Abstract
This chapter considers a series of research, technology, policy, and human resource-relevant recommendations aimed at identifying ultra-deep wellsite locations that may be problematic for risk of an oil spill, as well as enhancing prevention, preparedness, response, and subsequent injury assessment associated with ultra-deep oil spills. While various groups have offered research and process improvement recommendations, numbering in the high hundreds, this chapter focuses on 20 key research gaps and 4 policy changes that would improve outcomes for ultra-deep oil spill prevention and response. Recommended policy changes include (1) inclusion of site-specific risk assessments as an element of lease sale identification and approval, (2) collection of environmental baselines (both broadscale and installation-specific) and ongoing monitoring of oil contaminants, (3) improved transparency and data sharing for oil facility management and accidental releases, and (4) more formal international engagement in siting, oil spill preparedness, response, and impact assessment.
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References
Alaska Fisheries Science Center and Alaska Regional Office (2018) North Pacific Observer Program 2017 Annual Report. AFSC Processed Rep. 2018–02, 136 pp. Alaska Fisheries Science Center, NOAA, National Marine Fisheries Service, 7600 Sand Point Way NE, Seattle WA 98115. Available at http://www.afsc.noaa.gov/Publications/ProcRpt/PR2018-02.pdf
Australian Maritime Safety Authority (AMSA) (2010) Response to the Montara wellhead platform incident. Report of the incident analysis team. March 2010. Available online from: https://www.amsa.gov.au/marine-environment/incidents-and-exercises/response-montara-wellhead-platform-incident
Berenshtein I, Perlin N, Ainsworth C, Ortega-Ortiz J, Vaz AC, Paris CB (2020) Comparison of the spatial extent, impacts to shorelines and ecosystem, and 4-dimensional characteristics of simulated oil Spills (Chap. 20). In: Murawski SA, Ainsworth C, Gilbert S, Hollander D, Paris CB, Schlüter M, Wetzel D (eds) Scenarios and responses to future Deep Oil Spills – fighting the next war. Springer, Cham
Boebert E, Blossom JM (2016) Deepwater Horizon: a systems analysis of the Macondo disaster. Harvard University Press. 290 pp
Chancellor E, Murawski SA, Paris CB, Perruso L, Perlin N (2020) Comparative environmental sensitivity of offshore Gulf of Mexico waters potentially impacted by ultra-deep oil well blowouts (Chap. 26). In: Murawski SA, Ainsworth C, Gilbert S, Hollander D, Paris CB, Schlüter M, Wetzel D (eds) Scenarios and responses to future Deep Oil Spills – fighting the next war. Springer, Cham
Demopoulos AWJ, Bourque JR, Cordes E, Stamler KM (2015) Impacts of the Deepwater Horizon oil spill on deep-sea coral-associated sediment communities. Mar Ecol Prog Ser 561:51–68. https://doi.org/10.3354/meps11905
Fisher CR, Montagna PA, Sutton TT (2016) How did the Deepwater Horizon oil spill impact deep-sea ecosystems? Oceanography 29:182–195. https://doi.org/10.5670/oceanog.2016.82
French-McCay D, Crowley D, Rowe JJ, Bock M, Robinson H, Wenning R, Hayward Walker A, Joeckel J, Nedwed TJ, Parkerton TF (2018) Comparative risk assessment of spill response options for a deepwater oil well blowout: part 1. Oil spill modeling. Mar Pollut Bull 133:1001–1015
Iledare OO, Pulsipher AG, Dismukes DE, Mesyanzhinovet D (1997) Oil spills, workplace safety and firm size: evidence from the U.S. Gulf of Mexico OCS. Energy J 18:73–89
Interagency Coordinating Committee on Oil Pollution Research (ICCOPR) (2015) Oil pollution research and technology plan: Fiscal years 2015–2021. 270 pp. https://www.bsee.gov/sites/bsee_prod.opengov.ibmcloud.com/files/bsee-interim-document/statistics/2015-iccopr-research-and-technology-plan.pdf
Jablonowski CJ (2007) Employing detection controlled models in health and environmental risk assessment: a case in offshore oil drilling. Hum Ecol Risk Assess 13:986–1013
Ji Z-G, Johnson WR, DuFore CM (2017) Oil-spill risk analysis Gulf of Mexico Outer Continental Shelf (OCS) lease sales, Eastern Planning Area, Central Planning Area, and Western Planning Area, 2017–2022, and Gulf-wide OCS program, 2017–2086. OCS Report BOEM 2017–010. 57 pp.
