AGI Home | About AGIContact UsSearch 

Printable Version

Methane Hydrate Research and Development (6-9-04)

Methane hydrates, a frozen mixture of methane and water, have gained notice as a possible energy source and a potential hazard. Scientists have known of gas hydrates since the early 1800's from experiments with water gas mixtures, but naturally forming methane hydrates were not discovered until the 1960's when scientists and engineers working on the Siberian gas field Messoyakha discovered naturally forming "solid natural gas" -- methane hydrate -- in the subsurface sediments. This finding, plus an additional discovery on Alaska's North Slope, led geologists to search for other methane hydrate deposits around the world. During the 1990's, the enormous potential of methane hydrates was realized as estimates of reserves averaged around 200 million trillion cubic feet in the U.S., compared with 1400 trillion cubic feet of other sources of natural gas. Federal efforts to lead and support research and development of methane hydrates resulted in the Methane Hydrate Research and Development Act of 2000. Under the Act, the Department of Energy is coordinating a national effort of industry and federal agencies to understand the role of methane hydrates in the environment, explore possible solutions to methane hydrate hazards, and determine their potential as an energy source.

Most Recent Action

During the Republican-sponsored "Energy Week" in the House of Representatives, House Resources Committee Chairman Richard Pombo (R-CA) introduced H.R. 4515, which would provide energy companies incentives to produce natural gas from methane hydrate resources in certain areas. The U.S. Commission on Ocean Policy has estimated that the world's methane gas hydrate accumulations contain significantly more gas than all other conventional natural gas resources combined. These accumulations of densely packed gases inside a crystal structure occur in Arctic regions and in deep sea sediments. The technology to exploit this resource has not been developed, although the bill provides incentive for companies that develop technologies and begin extraction before the year 2018. The bill has been referred to the House Energy and Minerals Subcommittee. (6/9/04)

Previous Action

On January 24, 2003, the Houston Business Journal reported that Anadarko, Noble Drilling Corp., and Mauer Technology Inc., will soon begin drilling the permafrost on Alaska's North Slope for samples of methane hydrate. The companies plan to collect methane hydrate in its solid state and then transfer the samples at the surface to Anadarko's mobile Arctic core laboratory for further study. The companies are partaking in a three-year study, partially sponsored by the Department of Energy, to determine if methane hydrates located in permafrost could be a viable energy source. The Journal reports that Brad Tomer, an official of the National Energy Technology Laboratory, believes this project and others will show that commercial production of methane hydrates can become a reality in the next 10 years.

On February 19, 2003, ChevronTexaco identified possible hydrate locations in the Gulf of Mexico using three-dimensional seismic data. Two of the sites -- Atwater Block 14 and Keathley Canyon Block 195 -- were selected for further modeling and analysis, and possibly drilling. The project, co-sposered by the Department of Energy's National Energy Technology Laboratory is aimed at improving the understanding of safety hazards from hydrate-rich sediments in the Gulf of Mexico.

On April 11, 2003, the Department of Energy (DOE) announced that Anadarko had completed drilling of methane hydrate from the permafrost of Alaska's North Slope. Anadarko and two of its subsidiaries -- Noble Drilling Corp. and Mauer Technology -- are participating in an investigation to determine if the extraction of methane from hydrates in permafrost can be commercially viable. DOE is partially funding the research. According to Greenwire, the first tests on the recovered methane hydrate should be completed by the end of the month, with preliminary results expected in the fall. (5/20/03)


At standard temperatures and pressures, methane -- the main component of natural gas -- is a gaseous hydrocarbon. Under conditions of relatively high pressure and low temperature, such as those on the continental slope and in permafrost areas, methane is found as a crystalline solid encased within an ice-cage matrix -- a substance called methane hydrate. When liberated from this condensed structure, the volume of methane gas is 160 times greater than that of the hydrate form, making it an enormous resource potential. Estimates on the amount of methane hydrates contained on and offshore of the U.S. vary widely, but it is expected that if 1 percent of methane hydrate deposits were technically and economically recoverable, the U.S. could more than double its domestic natural gas resource base. Also, a 50 by 150 kilometer area off the coast of North and South Carolina might contain enough methane to meet U.S. demand for the next 70 years.

After their discovery in nature in the 1960's, hydrates were mostly viewed as an academic curiosity. But as oil and gas production moved into deeper waters, interest shifted to hydrates not only as a possible resource, but also as a potential hazard. As hydrate crystals often cement otherwise unconsolidated sands, their destabilization has been responsible for the disappearance of whole rigs from the induced liquefaction of sediment into which they were secured. Also, methane hydrates have caused massive submarine landslides. The release of large quantities of methane, a greenhouse gas ten times more effective than water vapor and carbon dioxide, also has environmental implications. The large-scale release of methane from hydrates has been invoked as a means to explain some periods of climate warming since the Last Glacial Maximum, when sea-level changes moved methane hydrates on the sea floor out of a field of stable pressure.

A hydrate-containing drill core recovered on a 1981 National Science Foundation-sponsored drilling program led to federal efforts to further study methane hydrates. From 1982 to 1992 the Department of Energy (DOE) spent approximately $8 million on investigations seeking to build a basic scientific foundation on the properties and locations of methane hydrates. The studies ceased as R&D priorities shifted to near-term and immediate exploration and production.

In hopes of curbing CO2 emission, the President's Committee of Advisors on Science and Technology recommended in a 1997 report that DOE begin a major initiative to establish a collaborative multi-agency and industry group to evaluate the production potential of methane hydrates in U.S. coastal waters and worldwide. Subsequently, DOE once again began providing resources to gas hydrate R&D programs. In 1998, two workshops under the coordination of the DOE lead to the report A Strategy for Methane Hydrate Research and Development, which was followed by the 1999 National Methane Hydrate Multi-year R&D Program Plan.

Despite the renewed interest and increased support, the complicated issues and technical challenges surrounding methane hydrate exploitation resulted in duplicate efforts and delayed results. Consequently, the Methane Hydrate Research and Development Act of 2000, which placed the 1997 recommendations into law, established the DOE as the lead agency in forming a nationally coordinated research program. The resulting National Methane Hydrate R&D Program awards grants and contracts through a competitive merit-based process. The program is led by the DOE but also includes the U.S. Naval Research Laboratory, the Minerals Management Service, the U.S. Geological Survey, the National Oceanic and Atmospheric Association, and the National Science Foundation. Current research efforts are focused on mitigating potential hazards that hydrates pose to ongoing deep-water oil and gas drilling, determining if there is a possible role for hydrates in the nation's long-term energy needs, and re-evaluating the current understanding of natural processes -- such as global climate change and evolution of the sea floor -- that may influence future policies. Progress of the research program will be evaluated by the National Research Council by September 30, 2004.

For additional information on methane hydrates and current research, see the DOE's National Energy Technology Laboratory web site and AGI's Update on Methane Hydrate Research and Development Act from the 106th Congress.

Sources: National Energy Technology Laboratory, Greenwire, Thomas, Library of Congress.

Contributed by Charna Meth, 2003 Spring Semester Intern; and Bridget Martin, 2004 AGI/AIPG Summer Intern.
Background section includes material from AGI's Update on Methane Hydrate Research and Development Act for the 106th Congress.

Please send any comments or requests for information to AGI Government Affairs Program.

Last updated on June 9, 2004

  Information Services |Geoscience Education |Public Policy |Environmental
Publications |Workforce |AGI Events

agi logo

© 2016. All rights reserved.
American Geosciences Institute, 4220 King Street, Alexandria, VA 22302-1502.
Please send any comments or problems with this site to:
Privacy Policy