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NARROW
GeoRef Subject
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all geography including DSDP/ODP Sites and Legs
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Canada
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Primary terms
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A New Approach to Predict Hydrogeological Parameters Using Shear Waves from the Multichannel Analysis of Surface Waves Method
Identification of gas hydrates and bottom-simulating reflectors in far-offset seismic images
A unified effective medium model for gas hydrates in sediments
New constraints on buried Triassic basins and regional implications for subsurface CO 2 storage from the SeisData6 seismic profile across the Southeast Georgia coastal plain
Preserved extent of Jurassic flood basalt in the South Georgia Rift: A new interpretation of the J horizon
Mantle earthquakes in the absence of subduction? Continental delamination in the Romanian Carpathians
Structural and stratigraphic control on the migration of a contaminant plume at the P Reactor area, Savannah River site, South Carolina
Empirical Mode Decomposition Operator for Dewowing GPR Data
Improved Hydrogeophysical Parameter Estimation from Empirical Mode Decomposition Processed Ground Penetrating Radar Data
Developing a robust geologic conceptual model using pseudo 3-D P-wave seismic reflection data
Natural Gas Hydrates: A Review
Abstract A strong upward trend exists for the consumption of all energy sources as people throughout the world strive for a higher standard of living. Someday, possibly soon, the earth's store of easily accessed hydrocarbons will no longer satisfy our growing economies and populations. By then, an unfamiliar but kindred hydrocarbon resource called natural gas hydrate may become a significant source of energy. Approximately 35 years ago, Russian scientists made what was then a bold assertion that gas hydrates, a crystalline solid of water and natural gas and a historical curiosity to physical chemists, should occur in abundance in the natural environment. Since this early start, the scientific foundation has been built for the realization that gas hydrates are a global phenomenon, occurring in permafrost regions of the arctic and in deep-water parts of most continental margins worldwide. The amount of natural gas contained in the world's gas-hydrate accumulations is enormous, but these estimates remain highly speculative. Researchers have long speculated that gas hydrates could eventually be a commercial producible energy resource, yet technical and economic hurdles have historically made gas-hydrate development a distant goal instead of a near-term possibility. This view began to change in recent years with the realization that this unconventional resource could possibly be developed with the existing conventional oil and gas production technology. The pace of gas-hydrate energy assessment projects has significantly accelerated over the past several years, but many critical gas-hydrate exploration and development questions still remain. The exploitation and potential development of gas-hydrate resources is a complex technological problem. However, humans have successfully dealt with such complicated problems in the past to satisf your energy needs; technical innovations have been key to our historical successes.