Johansen Ø, Rye H (2003) DeepSpill––Field study of a simulated oil and gas blowout in deep water. Spill Sci Technol Bull 8:433–443
Joint Analysis Group, Deepwater Horizon Oil Spill (JAG) (2011) Review of R/V Brooks McCall data to examine subsurface oil. NOAA Technical Report NOS OR&R 24, Silver Spring, MD 69 pp.
Lubchenco J, McNutt MK, Dreyfus G, Murawski SA, Kennedy DM, Anastas PT, Chu S, Hunter T (2012) Science in support of the Deepwater Horizon response. Proc Natl Acad Sci U S A 109:20212–20221
Malone K, Pesch S, Schlüter M, Krause D (2018) Oil droplet size distributions in deep-sea blowouts: influence of pressure and dissolved gases. Environ Sci Technol 52:6326–6333. https://doi.org/10.1021/acs.est.8b00587
Malone K, Aman ZM, Pesch S, Schlüter M, Krause D (2020) Jet formation at the spill site and resulting droplet size distributions (Chap. 4). In: Murawski SA, Ainsworth C, Gilbert S, Hollander D, Paris CB, Schlüter M, Wetzel D (eds) Deep Oil Spills: facts, fate and effects. Springer International, Cham
Mark-Moser M, Disenhof C, Rose K (2015) Gulf of Mexico geology and petroleum system: overview and literature review in support of risk and resource assessments. NETL-TRS-4-2015; EPAct Technical Report Series; U.S. Department of Energy, National Energy Technology Laboratory: Morgantown, WV; p 28
McEachran JD (2009) Fishes (Vertebrata: Pisces) of the Gulf of Mexico. In: Felder DL, Camp DK (eds) Gulf of Mexico–origins, waters, and biota, vol 1.: Biodiversity. Texas A&M University Press, College Station, pp 1223–1316
McGowan CJ, Kwok RK, Engel LS, Stenzel MR, Stewart PA, Sandler DP (2017) Respiratory, dermal, and eye irritation symptoms associated with Corexit™ EC9527A/EC9500A following the Deepwater Horizon oil spill: findings from the GuLF STUDY. Environ Health Perspect 097015:1–7. https://ehp.niehs.nih.gov/doi/pdf/10.1289/EHP1677
McNutt MK, Chu S, Lubchenco J, Hunter T, Dreyfus G, Murawski SA, Kennedy DM (2012) Applications of science and engineering to quantify and control the Deepwater Horizon oil spill. Proc Natl Acad Sci U S A 109:20222–20228. https://doi.org/10.1073/pnas.1214389109
Muehlenbachs L, Cohen MA, Gerarden T (2013) The impact of water depth on safety and environmental performance in offshore oil and gas production. Energy Policy 55:699–705. https://doi.org/10.1016/j.enpol.2012.12.074
Murawski SA, Hollander DJ, Gilbert S, Gracia A (2020) Deep-water oil and gas production in the Gulf of Mexico, and related global trends (Chap. 2). In: Murawski SA, Ainsworth C, Gilbert S, Hollander D, Paris CB, Schlüter M, Wetzel D (eds) Scenarios and responses to future Deep Oil Spills – fighting the next war. Springer, Cham
National Academies of Sciences, Engineering and Medicine (NASEM) (2019) Report of the committee on evaluation of the use of chemical dispersants in Oil Spill response. National Academies Press, Washington DC. xxx pp
National Academy of Engineering and National Research Council (NAE-NRC) (2012) Macondo Well Deepwater Horizon Blowout: lessons for improving offshore drilling safety. The National Academies Press, Washington, DC. https://doi.org/10.17226/13273
National Commission on the BP Deepwater Horizon Oil Spill and Offshore Drilling (2011) Deep water: the Gulf oil disaster and the future of offshore drilling. Report to the President. 398 pp. https://www.gpo.gov/fdsys/pkg/GPO-OILCOMMISSION/pdf/GPO-OILCOMMISSION.pdf
National Incident Command (NIC) (2010) National incident commander’s report: MC252 Deepwater Horizon. National incident command, Deepwater Horizon response. https://www.hsdl.org/?abstract&did=767583
National Research Council (NRC) (2003) Oil in the sea III: fates and effects. The National Academies Press, Washington, DC
National Research Council (NRC) (2005) Oil spill dispersants: efficacy and effects. The National Academies Press, Washington, DC, p 377
Paris CB, Trillo ML, Olascoaga MJ, Aman ZM, Schlüter M, Joye SB, Berenshtein I (2018) BP Gulf science data reveals ineffectual sub-sea dispersant injection for the Macondo blowout. Front Mar Sci (in press)
