Oil Pollution from Operations and Shipwrecks

Roger C. Prince

doi:10.1017/9781108381598.004

3 - Oil Pollution from Operations and Shipwrecks

Published online by Cambridge University Press: 22 January 2021

Edited by

Timothy Fileman and

Stephen de Mora: Affiliation:
Plymouth Marine Laboratory
Timothy Fileman: Affiliation:
Plymouth Marine Laboratory
Thomas Vance: Affiliation:
Plymouth Marine Laboratory

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Summary

Ships are essential facilitators of modern economies – they are by far the most cost-effective mode of long-distance transport for both finished goods and raw materials, and over 90 percent of world trade is carried by sea (IMO, 2017a). There were more than 50,000 ships in the world's merchant fleets in 2015. Bulk carriers – carrying solids such as coal and grains – accounted for about a fifth of the fleet, with a combined capacity of around 705 million tons deadweight. General cargo carriers numbered about 17,000, crude oil tankers about 7000 and container ships about 5000 (Statista, 2018). The amounts moved are staggering; for example, the International Tanker Owners Pollution Federation (ITOPF, 2018) reported that seaborne oil trade has averaged 100 trillion barrel-miles per year since 2000. Financial efficiency pushes for ever-larger vessels, and concomitantly ever-larger canals (Chen et al., 2016) and dock facilities (Mongelluzzo, 2016).

Type: Chapter
Information: Environmental Impact of Ships , pp. 56 - 74

DOI: https://doi.org/10.1017/9781108381598.004 [Opens in a new window]

Publisher: Cambridge University Press

Print publication year: 2020

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References

Admiralty and Maritime Law Guide (2017). International Convention for the Prevention of Pollution of the Sea by Oil, 1954. www.admiraltylawguide.com/conven/oilpol1954.html Google Scholar

Aeppli, C., Carmichael, C. A., Nelson, R. K. et al. (2012). Oil weathering after the Deepwater Horizon disaster led to the formation of oxygenated residues. Environmental Science & Technology, 46, 8799–8807.CrossRef Google Scholar

Allen, A. A., Jaeger, D., Mabile, N. J. & Costanzo, D. (2011). The use of controlled burning during the Gulf of Mexico Deepwater Horizon MC-252 oil spill response. In Proceedings of the International Oil Spill Conference. Washington, DC: American Petroleum Institute, Paper 194.Google Scholar

API (2013). Net Environmental Benefit Analysis for effective oil spill preparedness and response. www.api.org/~/media/Files/EHS/Clean_Water/Oil_Spill_Prevention/NEBA/NEBA-Net-Environmental-Benefit-Analysis-July-2013.pdf Google Scholar

Barbier, C. J. (2015). MDL-2179 oil spill by the oil rig “Deepwater Horizon.” www.laed.uscourts.gov/sites/default/files/OilSpill/Orders/1152015FindingsPhaseTwo.pdf Google Scholar

Bazhenova, O. K., Arefiev, O. A. & Frolov, E. B. (1998). Oil of the volcano Uzon caldera, Kamchatka. Organic Geochemistry, 31, 421–428.Google Scholar

Belore, R. C., Trudel, K., Mullin, J. V. & Guarino, A. (2009). Large-scale cold water dispersant effectiveness experiments with Alaskan crude oils and Corexit 9500 and 9527 dispersants. Marine Pollution Bulletin, 58, 118–128.Google Scholar

Benes, J., Chauvet, M., Kamenik, O. et al. (2015). The future of oil: geology versus technology. International Journal of Forecasting, 31, 207–221.Google Scholar

Black, B. & Ladson, M. (2010). Oil at 150: energy past and future in Pennsylvania. Pennsylvania Legacies, 10, 6–13.Google Scholar

Bourne, W. R., Parrack, J. D. & Potts, G. R. (1967). Birds killed in the Torrey Canyon disaster. Nature, 215, 1123–1125.Google Scholar

