Abstract
Hundreds of oil wells were drilled along Oil Creek in Pennsylvania in the mid-1800s, birthing the modern oil industry. No longer in operation, many wells are now classified as abandoned, and, due to their age, their locations are either unknown or inaccurately recorded. These historic-well sites present environmental, safety, and economic concerns in the form of possible methane leaks and physical hazards. Airborne magnetic and LiDAR surveys were conducted in the Pioneer Run watershed in Oil Creek State Park to find abandoned wells in a historically significant but physically challenging location. Wells were drilled in this area prior to modern geolocation and legal documentation. Although a large number of old wells were abandoned summarily without remediation of the site, much of the land area within Oil Creek State Park is now covered in trees and dense underbrush, which can obscure wellheads. The thick vegetation and steep terrain limited the possibility of ground-based surveys to easily find well sites for methane emissions studies. The data from remote sensing surveys were used to corroborate potential well locations from historic maps and photographs. Potential well sites were verified in a ground-based field survey and monitored for methane emissions. Two historic photographs documenting oil activity in the late 1800s were georeferenced using a combination of magnetic and LiDAR data. LiDAR data, which were more useful in georeferencing and in field verification, identified 290 field locations in the Pioneer Run watershed, 86% of which were possible well sites. Sixty-two percent of the ground-verified wells remained unplugged and comprised the majority of leaking wells. The mean methane emissions factor for unplugged wells was 0.027 ± 0.099 kg/day, lower than other Appalachian Basin methane emissions estimates. LiDAR was used for the first time, in combination with an airborne magnetic survey, to reveal underground oil industry features and inform well identification and remediation efforts in difficult-to-navigate regions. In the oldest oil fields, where well casing has been removed or wood conductor casing was installed, historic photographs provide additional lines of evidence for oil wells where ground disturbances have concealed surface features. Identification of well sites is necessary for mitigation efforts, as unplugged wells emit methane, a potent greenhouse gas.
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References
American Chemical Society National Historic Chemical Landmarks (ACS NHCL) (2009) Development of the Pennsylvania Oil Industry. http://www.acs.org/content/acs/en/education/whatischemistry/landmarks/pennsylvaniaoilindustry.html. Accessed 2019
Barnes JH, WD Sevon (2002) The geological story of Pennsylvania, educational series, 3rd edn, vol 4. Pennsylvania Geological Survey, Harrisburg, PA, USA
Beers F (1865) Outline map of Venango Co., PA from actual surveys, Atlas of the Oil Region of Pennsylvania, D.R. collection. Beers, Ellis, & Soule, New York, NY, USA
Bell HC (1890) History of Venango County, Pennsylvania: its past and present. Brown, Runk & Company, Chicago, IL, USA
Bowman I (1911) Well-drilling methods. Water Supply Paper
Brandt AR et al. (2014) Methane leaks from North American natural gas systems. Science 343(6172):733–735
Brandt AR, Heath GA, Cooley D (2016) Methane leaks from natural gas systems follow extreme distributions. Environ Sci Technol 50(22):12512–12520
Cahill AG et al. (2019) Advancing knowledge of gas migration and fugitive gas from energy wells in northeast British Columbia, Canada. Greenh Gases: Sci Technol 9(2):134–151
Carll JF (1875) Report of progress in the Venango County district. Second Geological Survey of Pennsylvania, vol 1. p 1–49. US Government Printing Office, Harrisburg, PA, USA
Chase AF et al. (2011) Airborne LiDAR, archaeology, and the ancient Maya landscape at Caracol, Belize. J Archaeol Sci 38(2):387–398
Cole S et al. (2012) NASA-NOAA satellite reveals new views of Earth at night. 07/15/2014 [cited 2020 01/06/2020]; Press release No. 12-422]
Conley S et al. (2016) Methane emissions from the 2015 Aliso Canyon blowout in Los Angeles, CA. Science 351(6279):1317–1320
