About This Item

Share This Item

The AAPG/Datapages Combined Publications Database

AAPG Bulletin

Abstract

AAPG Bulletin, V. 88, No. 6 (June 2004), P. 725-746.

Copyright copy2004. The American Association of Petroleum Geologists. All rights reserved.

Side-scan sonar imaging of hydrocarbon seeps on the Louisiana continental slope

William W. Sager,1 Ian R. MacDonald,2 Rusheng Hou3

1Department of Oceanography, Texas AampM University, College Station, Texas, 77843; [email protected]
2Physical and Life Sciences Department, Texas AampM University, Corpus Christi, Texas, 78412
3Department of Geology amp Geophysics, Texas AampM University, College Station, Texas, 77843

AUTHORS

Will Sager is a professor in the Departments of Oceanography and Geology and Geophysics and is the holder of the Jane and R. Ken Williams lsquo45 Chair in Ocean Drilling Science, Technology, and Education at Texas AampM University. He received a Ph.D. in geology and geophysics at the University of Hawaii and has spent the last 20 years at Texas AampM teaching and researching marine geology and geophysics. Author of 75 refereed research papers, and advisor of 20 M.S. and Ph.D. graduates, he has participated in 36 oceanographic research cruises.

Ian R. MacDonald is a professor of environmental science at Texas AampM University, Corpus Christi. He received his Ph.D. from Texas AampM University in 1990. Author of over 30 peer-reviewed articles as well as numerous reports and popular articles, including articles in National Geographic and Scientific American, MacDonaldprimes research has entailed extensive use of such deep-diving submarines as Johnson Sea-Link, Alvin, and the Navy nuclear submarine NR-1. His particular interest is the application of advanced imaging technology to marine research.

Rusheng Hou received an M.S. degree in geology and geophysics from Texas AampM University in 2001. He also earned a B.S. degree from Qingdao University of Oceanography and an M.S. degree from the Chinese Academy of Science in Bejing. Currently, he is pursuing the study of computer science at the University of Texas at Dallas.

ACKNOWLEDGMENTS

We are greatly indebted to the many people who have helped us gather data over many years of cruises. In particular, we thank the captains and crews of the R/V Gyre, R/V Seward Johnson, R/V Edwin Link, Johnson Sea Link, and submarine NR-1. We also thank a major United States geophysical surveying company, who wishes to remain anonymous, for use of three-dimensional (3-D) multichannel seismic data and Seismic Micro Technologies, Inc., for providing 3-D multichannel seismic data analysis software (Kingdom Suite). This work was supported by contract nos. 14-35-0001-30555 and 14-35-0001-31813 to the Geochemical and Environmental Research Group by the Minerals Management Service, Gulf of Mexico Outer Continental Shelf Region Office, U.S. Department of the Interior.

ABSTRACT

Submarine hydrocarbon seeps are widespread in the northwestern Gulf of Mexico and give rise to unusual seafloor features that are commonly poorly defined because water depth limits the resolution afforded by sea-surface seismic profiles. Detailed seep images are possible with side-scan sonars because such devices use beam-formed high-frequency sound to give high spatial resolution. Furthermore, side-scan sonars are useful for mapping seeps because their sound waves respond to changes in near-seafloor sediment properties caused by seep activity. To examine seep sonar signatures, we used a broad-swath, sea-surface side-scan sonar to survey three areas of the Louisiana continental slope where seeps are known to occur. In sonar mosaics from upper-slope study sites, seep features are the main anomalous seafloor response and display high backscatter of sonar waves. The mosaics show fault traces, fault scarps, authigenic carbonate mounds, irregular patches of seep-affected seafloor, mud mounds and mud volcanoes, craters, and sediment flows. Most of these features are located along faults that control seepage. Cores from seep-affected areas imply that enhanced sonar backscatter results from a combination of the perturbation of seafloor sediment physical properties and the introduction of seep-produced foreign material, including gas, oil, carbonate nodules and fragments, and chemosynthetic organism debris. In the lower slope survey area, tectonic activity and resultant mass sediment movements make identification of seeps more difficult. In this area, many sonar backscatter anomalies appear to result from sediment flows and mass movements on the edges and bottoms of intrasalt basins. Basin walls appear as highly dissected, commonly showing crenulations and grooves, which were probably created by sediment failure and erosion by downslope sediment transport. Seeps are commonly difficult to discern because of the abundance of other anomalous features, but seem to be located mainly on basin walls and summits of salt highs.

Pay-Per-View Purchase Options

The article is available through a document delivery service. Explain these Purchase Options.

Watermarked PDF Document: $14
Open PDF Document: $24

AAPG Member?

Please login with your Member username and password.

Members of AAPG receive access to the full AAPG Bulletin Archives as part of their membership. For more information, contact the AAPG Membership Department at [email protected].