Bragg, J. R., Prince, R. C., Harner, E. J. & Atlas, R. M. (1994). Effectiveness of bioremediation for the Exxon Valdez oil spill. Nature, 368, 413–418.Google Scholar

Brigden, C. T., Poulston, S., Twigg, M. V., Walker, A. P. & Wilkins, A. J. (2001). Photo-oxidation of short-chain hydrocarbons over titania. Applied Catalysis B: Environmental, 32, 63–71.CrossRef Google Scholar

Brooks, B. T. (1952). Evidence of catalytic action in petroleum formation. Industrial & Engineering Chemistry, 44, 2570–2577.Google Scholar

Bucas, G. & Saliot, A. (2002). Sea transport of animal and vegetable oils and its environmental consequences. Marine Pollution Bulletin, 44, 1388–1396.Google Scholar

Buie, G. W. (1999). Some thoughts on salvage operations during oil spills. In Proceedings of the International Oil Spill Conference. Washington, DC: American Petroleum Institute, pp. 1205–1209.Google Scholar

Buist, I. (2003). Window-of-opportunity for in situ burning. Spill Science & Technology Bulletin, 8, 341–346.CrossRef Google Scholar

Buist, I., Potter, S., Nedwed, T. & Mullin, J. (2011). Herding surfactants to contract and thicken oil spills in pack ice for in situ burning. Cold Regions Science and Technology, 67, 3–23.Google Scholar

Burrows, P., Rowley, C. & Owen, D. (1974). Torrey Canyon: a case study in accidental pollution. Scottish Journal of Political Economy, 21, 237–258.Google Scholar

Butler, J. N., Wells, P. G., Johnson, S. & Manock, J. J. (1998). Beach tar on Bermuda: recent observations and implications for global monitoring. Marine Pollution Bulletin, 36, 458–463.Google Scholar

Camplin, D. J. & Hall, R. (2014). Neogene history of Bone Gulf, Sulawesi, Indonesia. Marine & Petroleum Geology, 57, 88–108.CrossRef Google Scholar

Canevari, G. P. (1969). General dispersant theory. In Proceedings of the International Oil Spill Conference. Washington, DC: American Petroleum Institute, pp. 171–177.Google Scholar

Carstensen, J., Andersen, J. H., Gustafsson, B. G. & Conley, D. J. (2014). Deoxygenation of the Baltic Sea during the last century. Proceedings of the National Academy of Sciences of the United States of America, 111, 5628–5633.Google Scholar

Chakrabarty, A. N. (1981). Microorganisms Having Multiple Compatible Degradative Energy-Generating Plasmids and Preparation Thereof, US Patent 4, 259,444.Google Scholar

Chen, J., Zeng, X. & Deng, Y. (2016). Environmental pollution and shipping feasibility of the Nicaragua Canal. Marine Pollution Bulletin, 113, 87–93.CrossRef Google Scholar PubMed

Cho, Y., Ahmed, A., Islam, A. & Kim, S. (2015). Developments in FT-ICR MS instrumentation, ionization techniques, and data interpretation methods for petroleomics. Mass Spectrometry Reviews, 34, 248–263.Google Scholar

Clarke, K. C. & Hemphill, J. J. (2002). The Santa Barbara oil spill: a retrospective. Yearbook of the Association of Pacific Coast Geographers, 64, 157–162.Google Scholar

Colcomb, K., Bedborough, D., Lunel, T. et al. (1997). Shoreline cleanup and waste disposal issues during the Sea Empress incident. In Proceedings of the International Oil Spill Conference. Washington, DC: American Petroleum Institute, pp. 195–198.Google Scholar

Del Sontro, T. S., Leifer, I., Luyendyk, B. P., & Broitman, B. R. (2007). Beach tar accumulation, transport mechanisms, and sources of variability at Coal Oil Point, California. Marine Pollution Bulletin, 54, 1461–1471.Google Scholar

Edgar, G. J., Snell, H. L. & Lougheed, L. W. (2003). Impacts of the Jessica oil spill: an introduction. Marine Pollution Bulletin, 47, 273–275.Google Scholar