Covatch GL (2019) Personal communication, P.M.B. Saint-Vincent (ed)
Dahdah N, Sorkhabi R, Collister J (2015) Historical oil samples from Pennsylvania: geochemical correlation. Oil-Ind Hist 16:83–110
Dickey PA (1947) Oil geology of the Titusville Quadrangle, Pennsylvania. Department of Internal Affairs, Bureau of Topographic and Geologic Survey, Harrisburg, PA, USA. p 108
Dickey PA, Sherrill RE, Matteson LS (1943) Oil and gas geology of the Oil City quadrangle, Pennsylvania. Commonwealth of Pennsylvania Department of Internal Affairs, Harrisburg, PA, USA. p 234
Dilmore RM et al. (2015) Spatial and temporal characteristics of historical oil and gas wells in Pennsylvania: implications for new shale gas resources. Environ Sci Technol 49(20):12015–12023
Eaton SJM (1866) Petroleum. J.P. Skelly & Co., Philadelphia, PA, USA. p 299
Erno B, Schmitz R (1996) Measurements of soil gas migration around oil and gas wells in the Lloydminster area. J Can Pet Technol 35(7):37–46
Fingas M, Brown CE (2017) A review of oil spill remote sensing. Sensors 18(1):91
Forde ON, Mayer KU, Hunkeler D (2019) Identification, spatial extent and distribution of fugitive gas migration on the well pad scale. Sci Total Environ 652:356–366
Frischknecht FC et al. (1984) Geophysical methods for locating abandoned wells. EPA-600/S4-84-065. U.S. Environmental Protection Agency, Las Vegas, NV, USA
Frischknecht FC et al. (1985) Location of abandoned wells by magnetic surveys; acquisition and interpretation of aeromagnetic data for five test areas. In: U.S. Geological Survey (ed). U.S. Geological Survey, Washington, DC, USA
Giddens PH (1947) Pennsylavnia petroleum 1750–1872: a documentary history. Pennsylvania Historical & Museum Commission, Titusville, PA, USA. p 420
Hammack RW et al. (2016) Evaluation of a rapid airborne method for locating legacy wells in Pennsylvania. NETL, Pittsburgh, PA, USA
Hammond PA et al. (2020) Gas well integrity and methane migration: evaluation of published evidence during shale-gas development in the USA. Hydrogeol J 28:1481–1502
Harris TM, Thwaites RG (1904) The journal of a tour into the territory northwest of the allegheny mountains, made in the spring of the year 1803. The Arthur H. Clark Company, Cleveland, OH, USA
Hazzard JRG (1868) Petroleum Centre, Aug. 1, 1868. In: Morning herald. Bloss Bros. & Cogswell, Titusville, PA, USA
Hu C et al. (2018) Remote sensing estimation of surface oil volume during the 2010 Deepwater Horizon oil blowout in the Gulf of Mexico: scaling up AVIRIS observations with MODIS measurements. J Appl Remote Sens 12(2):026008
Ingraffea AR et al. (2014) Assessment and risk analysis of casing and cement impairment in oil and gas wells in Pennsylvania, 2000–2012. Proc Natl Acad Sci 111(30):10955
Kang M et al. (2014) Direct measurements of methane emissions from abandoned oil and gas wells in Pennsylvania. Proc Natl Acad Sci 111(51):18173–18177
Kang M et al. (2016) Identification and characterization of high methane-emitting abandoned oil and gas wells. Proc Natl Acad Sci 113(48):13636–13641
Keeports D (2016) HI FLOW sampler for natural gas leak rate measurement. Operation and Maintenance Rev. 7. Bacharach, Inc., New Kensington, PA, USA
Lord B (2017) Remote sensing techniques for onshore oil and gas exploration. Lead Edge 36(1):24–32
Montague J, Pinder GF, Watson TL (2018) Predicting gas migration through existing oil and gas wells. Environ Geosci 25:121–132
Mundia-Howe M et al. (2020) Mapping historic 1860’s oil fields using drone-based high-resolution LiDAR along Pioneer run in Oil Creek State Park, Pennsylvania. Manuscript in preparation
Patterson B (2018) Orphan wells: states wrestle with soaring costs for oil & gas industry mess. https://woub.org/2018/09/07/orphan-wells-states-wrestle-with-soaring-costs-for-oil-gas-industry-mess/
Pekney NJ et al. (2018) Measurement of methane emissions from abandoned oil and gas wells in Hillman State Park, Pennsylvania. Carbon Manag 9(2):165–175
Pownall T (1755) A map of the middle British colonies in North America. Evans, L, Philadelphia, PA, USA
Rabatel A et al. (2008) Rock falls in high-alpine rock walls quantified by terrestrial lidar measurements: a case study in the Mont Blanc area. Geophys Res Lett 35(10):L105102