Pesch S, Jaeger P, Jaggi A, Malone K, Hoffmann M, Krause D, Oldenburg T, Schlüter M (2018) Rise velocity of live-oil droplets in deep-sea oil spills. Environ Eng Sci. 35(4):289–299 https://doi.org/10.1089/ees.2017.0319
Pesch S, Schlüter M, Aman Z, Malone K, Krause D, Paris CB (2020) Behavior of rising droplets and bubbles – impact on the physics of deep-sea blowouts and oil fate (Chap. 5). In: Murawski SA, Ainsworth C, Gilbert S, Hollander D, Paris CB, Schlüter M, Wetzel D (eds) Deep Oil Spills: facts, fate and effects. Springer International, Cham
Peterson CH, Rice SD, Short JW, Esler D, Bodkin JL, Ballachey BE, Irons DB (2003) Long-term ecosystem response to the Exxon Valdez oil spill. Science 302:2082–2086
U.S. Bureau of Ocean Energy Management (BOEM) (2018) 2019–2024 National outer continental shelf oil and gas leasing draft proposed program. Available at: https://www.boem.gov/NP-Draft-Proposed-Program-2019-2024 380 pp
Sauer TC, Costa HJ, Brown JS, Ward TJ (1997) Toxicity identification evaluations of produced water effluents. Environ Toxicol Chem 16:2020–2028
Shultz J (1999) The risk of accidents and spills at offshore production platforms: a statistical analysis of risk factors and the development of predictive models. Doctoral Dissertation. Department of Engineering and Public Policy, Carnegie Mellon University, Pittsburgh
Soto LA, Botello AV, Licea-Durán S, Lizárraga-Partida M, Yáñez-Arancibia Y (2014) The environmental legacy of the Ixtoc 1 oil spill in Campeche sound, southwestern Gulf of Mexico. Front Mar Sci 1:1–9
Sutton TT, Frank T, Judkins H, Romero IC (2020) As Gulf oil extraction goes deeper, who is at risk? Community structure, distribution, and connectivity of the deep-pelagic fauna (Chap. 24). In: Murawski SA, Ainsworth C, Gilbert S, Hollander D, Paris CB, Schlüter M, Wetzel D (eds) Scenarios and responses to future Deep Oil Spills – fighting the next war. Springer, Cham
U.S. Bureau of Ocean Energy Management (BOEM) (2017a) Gulf of Mexico OCS Lease Sale. Final Supplemental Environmental Impact Statement 2018. Volume I: Chapters 1–8 and keyword Index. https://www.boem.gov/BOEM-EIS-2017-074-v1/ 412 pp. 4–123 etc.
U.S. Bureau of Ocean Energy Management (BOEM) (2017b) Assessment of technically and economically recoverable hydrocarbon resources of the Gulf of Mexico Outer Continental Shelf as of January 1, 2014. OCS Report BOEM 2017–005. 44 pp. https://www.boem.gov/BOEM-2017-005/
U.S. Environmental Protection Agency (EPA) (2017) Final National Pollutant Discharge Elimination System (NPDES) General Permit No. GEG460000 for Offshore Oil and Gas Activities in the Eastern Gulf of Mexico. Region 4 Permit
Varanasi U (2013) Making science useful in complex political and legal arenas: a case for frontloading science in anticipation of environmental changes to support natural resource laws and policies. Wash J Environ Law Policy 2013:238–265
Zhao L, Chen Z, Lee K (2008) A risk assessment model for produced water discharge from offshore petroleum platforms – development and validation. Mar Pollut Bull 56:1890–1897
Acknowledgments
The priority recommendations contained herein were culled from the literally hundreds similar recommendations offered by the Federal agencies, industry groups, NGOs, and academic researchers and in various after-action reports stemming from oil spills. In particular, these perspectives benefitted from discussions with oil spill experts including David Westerholm and Lisa DiPinto at NOAA and Robyn Conmy at EPA. Likewise, discussions with many colleagues in the industry were helpful in winnowing the list to include the most feasible options. Last, my colleagues at C-IMAGE were instrumental in articulating many of the research priorities. That being said, the responsibility for including specific recommendations as part of this chapter lies only with me.
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Murawski, S.A. (2020). Perspectives on Research, Technology, Policy, and Human Resources for Improved Management of Ultra-Deep Oil and Gas Resources and Responses to Oil Spills. In: Murawski, S., et al. Scenarios and Responses to Future Deep Oil Spills. Springer, Cham. https://doi.org/10.1007/978-3-030-12963-7_29
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