EIA (2020a). Crude oil input qualities. www.eia.gov/dnav/pet/pet_pnp_crq_a_EPC0_YCG_d_a.htm Google Scholar

EIA (2020b). Energy outlook. www.eia.gov/outlooks/steo/report/global_oil.cfm Google Scholar

EIA (2020c). Oil medium term market outlook. www.iea.org/search?q=Oil%20medium%20term%20market%20outlook Google Scholar

El-Shazly, N. E. (2016). The Gulf Tanker War: Iran and Iraq’s Maritime Swordplay. Berlin: Springer.Google Scholar

Etiope, G. (2015). Natural Gas Seepage: The Earth’s Hydrocarbon Degassing. Berlin: Springer.Google Scholar

Etiope, G., Panieri, G., Fattorini, D. et al. (2014). A thermogenic hydrocarbon seep in shallow Adriatic Sea (Italy): gas origin, sediment contamination and benthic foraminifera. Marine & Petroleum Geology, 57, 283–293.Google Scholar

Farwell, C., Reddy, C. M., Peacock, E. et al. (2009). Weathering and the fallout plume of heavy oil from strong petroleum seeps near Coal Oil Point, CA. Environmental Science & Technology, 43, 3542–3548.Google Scholar

Fingas, M. (2012). The Basics of Oil Spill Cleanup. Boca Raton, FL: CRC Press.Google Scholar

Fingas, M. (2013). Modeling oil and petroleum evaporation. Journal of Petroleum Science Research, 2, 104–115.Google Scholar

Fingas, M. & Fieldhouse, B. (2012). Studies on water-in-oil products from crude oils and petroleum products. Marine Pollution Bulletin, 64, 272–283.CrossRef Google Scholar PubMed

Fitzmaurice, M. (1993). The new Helsinki convention on the protection of the marine environment of the Baltic Sea area. Marine Pollution Bulletin, 26, 64–67.Google Scholar

Fodrie, F. J. & Heck, K. L. Jr. (2011). Response of coastal fishes to the Gulf of Mexico oil disaster. PLoS One, 6, e21609.Google Scholar

Gallagher, J. J., Hile, H. B. & Miller, J. A. (2001). The old New Carissa; a study in patience. In Proceedings of the International Oil Spill Conference. Washington, DC: American Petroleum Institute. pp. 85–90.Google Scholar

Gallaway, B. J., Konkel, W. J. & Norcross, B. L. (2017). Some thoughts on estimating change to Arctic cod populations from hypothetical oil spills in the eastern Alaska Beaufort Sea. Arctic Science, 3, 716–729.Google Scholar

Garneau, M. È., Michel, C., Meisterhans, G. et al. (2016). Hydrocarbon biodegradation by Arctic sea-ice and sub-ice microbial communities during microcosm experiments, Northwest Passage (Nunavut, Canada). FEMS Microbiology Ecology, 92, fiw130.CrossRef Google Scholar PubMed

Garrett, R. M., Pickering, I. J., Haith, C. E. & Prince, R. C. (1998). Photooxidation of crude oils. Environmental Science & Technology, 32, 3719–3723.CrossRef Google Scholar

The Global Response Network (2017). The Global Response Network. https://globalresponsenetwork.org Google Scholar

Goodman, R. (2003). Tar balls: the end state. Spill Science & Technology Bulletin, 8, 117–121.Google Scholar

Griffin, A. (1994). MARPOL 73/78 and vessel pollution: a glass half full or half empty? Indiana Journal of Global Legal Studies, 1, 489–513.Google Scholar

Gunter, C. T. (2014). Potential impacts from a worst case discharge from an United States offshore wind farm. In Proceedings of the International Oil Spill Conference. Washington, DC: American Petroleum Institute, pp. 869–877.Google Scholar

