Nagihara, Seiichi and Wang, Kelin (2000): Geothermal regime of the western margin of the Great Bahama Bank

Leg/Site/Hole:
ODP 166
ODP 166 1003
ODP 166 1004
ODP 166 1005
ODP 166 1006
ODP 166 1007
Identifier:
2001-002889
georefid

10.2973/odp.proc.sr.166.123.2000
doi

Creator:
Nagihara, Seiichi
University of Houston, Department of Geosciences, Houston, TX, United States
author

Wang, Kelin
Ocean Drilling Program, United States
author

Identification:
Geothermal regime of the western margin of the Great Bahama Bank
2000
In: Swart, Peter K., Eberli, Gregor P., Malone, Mitchell J., Anselmetti, Flavio S., Arai, Kohsaku, Bernet, Karin H., Betzler, Christian, Christensen, Beth A., De Carlo, Eric Heinen, Dejardin, Pascale M., Emmanuel, Laurent, Frank, Tracy D., Haddad, Geoffrey A., Isern, Alexandra R., Katz, Miriam E., Kenter, Jeroen A. M., Kramer, Philip A., Kroon, Dick, McKenzie, Judith A., McNeill, Donald F., Montgomery, Paul, Nagihara, Seiichi, Pirmez, Carlos, Reijmer, John J. G., Sato, Tokiyuki, Schovsbo, Niels H., Williams, Trevor, Wright, James D., Lowe, Ginny (editor), Proceedings of the Ocean Drilling Program, scientific results, Bahamas Transect; covering Leg 166 of the cruises of the drilling vessel JOIDES Resolution, San Juan, Puerto Rico, to Balboa Harbor, Panama, sites 1003-1009, 17 February-10 April 1996
Texas A & M University, Ocean Drilling Program, College Station, TX, United States
166
113-120
The geothermal regime of the western margin of the Great Bahama Bank was examined using the bottom hole temperature and thermal conductivity measurements obtained during and after Ocean Drilling Program (ODP) Leg 166. This study focuses on the data from the drilling transect of Sites 1003 through 1007. These data reveal two important observational characteristics. First, temperature vs. cumulative thermal resistance profiles from all the drill sites show significant curvature in the depth range of 40 to 100 mbsf. They tend to be of concave-upward shape. Second, the conductive background heat-flow values for these five drill sites, determined from deep, linear parts of the geothermal profiles, show a systematic variation along the drilling transect. Heat flow is 43-45 mW/m (super 2) on the seafloor away from the bank and decreases upslope to approximately 35 mW/m (super 2) . We examine three mechanisms as potential causes for the curved geothermal profiles. They are: (1) a recent increase in sedimentation rate, (2) influx of seawater into shallow sediments, and (3) temporal fluctuation of the bottom water temperature (BWT). Our analysis shows that the first mechanism is negligible. The second mechanism may explain the data from Sites 1004 and 1005. The temperature profile of Site 1006 is most easily explained by the third mechanism. We reconstruct the history of BWT at this site by solving the inverse heat conduction problem. The inversion result indicates gradual warming throughout this century by approximately 1 degrees C and is agreeable to other hydrographic and climatic data from the western subtropic Atlantic. However, data from Sites 1003 and 1007 do not seem to show such trends. Therefore, none of the three mechanisms tested here explain the observations from all the drill sites. As for the lateral variation of the background heat flow along the drill transect, we believe that much of it is caused by the thermal effect of the topographic variation. We model this effect by obtaining a two-dimensional analytical solution. The model suggests that the background heat flow of this area is approximately 43 mW/m (super 2) , a value similar to the background heat flow determined for the Gulf of Mexico in the opposite side of the Florida carbonate platform.
Coverage:Geographic coordinates:
North:25.0000
West:-79.4500East: -79.0000
South:23.0000

Oceanography; Atlantic Ocean; bottom water; carbonate platforms; Caribbean Sea; Great Bahama Bank; heat flow; Leg 166; North Atlantic; Ocean Drilling Program; ocean floors; ODP Site 1003; ODP Site 1004; ODP Site 1005; ODP Site 1006; ODP Site 1007; sea water; temperature; temperature logging; thermal conductivity; thermal regime; well-logging;

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