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  • Written by Steven Murawski, Downtown Partnership-Peter Betzer Endowed Chair in Biological Oceanography, University of South Florida

Over the decade since the Deepwater Horizon spill, thousands of scientists have analyzed its impact on the Gulf of Mexico. The spill affected many different parts of the Gulf, from coastal marshes to the deep sea.

At the Center for Integrated Modeling and Analysis of the Gulf Ecosystem, or C-IMAGE[1] at the University of South Florida, marine scientists[2] have been analyzing these effects since 2011. C-IMAGE has received funding from the Gulf of Mexico Research Initiative[3] – a broad, independent research program initially funded by a US$500 million grant from BP, the company held principally responsible for the spill.

Our findings and those of many other academic, government and industry researchers have filled two[4] books[5]. These works seek to quantify the past and future impacts of oil spills[6], and to help prevent such accidents from ever happening again. Here are some important findings on how the Deepwater Horizon disaster affected Gulf of Mexico ecosystems[7].

Scientists have found oil from the Deepwater Horizon blowout in fishes' livers and on the deep ocean floor Sediment cores from the seabed preserve evidence of oil that has settled onto the seafloor from historical spills. C-IMAGE Consortium, CC BY-ND[8][9]

Oil in fish and sediments

Before the spill, baseline data on oil contamination in fishes and sediments in the Gulf of Mexico did not exist. This kind of information is critical for assessing impacts from a spill and calculating how quickly the ecosystem can return to its previous, pre-spill state. Oil was already present in the Gulf from past spills[10] and natural seeps[11], but the Deepwater Horizon was the largest accidental spill in the ocean anywhere in the world.

C-IMAGE researchers developed the first comprehensive baseline of oil contamination in the Gulf’s fishes[12] and sediments, including all waters off the United States, Mexico and Cuba. Researchers spent almost 250 days at sea, sampling over 15,000 fishes and taking over 2,500 sediment cores.

Scientists have found oil from the Deepwater Horizon blowout in fishes' livers and on the deep ocean floor Research cruises on the RV Weatherbird II and the RV Justo Sierra took scientists all over the Gulf of Mexico from 2011 to 2018. C-IMAGE Consortium, CC BY-ND[13]

Repeated sampling from 2011 through 2018 of the region around the spill site has produced estimates of how quickly various species are able to overcome oil pollution; impacts on the health of various species, from microbes to whales; and how fast oil stranded on the bottom has become buried in sediments.

Importantly, no fish yet sampled anywhere in the Gulf has been free of hydrocarbons – a telling sign of chronic and ongoing pollution in the Gulf. It is not known if similar findings would result from ecosystem-wide studies elsewhere because such surveys are rare.

Many commercially important fish species were affected by the Deepwater Horizon disaster. Researchers found skin lesions on red snapper from the northern Gulf in the months after the spill, but the lesions became less frequent and severe by 2012[14]. There is other evidence of ongoing and increasing exposures to hydrocarbons over time in economically and environmentally important species like golden tilefish[15], grouper[16] and hake[17] as well as red snapper.

Increasing concentrations of hydrocarbons in liver tissues of some species, such as groupers, suggest these fish have experienced long-term exposure to oil. Chronic exposures have been associated with the decline of health indices in tilefish[18] and grouper[19].

Scientists embark on a ‘mud and blood’ research cruise in 2016 to collect and analyze fish and soil samples near the Deepwater Horizon spill site.

To complement field studies, scientists created an oil exposure test facility at Florida’s Mote Aquaculture Research Park[20] to assess how contact with oil affected adult fishes. For example, southern flounder that were exposed to oiled sediments for 35 days showed evidence of oxidative stress[21], a cellular imbalance that can cause decreased fertility, increased cellular aging and premature death.

Fishes that live in deeper waters, from depths of about 650 to 3,300 feet (200 to 1,000 meters) were also affected. These fish are especially important because they are a food source for larger commercially relevant fish, marine mammals and birds.

Researchers found increased concentrations of polycyclic aromatic hydrocarbons – chemicals that occur naturally in crude oil – in fish tissues after the spill. In 2015-2016, PAH levels were still higher than pre-spill levels[22]. Evidence indicates that the main sources of this contamination are through fishes’ diets and transfers from female fish to their eggs.

Oil on the sea floor

Much of the oil released in the spill created huge slicks at the water’s surface. But significant quantities of crude oil also were deposited at the bottom of the deep sea.

It was carried there by marine snow[23] – clumps of plankton, fecal pellets, biominerals and soil particles washed into the Gulf from land. In a process that occurs throughout the world’s oceans, these particles sink through the water column, transporting large quantities of material to the sea floor. In the Gulf, they attached to oil droplets as they descended.

Scientists have found oil from the Deepwater Horizon blowout in fishes' livers and on the deep ocean floor Marine snow (clumps of organic and mineral particles) in Gulf of Mexico waters carried oil and burnt hydrocarbons to the sea floor. Andrew Warren, CC BY-ND[24]

During the spill, responders set parts of the massive surface slick on fire[25] in an effort to prevent it from reaching beaches and marshes. Crude oil contains thousands of different carbon compounds that become more toxic after they are burned. Post-spill studies showed that these compounds can be trapped in marine snow[26], covering the seabed and harming organisms that live there.