Harris, C. (1995). The Braer incident: Shetland Islands, January 1993. In Proceedings of the International Oil Spill Conference. Washington, DC: American Petroleum Institute, pp. 813–819.Google Scholar

Hayes, D. G. (2017). Commentary: the relationship between “biobased,” “biodegradability” and “environmentally-friendliness” (or the absence thereof). Journal of the American Oil Chemists Society, 94, 1329–1331.Google Scholar

Hazen, T. C., Prince, R. C. & Mahmoudi, N. (2016). Marine oil biodegradation. Environmental Science & Technology, 50, 2121–2129.CrossRef Google Scholar PubMed

Hein, F. J. (2013). Overview of heavy oil, seeps, and oil (tar) sands, California. In Hein, F. J., Leckie, D., Larter, S. & Suter, J. R., eds., Heavy-Oil and Oil-Sand Petroleum Systems in Alberta and Beyond: AAPG Studies in Geology #64. Tulsa, OK: American Association of Petroleum Geologists, pp. 407–435.Google Scholar

HELCOM (2016). Illegal discharges of oil in the Baltic Sea. http://helcom.fi/baltic-sea-trends/environment-fact-sheets/hazardous-substances/illegal-discharges-of-oil-in-the-baltic-sea Google Scholar

Helm, R. C., Costa, D. P., DeBruyn, T. D. et al. (2014). Overview of effects of oil spills on Marine Mammals. In Fingas, M., ed., Handbook of Oil Spill Science and Technology. Hoboken, NJ: John Wiley, pp. 455–475.CrossRef Google Scholar

Henkel, L. A., Nevins, H., Martin, M. et al. (2014). Chronic oiling of marine birds in California by natural petroleum seeps, shipwrecks, and other sources. Marine Pollution Bulletin, 79, 155–163.CrossRef Google Scholar PubMed

Hughey, C. A., Galasso, S. A. & Zumberge, J. E. (2007). Detailed compositional comparison of acidic NSO compounds in biodegraded reservoir and surface crude oils by negative ion electrospray Fourier transform ion cyclotron resonance mass spectrometry. Fuel, 86, 758–768.CrossRef Google Scholar

IMO (2006). Pollution prevention equipment required under MARPOL 73/78. www.amnautical.com/products/pollution-prevention-equipment-under-marpol-2006-edition#.V7pT3Y73rxA Google Scholar

IMO (2016). International Convention for the Prevention of Pollution from Ships (MARPOL). www.imo.org/en/About/Conventions/ListOfConventions/Pages/International-Convention-for-the-Prevention-of-Pollution-from-Ships-(MARPOL).aspx Google Scholar

IMO (2017a). IMO Profile. Overview. https://business.un.org/en/entities/13 Google Scholar

IMO (2017b). Oil spill organizations and resource providers. www.imo.org/en/OurWork/Environment/PollutionResponse/OilPollutionResources/Pages/Oil%20Spill%20Organizations%20and%20Resource%20Providers.aspx Google Scholar

ITOPF (2018). Oil tanker spill statistics 2017. www.itopf.com/knowledge-resources/data-statistics/statistics Google Scholar

Jackson, M. J., Powell, T. G., Summons, R. E. & Sweet, I. P. (1986). Hydrocarbon shows and petroleum source rocks in sediments as old as 1.7×10⁹ years. Nature, 322, 727–729.Google Scholar

Kasting, J. F. & Siefert, J. L. (2002). Life and the evolution of Earth’s atmosphere. Science, 296, 1066–1068.CrossRef Google Scholar PubMed

Kerschner, C. & Hubacek, K. (2009). Assessing the suitability of input–output analysis for enhancing our understanding of potential economic effects of peak oil. Energy, 34, 284–290.CrossRef Google Scholar

Kim, S., Stanford, L. A., Rodgers, R. P. et al. (2005). Microbial alteration of the acidic and neutral polar NSO compounds revealed by Fourier transform ion cyclotron resonance mass spectrometry. Organic Geochemistry, 36, 1117–1134.Google Scholar

