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Constraining Microfractures in Foliated Alpine Fault Rocks With Laser Ultrasonics
Author(s) -
Simpson Jonathan,
Adam Ludmila,
Wijk Kasper,
Charoensawan Jirapat
Publication year - 2020
Publication title -
geophysical research letters
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 2.007
H-Index - 273
eISSN - 1944-8007
pISSN - 0094-8276
DOI - 10.1029/2020gl087378
Subject(s) - geology , anisotropy , seismic anisotropy , fault (geology) , slip (aerodynamics) , mineralogy , porosity , geomechanics , seismology , orientation (vector space) , geophysics , geotechnical engineering , geometry , optics , physics , mantle (geology) , thermodynamics , mathematics
Quantifying the amount and alignment of microfractures is important to understand the geomechanics, fluid flow, and seismic imaging of fault zones. At the Alpine Fault, New Zealand, the preferred alignment of minerals, foliation, and fractures results in elastic wave anisotropy. We have designed a unique laser‐ultrasonic laboratory setup to study Alpine Fault rock samples at upper crustal conditions. Combined with differential effective medium modeling, we distinguish microfracture porosity and orientation from mineral alignment, as a function of distance to the principal slip zone (PSZ). Nearest to the PSZ, the cataclasite has the lowest P wave anisotropy with the most (randomly oriented) fractures. Next, the ultramylonite exhibits the greatest P wave anisotropy (∼45%) with 40% of its fractures aligned with foliation. Further from the PSZ, P wave anisotropy is 14–19% on average, due to 20–30% of the fractures being oriented in the same direction as mineral alignment.