Riddick SN et al. (2019) Measuring methane emissions from abandoned and active oil and gas wells in West Virginia. Sci Total Environ 651:1849–1856
Root RC (1864) Map of the Oil District Venango, Crawford & Warren Counties, Pennsylvania, D.R. Collection. RC Root, Anthony & Co., New York, NY, USA
Saint-Vincent PMB et al. (2019) Rediscovery of abandoned wells in the world’s first oil field. Esri Story Maps
Saint-Vincent PMB et al. (2020a) An analysis of abandoned oil well characteristics affecting methane emissions estimates in the Cherokee platform in Eastern Oklahoma. Geophys Res Lett. 47(23). https://doi.org/10.1029/2020GL089663
Saint-Vincent PMB et al. (2020b) Identifying abandoned well sites using database records and aeromagnetic surveys. Environ Sci Technol 54(13):8300–8309
Sams 3rd JI et al. (2017) Methods and challenges to locating legacy wells in western Pennsylvania: case study at Hillman State Park. Environ Geosci 24(2):95–112
Schneising O et al. (2014) Remote sensing of fugitive methane emissions from oil and gas production in North American tight geologic formations. Earth’s Fut 2(10):548–558
Schout G et al. (2020) Impact of groundwater flow on methane gas migration and retention in unconsolidated aquifers. J Contam Hydrol 230:103619
Sevon WD, Fleeger GM, Shepps VC (1999) Pennsylvania and the Ice Age, educational series, 2nd edn, vol 6. Pennsylvania Geological Survey, Harrisburg, PA, USA
Sherrill RE, Dickey PA, Matteson LS (1941) Types of stratigraphic oil pools in Venango sands of northwestern Pennsylvania. In: Stratigraphic type oil fields. American Association of Petroleum Geologists, Pennsylvania. p 44
Stocker TF et al. (2013) Climate change 2013: the physical science basis. Contribution of working group I to the fifth assessment report of the intergovernmental panel on climate change. Cambridge University Press, New York, NY, USA
Taku Ide S, Friedmann J, Herzog HJ (2006) CO2 leakage through existing wells: current technology and regulations. In: Proceedings of the 8th Greenhouse Gas Technology Conference. Trondjheim, Norway
Townsend-Small A et al. (2016) Emissions of coalbed and natural gas methane from abandoned oil and gas wells in the United States. Geophys Res Lett 43(5):2283–2290
United States Environmental Protection Agency (2006) Data quality assessment: statistical methods for practitioners U.S.E.P. Agency (ed). Office of Environmental Information, Washington, DC, USA
U.S. Environmental Protection Agency (2020) Draft inventory of U.S. greenhouse gas emissions and sinks: 1990–2018. Environmental Protection Agency, Washington, DC, USA
Webster I (2020) Inflation calculator. A. Finance (ed)
Wertman WT (1958) Cable-tool coring with oil-base mud in Appalachian oilfields, D.o.t.I. Bureau of Mines, Morgantown, WV, USA. p 50
Zavala-Araiza D et al. (2015) Reconciling divergent estimates of oil and gas methane emissions. Proc Natl Acad Sci USA 112(51):15597–15602
Acknowledgements
This work was performed in support of the US Department of Energy’s Fossil Energy Crosscutting Technology Research Program. The Research was executed through the NETL Research and Innovation Center’s Natural Gas Infrastructure Program. Research performed by Leidos Research Support Team (LRST) staff was conducted under the RSS contract 89243318CFE000003. Additional funding through the Oak Ridge Institute for Science and Education Fellowship Program supported the research. Andrew Tinker of the NETL contractor USSE2 aided in field work in Pennsylvania. GAV of the NETL aided in magnetic data collection and processing. Susan Bates of the Drake Well Museum provided access to historical documents. The Pennsylvania Department for the Conservation of Natural Resources provided access to Oil Creek State Park for field work.
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Saint-Vincent, P.M.B., Sams, J.I., Mundia-Howe, M. et al. Historic and Modern Approaches for the Discovery of Abandoned Wells for Methane Emissions Mitigation in Oil Creek State Park, Pennsylvania. Environmental Management 67, 852–867 (2021). https://doi.org/10.1007/s00267-020-01420-3
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DOI: https://doi.org/10.1007/s00267-020-01420-3