Kucuksezgin, F., Pazi, I., Gonul, L. T. & Duman, M. (2013). Distribution and sources of polycyclic aromatic hydrocarbons in Cilician Basin shelf sediments (NE Mediterranean). Marine Pollution Bulletin, 71, 330–335.Google Scholar

Kvenvolden, K. A. & Cooper, C. K. (2003). Natural seepage of crude oil into the marine environment. Geo-Marine Letters, 23, 140–146.Google Scholar

Lee, K., Nedwed, T., Prince, R. C. & Palandro, D. (2013). Lab tests on the biodegradation of chemically dispersed oil should consider the rapid dilution that occurs at sea. Marine Pollution Bulletin, 73, 314–318.Google Scholar

Lemkau, K. L., Peacock, E. E., Nelson, R. K. et al. (2010). The M/V Cosco Busan spill: source identification and short-term fate. Marine Pollution Bulletin, 60, 2123–2129.Google Scholar

Lessard, R. R. & DeMarco, G. (2000). The significance of oil spill dispersants. Spill Science & Technology Bulletin, 6, 59–68.CrossRef Google Scholar

MacDonald, I. R., Garcia-Pineda, O., Beet, A. et al. (2015). Natural and unnatural oil slicks in the Gulf of Mexico. Journal of Geophysical Research: Oceans, 120, 8364–8380.Google Scholar

Martinelli, M., Luise, A., Tromellini, E. et al. (1995). The M/C Haven oil spill: environmental assessment of exposure pathways and resource injury. In Proceedings of the International Oil Spill Conference. Washington, DC: American Petroleum Institute, pp. 679–685.Google Scholar

McFarlin, K. M., Prince, R. C., Perkins, R. & Leigh, M. B. (2014). Biodegradation of dispersed oil in arctic seawater at –1°C. PLoS One, 9, e84297.CrossRef Google Scholar PubMed

McKirdy, D. M., Aldridge, A. K. & Ypma, P. J. (1983). A geochemical comparison of some crude oils from pre-Ordovician carbonate rocks. In Bjoroy, M., ed., Advances in Organic Geochemistry 1981: International Conference Proceedings. Hoboken, NJ: Wiley-Blackwell, pp. 99–107.Google Scholar

McNutt, M. K., Chu, S., Lubchenco, J. et al. (2012). Applications of science and engineering to quantify and control the Deepwater Horizon oil spill. Proceedings of the National Academy of Sciences of the United States of America, 109, 20222–20228.CrossRef Google Scholar PubMed

Mendes, S. D., Redmond, M. C., Voigritter, K. et al. (2015). Marine microbes rapidly adapt to consume ethane, propane, and butane within the dissolved hydrocarbon plume of a natural seep. Journal of Geophysical Research: Oceans, 120, 1937–1953.Google Scholar

Monfils, R. (2005). The global risk of marine pollution from WWII shipwrecks: examples from the seven seas. In Proceedings of the International Oil Spill Conference. Washington, DC: American Petroleum Institute, pp. 1049–1054.Google Scholar

Mongelluzzo, W. (2016). No easy solutions to problems plaguing US ports. www.joc.com/port-news/us-ports/no-easy-solutions-problems-plaguing-us-ports_20160324.html Google Scholar

Mudge, S. (1997). Can vegetable oils outlast mineral oils in the marine environment? Marine Pollution Bulletin, 34, 213.Google Scholar

Nauman, S. A. (1991). Shoreline clean-up: equipment and operations. In Proceedings of the International Oil Spill Conference. Washington, DC: American Petroleum Institute, pp. 141–148.Google Scholar

NRC (1998). Oil Spill Risks from Tank Vessel Lightering. Washington, DC: National Academies Press.Google Scholar

NRC (2003). Oil in the Sea III. Washington, DC: National Academies Press.Google Scholar

Owens, E. H., Taylor, E. & Humphrey, B. (2008). The persistence and character of stranded oil on coarse-sediment beaches. Marine Pollution Bulletin, 56, 14–26.Google Scholar

