Characterizing the uppermost 100 m structure of the San Jacinto fault zone southeast of Anza, California, through joint analysis of geological, topographic, seismic and resistivity data

Pieter Ewald Share; Petr Tábořík; Petra Štěpančíková; Jakub Stemberk; Thomas K. Rockwell; Adam Wade; J. Ramon Arrowsmith; Andrea Donnellan; Frank L. Vernon; Yehuda Ben-Zion

doi:10.1093/gji/ggaa204

Characterizing the uppermost 100 m structure of the San Jacinto fault zone southeast of Anza, California, through joint analysis of geological, topographic, seismic and resistivity data

Pieter Ewald Share, Petr Tábořík, Petra Štěpančíková, Jakub Stemberk, Thomas K. Rockwell, Adam Wade, J. Ramon Arrowsmith, Andrea Donnellan, Frank L. Vernon, Yehuda Ben-Zion

Earth and Space Exploration, School of (SESE)

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

15 Scopus citations

Abstract

We present results from complementary geological, topographic, seismic and electrical resistivity surveys at the Sagebrush Flat (SGB) site along the Clark fault (CF) strand of the San Jacinto fault zone trifurcation area southeast of Anza, California. Joint interpretation of these data sets, each with unique spatiotemporal sensitivities, allow us to better characterize the shallow (<100 m) fault zone at this structurally complex site. Geological mapping at the surface shows the CF has three main subparallel strands within a <100 m zone with varying degrees of rock damage. These strands intersect units of banded gneiss and tonalite, and various sedimentary units. Near the surface, the weathered but more intact tonalite and gneiss to the southwest have relatively high V_P. The low-lying flat sedimentary basins around the two southwestern-most CF strands and elevated damaged gneiss to the northeast have lowest V_P <500 m s^-1. The high relief of the northeast gneiss unit may in part be explained by its extensive damage and inferred increased relative rock uplift. Resistivity imaging shows the unconsolidated dry basin sediments (maximum >1300 Ohm.m) contrasted against the compacted fine-grained (potentially wet) materials within the CF core and the Bautista Formation (minimum <40 Ohm.m), which is slightly elevated above the flat basins. The inverse relationship between V_P (increases) and resistivity (decreases) in the uppermost ∼15 m can be characterized as log-log linear with slopes of -2.6 to -4. At depths >30 m, the velocity heterogeneity near the surface merges into larger-scale structures that are generally slower on the northeast side of the CF core compared to the southwest side (as much as ∼40 per cent reduction in average V_P). A previous study revealed a 20-37 per cent variability in peak ground velocities across the SGB site from local earthquakes. The upper end of that range is associated with the near-surface unconsolidated sedimentary basins and northeast damaged gneiss unit. Preliminary analysis of time-dependent topography mostly shows effects of changing vegetation and anthropogenic activity.

Original language	English (US)
Pages (from-to)	781-794
Number of pages	14
Journal	Geophysical Journal International
Volume	222
Issue number	2
DOIs	https://doi.org/10.1093/gji/ggaa204
State	Published - May 13 2020

Keywords

Earthquake hazards
Electrical resistivity tomography (ERT)
Fractures, faults, and high strain deformation zones
Image processing
Seismic tomography
Structure of the Earth

ASJC Scopus subject areas

Geophysics
Geochemistry and Petrology

Access to Document

10.1093/gji/ggaa204

Cite this

Share, P. E., Tábořík, P., Štěpančíková, P., Stemberk, J., Rockwell, T. K., Wade, A., Arrowsmith, J. R., Donnellan, A., Vernon, F. L., & Ben-Zion, Y. (2020). Characterizing the uppermost 100 m structure of the San Jacinto fault zone southeast of Anza, California, through joint analysis of geological, topographic, seismic and resistivity data. Geophysical Journal International, 222(2), 781-794. https://doi.org/10.1093/gji/ggaa204

Characterizing the uppermost 100 m structure of the San Jacinto fault zone southeast of Anza, California, through joint analysis of geological, topographic, seismic and resistivity data. / Share, Pieter Ewald; Tábořík, Petr; Štěpančíková, Petra et al.
In: Geophysical Journal International, Vol. 222, No. 2, 13.05.2020, p. 781-794.

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

Share, PE, Tábořík, P, Štěpančíková, P, Stemberk, J, Rockwell, TK, Wade, A, Arrowsmith, JR, Donnellan, A, Vernon, FL & Ben-Zion, Y 2020, 'Characterizing the uppermost 100 m structure of the San Jacinto fault zone southeast of Anza, California, through joint analysis of geological, topographic, seismic and resistivity data', Geophysical Journal International, vol. 222, no. 2, pp. 781-794. https://doi.org/10.1093/gji/ggaa204