Researchers coined the term MOSSFA (marine oil snow sedimentation and flocculent accumulation) to describe this mechanism for deposition of significant oil on the seabed. Thanks to this research, MOSSFA has been incorporated into models that U.S. government agencies use for oil spill response. C-IMAGE researchers have also developed methods to predict the intensity of MOSSFA[27] if a similar-sized oil spill occurs anywhere in the world.

Post-spill studies found that levels of oil compounds on the seafloor in the area affected by the spill were two to three times higher than background levels[28] elsewhere in the Gulf. Sediment cores taken from around the wellhead showed that the density of minute single-celled organisms called foraminifera[29], which are abundant throughout the world’s oceans and are a food source for other fishes, squids and marine mammals, declined by 80% to 90% over 10 months following the event, and their species diversity declined by 30% to 40%[30].

Oxygen levels in these sediments also decreased in the three years following the spill, degrading conditions for organisms living at the sea floor[31]. As a result of changes like these, researchers project that it will take perhaps 50 to 100 years for the deep ocean ecosystem to recover[32].

Scientists have found oil from the Deepwater Horizon blowout in fishes' livers and on the deep ocean floor Commercial and sport fishing generate millions of dollars in revenues for Gulf coast states. The Deepwater Horizon spill affected many popular species, including grouper, red snapper and flounder. Lance Cpl. Brianna Gaudi, USMC[33]

More transparency from the oil industry

Scientists are still assessing key questions about the Gulf’s ecological health, such as how long it will take for deep ecosystems to recover and what the lasting impacts are of episodic pollution events on top of chronic exposure. But here are some steps that would make it easier to measure both chronic effects of oil pollution and impacts from large-scale spills.

Today, the only discharge that offshore oil and gas producers are required to measure is from “produced water” – natural water that comes up from beneath the sea floor along with oil and gas. And they are only required to report its hydrocarbon concentrations, even though the water can contain metals and radioactive material.

In our view, they should also be required to routinely monitor oil contaminants in water, sediments and marine life near each platform, just as wastewater treatment plants periodically gather data on what they are discharging. This would provide a baseline for analyzing impacts from future spills and for detecting leaks hidden from the surface.

Researchers would also like to see more transparency in data sharing about the industry – including routine equipment failures, other discharges[34] such as drilling muds[35] and other operational details – and greater U.S. engagement with Mexico and Cuba on oil exploration and spill response. As oil and gas production moves into ever-deeper waters, the goal should be to respond faster, more effectively and with a better understanding of what’s happening in real time.

[You’re smart and curious about the world. So are The Conversation’s authors and editors. You can read us daily by subscribing to our newsletter[36].]

References

  1. ^ C-IMAGE (www.marine.usf.edu)
  2. ^ marine scientists (www.researchgate.net)
  3. ^ Gulf of Mexico Research Initiative (gulfresearchinitiative.org)
  4. ^ two (www.springer.com)
  5. ^ books (www.springer.com)
  6. ^ past and future impacts of oil spills (beneaththehorizon.org)
  7. ^ affected Gulf of Mexico ecosystems (www.youtube.com)
  8. ^ C-IMAGE Consortium (flic.kr)
  9. ^ CC BY-ND (creativecommons.org)
  10. ^ past spills (response.restoration.noaa.gov)
  11. ^ natural seeps (www.whoi.edu)
  12. ^ fishes (doi.org)
  13. ^ CC BY-ND (creativecommons.org)
  14. ^ less frequent and severe by 2012 (doi.org)
  15. ^ golden tilefish (doi.org)
  16. ^ grouper (doi.org)
  17. ^ hake (doi.org)
  18. ^ tilefish (doi.org)
  19. ^ grouper (doi.org)
  20. ^ Mote Aquaculture Research Park (mote.org)
  21. ^ oxidative stress (www.medicalnewstoday.com)
  22. ^ still higher than pre-spill levels (pubs.acs.org)
  23. ^ marine snow (theconversation.com)
  24. ^ CC BY-ND (creativecommons.org)
  25. ^ set parts of the massive surface slick on fire (abcnews.go.com)
  26. ^ can be trapped in marine snow (doi.org)
  27. ^ predict the intensity of MOSSFA (link.springer.com)
  28. ^ two to three times higher than background levels (doi.org)
  29. ^ foraminifera (ocean.si.edu)
  30. ^ declined by 30% to 40% (doi.org)
  31. ^ degrading conditions for organisms living at the sea floor (doi.org)
  32. ^ 50 to 100 years for the deep ocean ecosystem to recover (doi.org)
  33. ^ Lance Cpl. Brianna Gaudi, USMC (www.iimef.marines.mil)
  34. ^ other discharges (www.boem.gov)
  35. ^ drilling muds (www.sciencedirect.com)
  36. ^ You can read us daily by subscribing to our newsletter (theconversation.com)

Authors: Steven Murawski, Downtown Partnership-Peter Betzer Endowed Chair in Biological Oceanography, University of South Florida

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