Palminteri, J. (2014). Underwater seep tents dry up off Goleta. https://keyt.com/news/2014/07/23/underwater-seep-tents-dry-up-off-goleta Google Scholar

Peters, K. E., Walters, C. C. & Moldowan, J. M. (2005). The Biomarker Guide. Cambridge: Cambridge University Press.Google Scholar

Prince, R. C. (2010). Eukaryotic hydrocarbon degraders. In Timmis, K. N., ed., Handbook of Hydrocarbon and Lipid Microbiology. Berlin: Springer-Verlag, pp. 2066–2078.Google Scholar

Prince, R. C. (2015). Oil spill dispersants: boon or bane? Environmental Science & Technology, 49, 6376–6384.Google Scholar

Prince, R. C. (2016). Biostimulation of marine crude oil spills using dispersants. In McGenity, T. J., Timmis, K. N. & Nogales, B., eds., Hydrocarbon and Lipid Microbiology Protocols. Berlin: Springer, pp. 95–104.Google Scholar

Prince, R. C. & Walters, C. C. (2016). Biodegradation of oil and its implications for source identification. In Stout, S. A. & Wang, Z., eds., Standard Handbook Oil Spill Environmental Forensics, 2nd ed. Cambridge, MA: Academic Press, pp. 869–916.Google Scholar

Prince, R. C., Gramain, A. & McGenity, T. J. (2010). Prokaryotic hydrocarbon degraders. In Timmis, K. N., ed., Handbook of Hydrocarbon and Lipid Microbiology. Berlin: Springer-Verlag, pp. 1672–1692.Google Scholar

Prince, R. C., McFarlin, K. M., Butler, J. D. et al. (2013). The primary biodegradation of dispersed crude oil in the sea. Chemosphere, 90, 521–526.Google Scholar

Prince, R. C., Nash, G. W. & Hill, S. J. (2016). The biodegradation of crude oil in the deep ocean. Marine Pollution Bulletin, 111, 354–357.Google Scholar

Prince, R. C., Butler, J. D. & Redman, A. D. (2017). The rate of crude oil biodegradation in the sea. Environmental Science & Technology, 51, 1278–1284.Google Scholar

Quigley, D. C., Hornafius, J. S., Luyendyk, B. P. et al. (1999). Decrease in natural marine hydrocarbon seepage near Coal Oil Point, California, associated with offshore oil production. Geology, 27, 1047–1050.2.3.CO;2>CrossRef Google Scholar

Redman, A. D., Parkerton, T. F., McGrath, J. A. & Di Toro, D. M. (2012). PETROTOX: an aquatic toxicity model for petroleum substances. Environmental Toxicology & Chemistry, 31, 2498–2506.Google Scholar

Savage, C. (2014). Guantánamo detainee pleads guilty in 2002 attack on tanker off Yemen. New York Times. www.nytimes.com/2014/02/21/us/guantanamo-detainee-ahmed-muhammed-haza-al-darbi.html?_r=0 Google Scholar

Selley, R. C. & Van der Spuy, D. (2016). The oil and gas basins of Africa. Episodes 39, 429–445.Google Scholar

Simoneit, B. R. & Kvenvolden, K. A. (1994). Comparison of ¹⁴C ages of hydrothermal petroleums. Organic Geochemistry, 21, 525–529.Google Scholar

Smil, V. (2006). Peak oil: a catastrophist cult and complex realities. World Watch, 19, 22–24.Google Scholar

Smith, S. R. & Knap, A. H. (1985). Significant decrease in the amount of tar stranding on Bermuda. Marine Pollution Bulletin, 16, 19–21.Google Scholar

Speight, J. G. (2014). The Chemistry and Technology of Petroleum, 5th ed. Boca Raton, FL: CRC Press.Google Scholar

