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Research, Response for Future Oil Spills: Lessons Learned from Deepwater Horizon



Research, Response for Future Oil Spills: Lessons Learned from Deepwater Horizon

Research, Response for Future Oil Spills: Lessons Learned from Deepwater Horizon

A special collection of articles about the Deepwater Horizon oil spill provides the first comprehensive analysis and synthesis of the science used in the unprecedented response effort by the government, academia, and industry. Papers present a behind-the-scenes look at the extensive scientific and engineering effort—teams, data, information, and advice from within and outside the government—assembled to respond to the disaster. And, with the benefit of hindsight and additional analyses, these papers evaluate the accuracy of the information that was used in real-time to inform the response team and the public.

For the most part, information presented publically during the spill was accurate. Oil was rapidly consumed by bacteria, seafood was not contaminated by hydrocarbons or dispersants, and the oil budget was by and large accurate. The only part of the oil budget that was later found to be inaccurate was the fraction of oil that was chemically dispersed versus naturally dispersed. That information had no impact on public safety, seafood safety or the response effort, but understanding the amount of oil that was dispersed chemically vs. naturally is important for future such efforts.

One of the most controversial issues concerned the rate at which hydrocarbons were spewing forth from the damaged well. The lengthy time it took for the scientific team to determine the flow rate led to considerable speculation that the government was withholding information. In reality, as described by the papers, the government/academic team charged with determining flow rate took the time they needed to get it right. The accuracy of the flow rates improved with time as more and better in situ data were acquired and more independent methods reported results.

Valuable lessons were learned, with preparation and knowledge being two key elements needed to respond to disasters such as the Deepwater Horizon oil spill, one of the worst environmental emergencies in the history of the U.S. and one that also took the lives of 11 oil rig workers.

Two overview papers and 13 specialty papers constitute a special section of the prestigious Proceedings of the National Academy of Science. Of the 15 papers, three are newly published: two introductory papers and one specialty paper provide an inside look at the scientific and engineering aspects of stopping the flow of oil, guaranteeing the integrity of the well once it was shut in, estimating the amount of oil spilled, capturing and recovering oil, tracking and forecasting surface oil, protecting coastal and oceanic wildlife and habitat, managing fisheries and protecting the safety of seafood. The papers describe the process underway to determine the impact of the spill on the natural resources and ecosystems of the Gulf of Mexico, but because those analyses are not completed, no conclusions are presented. The remaining 12 papers have been previously published online.

“While the federal family was well versed in oil response and remediation, and we brought many resources to bear, the scale and complexity of Deepwater Horizon taxed our organizations in unprecedented ways,” said Jane Lubchenco, Ph.D., under secretary of commerce for oceans and atmosphere and NOAA administrator. “We learned much during this extraordinary disaster and we hope the lessons learned will be implemented before and used during any future events.”

In one of the papers—“Science in support of the Deepwater Horizon response”—lead author Lubchenco and her co-authors suggest future oil spill response preparedness include:

  • Gather adequate environmental baselines for all regions at risk;
  • Develop new technologies for rapid precise reconnaissance and sampling to support a timely and robust response effort;
  • Fill large information gaps regarding biological effects of oil, changing climate, and other simultaneous drivers of variability in coastal and aquatic ecosystems;
  • Require future oil extraction permits be conditional on having mechanisms in place to rapidly assess flow rate; and
  • Conduct research on the impacts of dispersants and dispersants-plus-oil on a wide range of species and life stages.

Another paper—”Application of science and engineering to quantify and control the Deepwater Horizon oil spill”—describes the unprecedented collaboration among government, academic, and industry scientists and engineers. Lead author Marcia McNutt, Ph.D., director of the USGS, explains how scientific and engineering information was crucial to guide decision-making for questions never before encountered, especially during the tense hours after the well was capped, but might still be leaking underground.

“Although we all hope ‘Never again!’ will there be an oil spill like the Deepwater Horizon, there will always be some risk as we move into deeper water and more difficult environments in our quest for the planet’s remaining fossil fuels,” said McNutt. “A significant drawback in addressing many of the issues we confronted in Deepwater Horizon was the lack of peer-reviewed scientific publications from prior marine-well blowouts to help guide our actions; we will not make that mistake again by neglecting to publish for posterity the scientific lessons from this tragedy.”

The event also showed the value of federal partnerships with academic institutions.

“The coordination within and across agencies was impressive, but so too was the engagement of academic scientists in a joint effort to respond to the disaster” said Steve Murawski, a co-author on both introductory papers, chief scientist at NOAA Fisheries during the response effort and now a professor at the University of South Florida. “Through these partnerships, new scientific discoveries were made such as estimating flow rate from atmospheric measurements, testing for dispersant in seafood, understanding the behavior of the loop current, and discovering novel microbial communities in the Gulf.”

A final paper—“Scientific basis for safely shutting in the Macondo well after the April 20, 2010 Deepwater Horizon blowout”—further points to the unprecedented level of coordination among scientists, engineers, and emergency response officials in the public and private sectors.  In this paper, scientists describe the geological hazards of shutting in the well and the conditions under which this could safely and successfully be done.

“Without this level of cooperation and round-the-clock engagement by people from many disciplines, it would not have been possible to carry out the continual scientific analyses needed to ensure the well was not leaking below the sea floor once the capping stack was closed,” explained lead author Steve Hickman, USGS research geologist. “For the government scientists onsite at BP headquarters, rapid acquisition and analysis of critical data sets and open exchange of ideas and possible outcomes was essential to ensuring the well had enough integrity to remain safely shut in until it was killed and sealed with cement.”

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More information

Parameter Value Description
Magnitude mb The magnitude for the event.
Longitude ° East Decimal degrees longitude. Negative values for western longitudes.
Latitude ° North Decimal degrees latitude. Negative values for southern latitudes.
Depth km Depth of the event in kilometers.
Place Textual description of named geographic region near to the event. This may be a city name, or a Flinn-Engdahl Region name.
Time 1970-01-01 00:00:00 Time when the event occurred. UTC/GMT
Updated 1970-01-01 00:00:00 Time when the event was most recently updated. UTC/GMT
Timezone offset Timezone offset from UTC in minutes at the event epicenter.
Felt The total number of felt reports
CDI The maximum reported intensity for the event.
MMI The maximum estimated instrumental intensity for the event.
Alert Level The alert level from the PAGER earthquake impact scale. Green, Yellow, Orange or Red.
Review Status Indicates whether the event has been reviewed by a human.
Tsunami This flag is set to "1" for large events in oceanic regions and "0" otherwise. The existence or value of this flag does not indicate if a tsunami actually did or will exist.
SIG A number describing how significant the event is. Larger numbers indicate a more significant event.
Network The ID of a data contributor. Identifies the network considered to be the preferred source of information for this event.
Sources A comma-separated list of network contributors.
Number of Stations Used The total number of Number of seismic stations which reported P- and S-arrival times for this earthquake.
Horizontal Distance Horizontal distance from the epicenter to the nearest station (in degrees).
Root Mean Square sec The root-mean-square (RMS) travel time residual, in sec, using all weights.
Azimuthal Gap The largest azimuthal gap between azimuthally adjacent stations (in degrees).
Magnitude Type The method or algorithm used to calculate the preferred magnitude for the event.
Event Type Type of seismic event.
Event ID Id of event.
Event Code An identifying code assigned by, and unique from, the corresponding source for the event.
Event IDS A comma-separated list of event ids that are associated to an event.

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