessURL": "https://www.sciencedirect.com/science/article/pii/S0377027309000730",
    "mediaType": "text/html",
    "description": "William Leeman, Derek Schutt, and Scott Hughes, 2009. "Thermal structure beneath the Snake River Plain: Implications for the Yellowstone hotspot.""
  },
  {
    "@type": "dcat:Distribution",
    "title": "McLing et al 2016 Paper on Wellbore and Groundwater Temperature Distribution in ESRP",
    "format": "HTML",
    "accessURL": "https://www.sciencedirect.com/science/article/pii/S0377027316300385",
    "mediaType": "text/html",
    "description": "McLing et al, 2016. "Wellbore and Groundwater Temperature Distribution Eastern Snake River Plain, Idaho: Implications for Groundwater Flow and Geothermal Potential." A map of groundwater temperatures from the Eastern Snake River Plain (ESRP) regional aquifer can be used to identify and interpret important features of the aquifer, including aquifer flow direction, aquifer thickness, and potential geothermal anomalies. The ESRP is an area of high heat flow, yet most of this thermal energy fails to reach the surface, due to the heat being swept downgradient by the aquifer to the major spring complexes near Thousand Springs, ID, a distance of 300 km. "
  },
  {
    "@type": "dcat:Distribution",
    "title": "Podgorney et al 2016 SGW Overview of Snake River Plain FORGE Site",
    "format": "HTML",
    "accessURL": "https://www.semanticscholar.org/paper/A-Snake-River-Plain-Field-Laboratory-for-Enhanced-Podgorney-Snyder/823d03f7b33ba6c101dc38a925258376039adfcf",
    "mediaType": "text/html",
    "description": "Podgorney et al, 2016. "A Snake River Plain Field Laboratory for Enhanced Geothermal Systems: An Overview of the Snake River Geothermal Consortium’s Proposed FORGE Site." from the 41st Stanford Geothermal Workshop."
  }
]
                                        

                                            [
  "3D",
  "3D model",
  "Annual report",
  "EGS",
  "ERSP",
  "ESRP",
  "Eastern",
  "Eastern Snake River Plain",
  "FORGE",
  "GRRA",
  "Geothermal Systems",
  "He",
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                                            [
  "019:006"
]
                                        

                                            {
  "name": "Idaho National Laboratory",
  "@type": "org:Organization"
}
                                        

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