Seismic Imaging of a Shale Landscape Under Compression Shows Limited Influence of Topography-Induced Fracturing

Lisa Ma; David Oakley; Andrew Nyblade; Seulgi Moon; Natalie Accardo; Wei Wang; Xin Gu; Kristen Brubaker; Gregory J. Mount; Brandon Forsythe; Bradley J. Carr; Susan L. Brantley

doi:10.1029/2021GL093372

Seismic Imaging of a Shale Landscape Under Compression Shows Limited Influence of Topography-Induced Fracturing

Lisa Ma, David Oakley, Andrew Nyblade, Seulgi Moon, Natalie Accardo, Wei Wang, Xin Gu, Kristen Brubaker, Gregory J. Mount, Brandon Forsythe, Bradley J. Carr, Susan L. Brantley

Biogeochemical Dynamics

Research output: Contribution to journal › Article › peer-review

8 Scopus citations

Abstract

We used seismic refraction to image the P-wave velocity structure of a shale watershed experiencing regional compression in the Valley and Ridge Province (USA). From estimates showing strong compressional stress, we expected the depth to unweathered bedrock to mirror the hill-valley-hill topography (“bowtie pattern”) by analogy to seismic velocity patterns in crystalline bedrock in the North American Piedmont that also experience compression. Previous researchers used failure potentials calculated for strong compression in the Piedmont to suggest fractures are open deeper under hills than valleys to explain the “bowtie” pattern. Seismic images of the shale watershed, however, show little evidence of such a “bowtie.” Instead, they are consistent with weak (not strong) compression. This contradiction could be explained by the greater importance of infiltration-driven weathering than fracturing in determining seismic velocities in shale compared to crystalline bedrock, or to local perturbations of the regional stress field due to lithology or structures.

Original language	English
Article number	e2021GL093372
Journal	Geophysical Research Letters
Volume	48
Issue number	17
DOIs	https://doi.org/10.1029/2021GL093372
State	Published - Sep 16 2021

Funding

Funding is acknowledged from DOE OBES DE‐FG02‐05ER15675 and NSF EAR grants 12‐39285, 13‐31726 to S. L. Brantley and 19‐45431, 20‐12073 to S. Moon Shale Hills, part of Penn State's Stone Valley Forest, is facilitated by the College of Agricultural Sciences and Department of Ecosystem Science and Management. C. Cole, J. Grant, K. Lutz, and J. Renzaglia helped with P‐wave‐arrival picking. We thank Mon‐Han Huang and Roy Johnson for helpful reviews. Funding is acknowledged from DOE OBES DE-FG02-05ER15675 and NSF EAR grants 12-39285, 13-31726 to S. L. Brantley and 19-45431, 20-12073 to S. Moon Shale Hills, part of Penn State's Stone Valley Forest, is facilitated by the College of Agricultural Sciences and Department of Ecosystem Science and Management. C. Cole, J. Grant, K. Lutz, and J. Renzaglia helped with P-wave-arrival picking. We thank Mon-Han Huang and Roy Johnson for helpful reviews.

Keywords

fracturing
groundwater
headwater catchment
shale
topography
weathering

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10.1029/2021GL093372

Cite this

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title = "Seismic Imaging of a Shale Landscape Under Compression Shows Limited Influence of Topography-Induced Fracturing",

abstract = "We used seismic refraction to image the P-wave velocity structure of a shale watershed experiencing regional compression in the Valley and Ridge Province (USA). From estimates showing strong compressional stress, we expected the depth to unweathered bedrock to mirror the hill-valley-hill topography (“bowtie pattern”) by analogy to seismic velocity patterns in crystalline bedrock in the North American Piedmont that also experience compression. Previous researchers used failure potentials calculated for strong compression in the Piedmont to suggest fractures are open deeper under hills than valleys to explain the “bowtie” pattern. Seismic images of the shale watershed, however, show little evidence of such a “bowtie.” Instead, they are consistent with weak (not strong) compression. This contradiction could be explained by the greater importance of infiltration-driven weathering than fracturing in determining seismic velocities in shale compared to crystalline bedrock, or to local perturbations of the regional stress field due to lithology or structures.",

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author = "Lisa Ma and David Oakley and Andrew Nyblade and Seulgi Moon and Natalie Accardo and Wei Wang and Xin Gu and Kristen Brubaker and Mount, {Gregory J.} and Brandon Forsythe and Carr, {Bradley J.} and Brantley, {Susan L.}",

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AU - Accardo, Natalie

AU - Wang, Wei

AU - Gu, Xin

AU - Brubaker, Kristen

AU - Mount, Gregory J.

AU - Forsythe, Brandon

AU - Carr, Bradley J.

AU - Brantley, Susan L.

PY - 2021/9/16

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N2 - We used seismic refraction to image the P-wave velocity structure of a shale watershed experiencing regional compression in the Valley and Ridge Province (USA). From estimates showing strong compressional stress, we expected the depth to unweathered bedrock to mirror the hill-valley-hill topography (“bowtie pattern”) by analogy to seismic velocity patterns in crystalline bedrock in the North American Piedmont that also experience compression. Previous researchers used failure potentials calculated for strong compression in the Piedmont to suggest fractures are open deeper under hills than valleys to explain the “bowtie” pattern. Seismic images of the shale watershed, however, show little evidence of such a “bowtie.” Instead, they are consistent with weak (not strong) compression. This contradiction could be explained by the greater importance of infiltration-driven weathering than fracturing in determining seismic velocities in shale compared to crystalline bedrock, or to local perturbations of the regional stress field due to lithology or structures.

AB - We used seismic refraction to image the P-wave velocity structure of a shale watershed experiencing regional compression in the Valley and Ridge Province (USA). From estimates showing strong compressional stress, we expected the depth to unweathered bedrock to mirror the hill-valley-hill topography (“bowtie pattern”) by analogy to seismic velocity patterns in crystalline bedrock in the North American Piedmont that also experience compression. Previous researchers used failure potentials calculated for strong compression in the Piedmont to suggest fractures are open deeper under hills than valleys to explain the “bowtie” pattern. Seismic images of the shale watershed, however, show little evidence of such a “bowtie.” Instead, they are consistent with weak (not strong) compression. This contradiction could be explained by the greater importance of infiltration-driven weathering than fracturing in determining seismic velocities in shale compared to crystalline bedrock, or to local perturbations of the regional stress field due to lithology or structures.

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Seismic Imaging of a Shale Landscape Under Compression Shows Limited Influence of Topography-Induced Fracturing

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