Four Critical Needs to Change the Hydrate Energy Paradigm from Assessment to Production: The 2007 Report to Congress by the U.S. Federal methane Hydrate Advisory Committee

This work summarizes a two-year study by the U.S. Federal Methane Hydrate Advisory Committee recommending the future needs for federally-supported hydrate research. The Report was submitted to the US Congress on August 14, 2007 and includes four recommendations regarding (a) permafrost hydrate produ...

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Bibliographic Details
Main Authors: Mahajan,D., Sloan, D., Brewer, P., Dutta, N., Johnson, A., Jones, E., Juenger, K., Kastner, M., Masutani, S., Swenson, R., Whelan, J., Wilson, s., Woolsey, R.
Other Authors: United States. Department of Energy.
Format: Article in Journal/Newspaper
Language:English
Published: Brookhaven National Laboratory 2009
Subjects:
International Cooperation
Fuel Oils
Hydrates
Gas Hydrates
Testing
Electric Power
Natural Gas
Coal
01 Coal
Lignite
And Peat
Methane
03 Natural Gas
Fossil Fuels
Permafrost
02 Petroleum
Greenhouse Effect
Climates
Market
Viability
29 Energy Planning
Policy And Economy
Liquefied Natural Gas
Advisory Committees
Energy Policy
Methane hydrate
permafrost
Online Access:http://digital.library.unt.edu/ark:/67531/metadc929376/
Description
Summary:This work summarizes a two-year study by the U.S. Federal Methane Hydrate Advisory Committee recommending the future needs for federally-supported hydrate research. The Report was submitted to the US Congress on August 14, 2007 and includes four recommendations regarding (a) permafrost hydrate production testing, (b) marine hydrate viability assessment (c) climate effect of hydrates, and (d) international cooperation. A secure supply of natural gas is a vital goal of the U.S. national energy policy because natural gas is the cleanest and most widely used of all fossil fuels. The inherent cleanliness of natural gas, with the lowest CO2 emission per unit of heat energy of any fossil fuel, means substituting gas for coal and fuel oil will reduce emissions that can exacerbate the greenhouse effect. Both a fuel and a feedstock, a secure and reasonably priced supply of natural gas is important to industry, electric power generators, large and small commercial enterprises, and homeowners. Because each volume of solid gas hydrate contains as much as 164 standard volumes of methane, hydrates can be viewed as a concentrated form of natural gas equivalent to compressed gas but less concentrated than liquefied natural gas (LNG). Natural hydrate accumulations worldwide are estimated to contain 700,000 TCF of natural gas, of which 200,000 TCF are located within the United States. Compared with the current national annual consumption of 22 TCF, this estimate of in-place gas in enormous. Clearly, if only a fraction of the hydrated methane is recoverable, hydrates could constitute a substantial component of the future energy portfolio of the Nation (Figure 1). However, recovery poses a major technical and commercial challenge. Such numbers have sparked interest in natural gas hydrates as a potential, long-term source of energy, as well as concerns about any potential impact the release of methane from hydrates might have on the environment. Energy-hungry countries such as India and Japan are outspending the United States on hydrate science and engineering R&D by a factor of 10, and may bring this resource to market as much as a decade before the United States.

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