April 20, 2020, marks the tenth anniversary of the Deepwater Horizon rig explosion, the offshore oil industry's biggest environmental disaster.
Eleven people died, 17 others were injured, Transocean's drilling rig sank, and an incident caused more than four million barrels of oil to spill into the U.S. Gulf of Mexico from the BP-operated Macondo well which spewed oil into the ocean for 87 days before it was finally capped.
In a review paper published in the journal Nature Reviews Earth & Environment, Woods Hole Oceanographic Institution (WHOI) geochemists Elizabeth Kujawinski and Christopher Reddy review what they— and their science colleagues from around the world—have learned from studying the spill over the past decade.
Here are some takeaways:
“So many lessons were learned during the Deepwater Horizon disaster that it seemed appropriate and timely to consider those lessons in the context of a review,” says Kujawinski. “We found that much good work had been done on oil weathering and oil degradation by microbes, with significant implications for future research and response activities.”
“At the end of the day, this oil spill was a huge experiment,” adds Reddy. “It shed great light on how nature responds to an uninvited guest. One of the big takeaways is that the oil doesn’t just float and hang around. A huge amount of oil that didn’t evaporate was pummeled by sunlight, changing its chemistry. That’s something that wasn’t seen before, so now we have insight into this process.”
Released for the first time in a deep ocean oil spill, chemical dispersants remain one of the most controversial debates in the aftermath of Deepwater Horizon. Studies offer conflicting conclusions about whether dispersants released in the deep sea reduced the amount of oil that reached the ocean surface, and the results are ambiguous about whether dispersants helped microbes break down the oil at all.
“I think the biggest unknowns still center on the impact of dispersants on oil distribution in seawater and their role in promoting—or inhibiting—microbial degradation of the spilled oil,” says Kujawinski, whose lab was the first to identify the chemical signature of the dispersants, making it possible to track in the marine environment.
Though the authors caution that the lessons learned from the Deepwater Horizon release may not be applicable to all spills, the review highlights advances in oil chemistry, microbiology, and technology that may be useful at other deep-sea drilling sites and shipping lanes in the Arctic. The authors call on the research community to work collaboratively to understand the complex environmental responses at play in cold climates, where the characteristics of oil are significantly different from the Gulf of Mexico.
“Now we have a better sense of what we need to know,” Kujawinski says. “Understanding what these environments look like in their natural state is really critical to understanding the impact of oil spill conditions.”
Additional authors of the review are chemist Ryan P. Rodgers (Florida State University), and microbiologists J. Cameron Thrash (University of Southern California, Los Angeles), David L. Valentine (University of California Santa Barbara), and Helen K. White (Haverford College).