International Expedition Investigates Climate Change, Alternative Fuels in Arctic
- Accept the Challenge
- About NRL
- Doing Business
- Public Affairs & Media
- Public Affairs Office
- News Releases
- 2014 News Releases
- 2013 News Releases
- 2012 News Releases
- 2011 News Releases
- 2010 News Releases
- 2009 News Releases
- 2008 News Releases
- 2007 News Releases
- 2006 News Releases
- 2005 News Releases
- 2004 News Releases
- 2003 News Releases
- 2002 News Releases
- 2001 News Releases
- 2000 News Releases
- 1999 News Releases
- 1998 News Releases
- 1997 News Releases
- 1996 News Releases
- NRL Videos
- Email Updates
- Social Media
- NRL Events
- Popular Images
- Public Notices
- Field Sites
- Visitor Info
- Contact NRL
Scientists from the Marine Biogeochemistry and Geology and Geophysics sections of the Naval Research Laboratory organized and led a team of university and government scientists on an Arctic expedition to initiate methane hydrate exploration in the Beaufort Sea and determine the spatial variation of sediment contribution to Arctic climate change.
|NRL's Marine Biogeochemistry section organized and led an international research expedition aboard the USCG Polar Sea in the Beaufort Sea during September 15-26, 2009. Photo: U.S. Coast Guard|
Utilizing the U.S. Coast Guard Cutter Polar Sea as a research platform, three cross-shelf transects were surveyed and sampled off Alaska's North Slope at Hammerhead, Thetis Island and Halkett representing three regions of the Alaskan shelf. The expedition integrated expertise in coastal geophysics, sediment geochemistry, dissolved and free methane fluxes through the water column and into the atmosphere, sediment and water column microbiology and biogeochemistry and detailed characterization of the sub-seafloor geology.
"The objective of the sampling is to help determine variations in the shallow sediment and water column methane sources, methane cycling and the subsequent flux to the atmosphere," said Richard Coffin, chief scientist, NRL Chemistry Division.
The content, location and distribution of methane in hydrate is variable and controlled by geothermal gradients and biological and thermal methane production. Large deposits of methane hydrates, frozen mixtures of hydrocarbon gas (mostly methane) and water, occur over large areas of the ocean floor. International research has begun with a primary goal of obtaining the methane in these hydrates as an energy source.
During the 12-day expedition, Methane In The Arctic Shelf and Slope (MITAS-1), the crew conducted 34 conductivity-temperature-depth (CTD) water column casts using a rosette of Niskin bottles and collected sediment samples from 14 piston cores, three vibrocores and 20 multicores. Regions selected for this study were based on the review of Minerals Management Service and U.S. Geologic Survey (USGS) seismic data with specific sample locations decided onboard through review of the 3.5 Kilohertz (kHz) sub-bottom profiler data.
The MITAS-1 crew focused on six primary goals to include:
- Acquire and integrate seismic, acoustic, temperature, geochemical, and lithostratigraphic data for evaluation of deep sediment hydrate distributions.
- Estimate spatial variation and controls on the vertical methane flux as it relates to variations in lithostratigraphy, geologic structures, water column temperatures, heat flow, seismic and acoustic profiles, and water depth.
- Develop and calibrate models to evaluate sediment hydrate loading, hydrate destabilization through warming, and the fate of methane after destabilization.
- Determine and model the transport of methane from the sediment through the water column into the atmosphere.
- Study the control of total methane emissions by microbial methane consumption in the sediment and in the water column.
- Study the contribution of methane to the benthic and pelagic carbon cycling.
The expedition was supported by NRL, Office of Naval Research (ONR), Department of Energy (DoE), Royal Netherlands Institute for Sea Research (NIOZ), French Research Institute for Exploitation of the Sea (IFREMER) and the German Leibniz Institute of Marine Sciences (IFM-Geomar). Future expeditions will also include scientists from Scotland's Herriot-Watt University, Norway's University of Bergen and GNS Science of New Zealand.
"Our project is intended to initiate a long-term collaboration in future expeditions in the Beaufort Sea and other regions of the Arctic Ocean," said Coffin.
NRL has developed strong research topics regarding methane hydrates over the last 30 years. NRL has unique field and laboratory expertise that couples physical, chemical, and biological parameters to address methane hydrate distribution, formation, and stability. In February 2009, the workshop, Developing Long Term International Collaboration on Methane Hydrate Research and Monitoring in the Arctic Region, organized by J. Greinert (NIOZ), R. Coffin (NRL), I. Pecher (Harriot-Watt Univ.), T. Treude (IFM-GEOMAR) and N. Langhorne (ONR-Global), was successful in initiating collaborative international methane hydrate research off the coasts of Russia and Norway.
About the U.S. Naval Research Laboratory
The U.S. Naval Research Laboratory is the Navy's full-spectrum corporate laboratory, conducting a broadly based multidisciplinary program of scientific research and advanced technological development. The Laboratory, with a total complement of approximately 2,500 personnel, is located in southwest Washington, D.C., with other major sites at the Stennis Space Center, Miss., and Monterey, Calif. NRL has served the Navy and the nation for over 90 years and continues to meet the complex technological challenges of today's world. For more information, visit the NRL homepage or join the conversation on Twitter, Facebook, and YouTube.
Comment policy: We hope to receive submissions from all viewpoints, but we ask that all participants agree to the Department of Defense Social Media User Agreement. All comments are reviewed before being posted.