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Workshop on Integrating Modeling and USGS Laboratory Studies of Gas Hydrates
On August 2-3, the U.S. Geological Survey (USGS) hosted a workshop in Denver, CO, to determine how its gas-hydrate laboratory studies could be more closely aligned with a growing number of modeling studies that simulate gas hydrates within geologic and petroleum systems. This strategic focus on specific models is a response to several gas-hydrate-related computer-modeling codes currently being used in the hydrate community (for example, TOUGH-Fx/hydrate from Lawrence Berkeley National Laboratory; CGM STARS from commercial hydrocarbon exploration; MH21 from the University of Tokyo, Japan; and STOMP-HYD from the Pacific Northwest National Laboratory). The workshop was intended not to suggest that laboratory results are relevant only to constraining or validating these types of models, but rather to identify those key parameters that USGS laboratory experiments could provide to help further our understanding of gas hydrates in the natural environment. The workshop was convened by USGS scientists Debbie Hutchinson (Coastal and Marine Geology, Woods Hole, MA) and Tim Collett (Energy Resources, Denver). Twenty-nine scientists representing the USGS, the Geological Survey of Canada, the U.S. National Laboratories, industry, academia, the U.S. Department of Energy (DOE), and the Minerals Management Service (MMS) participated in the meeting. Covering a broad range of expertise, they included laboratory experimentalists, numerical modelers, field scientists, and Federal research managers. The day-and-a-half meeting began with a day of presentations and discussions about modeling approaches, laboratory knowledge, and how laboratory and modeling studies are linked. Here is a sampling of some of the key themes that emerged from these indepth discussions:
The last half-day of the workshop involved brainstorming and synthesis, in which all participants identified the five highest-priority hydrate-research topics they felt were required to advance laboratory, field, and modeling studies, within the context of understanding the natural gas-hydrate system. The priorities generally followed the major themes summarized above. Of particular note is that the primary knowledge gap that repeatedly arose was in characterizing transport and transient phenomena in the gas-hydrate system. The nature of this gap shows that, in the 45 years since gas hydrates have been recognized in the natural environment, the study of natural gas hydrates has finally matured from characterizing the simple, static situation (that is, how to identify and characterize gas hydrates in the Earth) to understanding the time-dependent processes that control their formation and dissociation. A better understanding of these transport and transient phenomena will go a long way toward clarifying and refining the role of gas hydrates as a potential future energy resource, as a hazard within the shallow sea floor, and as an agent of climate change.
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in this issue:
Coastal Impacts of Hurricane Katrina Hydrologic Impacts of Hurricane Dennis ATRIS Used to Survey Sea Floor in Dry Tortugas National Park Using Genetic Modeling to Assess the Health and Status of Manatee Populations USGS Activities Rock the Waquoit Bay Watershed Block Party Balancing Wildlife Needs and Wetland Restoration in San Francisco Bay Journalism Interns Help Get the USGS Word Out 2005 Meeting of the Digital Library for Earth System Education Workshop on Integrating Modeling and Laboratory Gas Hydrate Studies Steven Schwarzbach Appointed Director of USGS Western Ecological Research Center |