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Shear-wave anisotropy reveals pore fluid pressure–induced seismicity in the U.S. midcontinent
Nolte, Keith Alexander ; Tsoflias, Georgios P. ; Bidgoli, Tandis S. ; Watney, W. Lynn
Nolte, Keith Alexander
Tsoflias, Georgios P.
Bidgoli, Tandis S.
Watney, W. Lynn
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Abstract
Seismicity in the U.S. midcontinent has increased by orders of magnitude over the past decade. Spatiotemporal correlations of seismicity to wastewater injection operations have suggested that injection-related pore fluid pressure increases are inducing the earthquakes. We present direct evidence linking earthquake occurrence to pore pressure increase in the U.S. midcontinent through time-lapse shear-wave (S-wave) anisotropy analysis. Since the onset of the observation period in 2010, the orientation of the fast S-wave polarization has flipped from inline with the maximum horizontal stress to inline with the minimum horizontal stress, a change known to be associated with critical pore pressure buildup. The time delay between fast and slow S-wave arrivals exhibits increased variance through time, which is common in critical pore fluid settings. Near-basement borehole fluid pressure measurements indicate pore pressure increase in the region over the earthquake monitoring period.
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2017-12-13
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American Association for the Advancement of Science
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Nolte, K. A., Tsoflias, G. P., Bidgoli, T. S., & Watney, W. L. (2017). Shear-wave anisotropy reveals pore fluid pressure–induced seismicity in the US midcontinent. Science advances, 3(12), e1700443.