Study of a prehistoric landslide using seismic reflection methods integrated with geological data in the Wasatch Mountains, Utah, USA

Study of a prehistoric landslide using seismic reflection methods integrated with geological data in the Wasatch Mountains, Utah, USA

An integration of geological and geophysical techniques characterizes the internal and basal structure of a landslide along the western margin of the Wasatch Mountains in northern Utah, USA. The study area is within a region of planned and continuing residential development. The Little Valley Landsl...

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Bibliographic Details
Published in:Engineering geology Vol. 95; no. 1; pp. 1 - 29
Main Authors: Tingey, Brady E., McBride, John H., Thompson, Timothy J., Stephenson, William J., South, John V., Bushman, Michelle
Format: Journal Article
Language:English
Published: Amsterdam Elsevier B.V 22-11-2007
Elsevier
Subjects:
Ancient landslide
Applied sciences
Buildings. Public works
Earth sciences
Earth, ocean, space
Engineering and environment geology. Geothermics
Exact sciences and technology
Geologic mapping
Geophysics
Geotechnics
Natural hazards: prediction, damages, etc
Soil mechanics. Rocks mechanics
United States
North America
Utah
America
Geologic mapping
Ancient landslide
Geophysics
Cartography
Trench
Data analysis
Integration
Age estimation
Geology
Seismic reflection methods
Borehole
Prehistory
Topography
Landslide
Method study
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Summary:An integration of geological and geophysical techniques characterizes the internal and basal structure of a landslide along the western margin of the Wasatch Mountains in northern Utah, USA. The study area is within a region of planned and continuing residential development. The Little Valley Landslide is a prehistoric landslide as old as 13 ka B.P. Drilling and trenching at the site indicate that the landslide consists of chaotic and disturbed weathered volcanic material derived from Tertiary age volcanic rocks that comprise a great portion of the Wasatch Range. Five short high-resolution common mid-point seismic reflection profiles over selected portions of the site examine the feasibility of using seismic reflection to study prehistoric landslides in the Wasatch Mountain region. Due to the expected complexity of the near-surface geology, we have pursued an experimental approach in the data processing, examining the effects of muting first arrivals, frequency filtering, model-based static corrections, and seismic migration. The results provide a framework for understanding the overall configuration of the landslide, its basal (failure) surface, and the structure immediately underlying this surface. A glide surface or décollement is interpreted to underlie the landslide suggesting a large mass movement. The interpretation of a glide surface is based on the onset of coherent reflectivity, calibrated by information from a borehole located along one of the seismic profiles. The glide surface is deepest in the center portion of the landslide and shallows up slope, suggesting a trough-like feature. This study shows that seismic reflection techniques can be successfully used in complex alpine landslide regions to (1) provide a framework in which to link geological data and (2) reduce the need for an extensive trenching and drilling program.
ISSN:0013-7952
1872-6917
DOI:10.1016/j.enggeo.2007.08.006