P-wave anisotropy of mylonitic and infrastructural rocks from a Cordilleran core complex: the Ruby-East Humboldt Range, Nevada

In order to evaluate the possibility that compressional-wave anisotropy might characterize the upper to middle crust of the North American Cordillera, we examined the nature and degree of seismic anisotropy of rock samples collected from the mylonite zone and underlying infrastructure of the Ruby-Ea...

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Bibliographic Details
Published inPhysics of the earth and planetary interiors Vol. 78; no. 3; pp. 319 - 336
Main Authors McDonough, Daniel T., Fountain, David M.
Format Journal Article Conference Proceeding
LanguageEnglish
Published Lausanne Elsevier B.V 01.07.1993
Amsterdam Elsevier Science
New York, NY
Subjects
Earth sciences
Earth, ocean, space
Earthquakes, seismology
Exact sciences and technology
Internal geophysics
Western U.S
Montana
United States
North America
Nevada
petrofabrics
Cordillera
mylonites
anisotropy
Ruby Range
feldspar
P-waves
elastic waves
amphibolite facies
preferred orientation
metamorphic rocks
quartzites
upper crust
grade
temperature
amphibolites
polarization
Delay time
facies
rubies
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Summary:In order to evaluate the possibility that compressional-wave anisotropy might characterize the upper to middle crust of the North American Cordillera, we examined the nature and degree of seismic anisotropy of rock samples collected from the mylonite zone and underlying infrastructure of the Ruby-East Humboldt metamorphic core complex in northeastern Nevada. Seismic anisotropy in quartzofeldspathic rocks from all structural levels is low and generally related to the volume of mica relative to feldspar. Upper amphibolite facies infrastructure quartzite has a stronger and different quartz crystallographic preferred orientation (CPO) and, thus, higher seismic anisotropy than the lower grade mylonitic quartzites, a feature related to the higher temperature deformation conditions that characterized the infrastructure. Schistose mylonite zone rocks, as a group, have the highest anisotropy. We infer that this is, in large part, due to mica CPO although the anisotropy patterns suggest that quartz CPO may be a factor. Anisotropy is higher in infrastructural quartzites, calc-silicates, and marbles than in mylonite-zone equivalents. Seismic anisotropy data for other Cordilleran core complex samples suggest that these patterns are common characteristics of Cordilleran core complex rocks.
ISSN:0031-9201
1872-7395
DOI:10.1016/0031-9201(93)90163-4