OS23C-2030
Advective and Conductive Heat Flow Budget Across the Wagner Basin, Northern Gulf of California
Tuesday, 15 December 2015
Poster Hall (Moscone South)
Florian Neumann1, Raquel Negrete-Aranda1, Juan Contreras1, Christian Müller2, Michael Hutnak3, Antonio Gonzalez-Fernandez1, Robert N Harris4 and John G Sclater5, (1)CICESE National Center for Scientific Research and Higher Education of Mexico, Geology, Ensenada, Mexico, (2)FIELAX GmbH, Bremerhaven, Germany, (3)University of California Santa Cruz, Earth and Planetary Science, Santa Cruz, CA, United States, (4)Oregon State University, Collage of Earth, Oceanic and Atmospheric Sciences, Corvallis, OR, United States, (5)Scripps Institution of Oceanography, La Jolla, CA, United States
Abstract:
In May 2015, we conducted a cruise across the northern Gulf of California, an area of continental rift basin formation and rapid deposition of sediments. The cruise was undertaken aboard the R/V Alpha Helix; our goal was to study variation in superficial conductive heat flow, lateral changes in the shallow thermal conductivity structure, and advective transport of heat across the Wagner basin. We used a Fielax heat flow probe with 22 thermistors that can penetrate up to 6 m into the sediment cover. The resulting data set includes 53 new heat flow measurements collected along three profiles. The longest profile (42 km) contains 30 measurements spaced 1-2 km apart. The western part of the Wagner basin (hanging wall block) exhibit low to normal conductive heat flow whereas the eastern part of the basin (foot wall block) heat flow is high to very high (up to 2500 mWm-2). Two other short profiles (12 km long each) focused on resolving an extremely high heat flow anomaly up to 15 Wm-2 located near the intersection between the Wagner bounding fault system and the Cerro Prieto fault. We hypothesize that the contrasting heat flow values observed across the Wagner basin are due to horizontal water circulation through sand layers and fault pathways of high permeability. Circulation appears to be from west (recharge zone) to east (discharge zone). Additionally, our results reveal strong vertical advection of heat due to dehydration reactions and compaction of fine grained sediments.