Stanford, L. A., Kim, S., Klein, G. C., et al. (2007). Identification of water-soluble heavy crude oil organic-acids, bases, and neutrals by electrospray ionization and field desorption ionization Fourier transform ion cyclotron resonance mass spectrometry. Environmental Science & Technology, 41, 2696–2702.Google Scholar

Statista (2018). Number of ships in the world merchant fleet between January 1, 2008 and January 1, 2017, by type. www.statista.com/statistics/264024/number-of-merchant-ships-worldwide-by-type Google Scholar

Sutton, C. & Calder, J. A. (1975). Solubility of alkylbenzenes in distilled water and sea water at 25.0°. Journal of Chemical and Engineering Data, 20, 320–322.Google Scholar

Tissot, B. P. & Welte, D. H. (1984). Petroleum Formation and Occurrence. Berlin: Springer-Verlag.CrossRef Google Scholar

US Coast Guard (2016). Oil Pollution Act of 1990 (OPA). www.uscg.mil/Mariners/National-Pollution-Funds-Center/About_NPFC/OPA Google Scholar

US Congress House Committee on Merchant Marine and Fisheries, Subcommittee on Coast Guard and Navigation (1989). Liability for Oil Pollution Damages. Washington, DC: US Government Printing Office.Google Scholar

US Department of Justice (2011). Ship owners and operators to pay $44 million in damages and penalties for 2007 Bay Bridge crash and oil spill. https://casedocuments.darrp.noaa.gov/southwest/cosco/pdf/09-19-11_Cosco%20Busan_Overall_Consent_Decree_Press_Release%20FINAL.pdf Google Scholar

USDOE (2008). Strategic petroleum reserve crude oil assay manual. www.spr.doe.gov/reports/docs/CrudeOilAssayManual.pdf Google Scholar

USEPA (2008). Global trade and fuels assessment – future trends and effects of requiring clean fuels in the marine sector. https://nepis.epa.gov Google Scholar

USEPA (2011). Environmentally acceptable lubricants EPA 800-R-11-002. https://nepis.epa.gov Google Scholar

Varfolomeev, S. D., Karpov, G. A., Synal, H. A., Lomakin, S. M. & Nikolaev, E. N. (2011). The youngest natural oil on Earth. Doklady Chemistry, 438, 144–147.Google Scholar

Vonk, S. M., Hollander, D. J. & Murk, A. J. (2015). Was the extreme and wide-spread marine oil-snow sedimentation and flocculent accumulation (MOSSFA) event during the Deepwater Horizon blow-out unique? Marine Pollution Bulletin, 100, 5–12.Google Scholar

Wade, T. L., Sericano, J. L., Sweet, S. T., Knap, A. H. & Guinasso, N. L. (2016). Spatial and temporal distribution of water column total polycyclic aromatic hydrocarbons (PAH) and total petroleum hydrocarbons (TPH) from the Deepwater Horizon (Macondo) incident. Marine Pollution Bulletin, 103, 286–293.Google Scholar

Warnock, A. M., Hagen, S. C. & Passeri, D. L. (2015). Marine tar residues: a review. Water Air & Soil Pollution 226, 1–24.Google Scholar

Wiltshire, G. A. & Corcoran, L. (1991). Response to the Presidente Rivera major oil spill, Delaware River. In Proceedings of the International Oil Spill Conference. Washington, DC: American Petroleum Institute, pp. 253–258.Google Scholar

Wolborsky, S. L. (2014). Choke Hold: The Attack on Japanese Oil in World War II. Auckland: Pickle Partners Publishing.Google Scholar

Word, J. Q., Clark, J. R. & Word, L. S. (2013). Comparison of the acute toxicity of Corexit 9500 and household cleaning products. Human & Ecological Risk Assessment, 21, 707–725.Google Scholar

Zahed, M. A., Aziz, H. A., Isa, M. H. & Mohajeri, L. (2010). Effect of initial oil concentration and dispersant on crude oil biodegradation in contaminated seawater. Bulletin of Environmental Contamination & Toxicology, 84, 438–442.Google Scholar

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