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title = "Characterizing the uppermost 100 m structure of the San Jacinto fault zone southeast of Anza, California, through joint analysis of geological, topographic, seismic and resistivity data",

abstract = "We present results from complementary geological, topographic, seismic and electrical resistivity surveys at the Sagebrush Flat (SGB) site along the Clark fault (CF) strand of the San Jacinto fault zone trifurcation area southeast of Anza, California. Joint interpretation of these data sets, each with unique spatiotemporal sensitivities, allow us to better characterize the shallow (<100 m) fault zone at this structurally complex site. Geological mapping at the surface shows the CF has three main subparallel strands within a <100 m zone with varying degrees of rock damage. These strands intersect units of banded gneiss and tonalite, and various sedimentary units. Near the surface, the weathered but more intact tonalite and gneiss to the southwest have relatively high VP. The low-lying flat sedimentary basins around the two southwestern-most CF strands and elevated damaged gneiss to the northeast have lowest VP <500 m s-1. The high relief of the northeast gneiss unit may in part be explained by its extensive damage and inferred increased relative rock uplift. Resistivity imaging shows the unconsolidated dry basin sediments (maximum >1300 Ohm.m) contrasted against the compacted fine-grained (potentially wet) materials within the CF core and the Bautista Formation (minimum <40 Ohm.m), which is slightly elevated above the flat basins. The inverse relationship between VP (increases) and resistivity (decreases) in the uppermost ∼15 m can be characterized as log-log linear with slopes of -2.6 to -4. At depths >30 m, the velocity heterogeneity near the surface merges into larger-scale structures that are generally slower on the northeast side of the CF core compared to the southwest side (as much as ∼40 per cent reduction in average VP). A previous study revealed a 20-37 per cent variability in peak ground velocities across the SGB site from local earthquakes. The upper end of that range is associated with the near-surface unconsolidated sedimentary basins and northeast damaged gneiss unit. Preliminary analysis of time-dependent topography mostly shows effects of changing vegetation and anthropogenic activity.",

keywords = "Earthquake hazards, Electrical resistivity tomography (ERT), Fractures, faults, and high strain deformation zones, Image processing, Seismic tomography, Structure of the Earth",

author = "Share, {Pieter Ewald} and Petr T{\'a}bo{\v r}{\'i}k and Petra {\v S}t{\v e}pan{\v c}{\'i}kov{\'a} and Jakub Stemberk and Rockwell, {Thomas K.} and Adam Wade and Arrowsmith, {J. Ramon} and Andrea Donnellan and Vernon, {Frank L.} and Yehuda Ben-Zion",

note = "Funding Information: We would first like to thank Bud Wellman and his family for allowing us to use the Sagebrush Flat field site over several years for this research. We also thank David Okaya for assistance with using the inversion code of Hole (1992). The studies were supported by the Department of Energy (awards DE-SC0016520 and DE-SC0016527), and the Jet Propulsion Laboratory, California Institute of Technology, under contract with NASA (NASA{\textquoteright}s Earth Surface and Interior Program). The geological and geomorphic analysis was partially supported by the Southern California Earthquake Center (SCEC) Award #17085 (SCEC is based on NSF Cooperative Agreement EAR-1600087 and USGS Cooperative Agreement G17AC00047) and by the Strategic University Research Partnership between the Jet Propulsion Laboratory, California Institute of Technology and Arizona State University. The resistivity imaging work was carried out with support of the long-term conceptual development research organization RVO: 67985891 and the Center for Geosphere Dynamics (UNCE/SCI/006). Most figures were created in MATLAB and using the Generic Mapping Tools (Wessel et al. 2013). The manuscript benefitted from constructive and useful comments by the editor Juan Carlos Afonso and reviewers Will Levandowski and Derrick Hasterock. Publisher Copyright: {\textcopyright} 2020 The Author(s) 2020. Published by Oxford University Press on behalf of The Royal Astronomical Society.",

year = "2020",

month = may,

day = "13",

doi = "10.1093/gji/ggaa204",

language = "English (US)",

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pages = "781--794",

journal = "Geophysical Journal International",

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TY - JOUR

T1 - Characterizing the uppermost 100 m structure of the San Jacinto fault zone southeast of Anza, California, through joint analysis of geological, topographic, seismic and resistivity data

AU - Share, Pieter Ewald

AU - Tábořík, Petr

AU - Štěpančíková, Petra

AU - Stemberk, Jakub

AU - Rockwell, Thomas K.

AU - Wade, Adam

AU - Arrowsmith, J. Ramon

AU - Donnellan, Andrea

AU - Vernon, Frank L.

AU - Ben-Zion, Yehuda

N1 - Funding Information: We would first like to thank Bud Wellman and his family for allowing us to use the Sagebrush Flat field site over several years for this research. We also thank David Okaya for assistance with using the inversion code of Hole (1992). The studies were supported by the Department of Energy (awards DE-SC0016520 and DE-SC0016527), and the Jet Propulsion Laboratory, California Institute of Technology, under contract with NASA (NASA’s Earth Surface and Interior Program). The geological and geomorphic analysis was partially supported by the Southern California Earthquake Center (SCEC) Award #17085 (SCEC is based on NSF Cooperative Agreement EAR-1600087 and USGS Cooperative Agreement G17AC00047) and by the Strategic University Research Partnership between the Jet Propulsion Laboratory, California Institute of Technology and Arizona State University. The resistivity imaging work was carried out with support of the long-term conceptual development research organization RVO: 67985891 and the Center for Geosphere Dynamics (UNCE/SCI/006). Most figures were created in MATLAB and using the Generic Mapping Tools (Wessel et al. 2013). The manuscript benefitted from constructive and useful comments by the editor Juan Carlos Afonso and reviewers Will Levandowski and Derrick Hasterock. Publisher Copyright: © 2020 The Author(s) 2020. Published by Oxford University Press on behalf of The Royal Astronomical Society.

PY - 2020/5/13

Y1 - 2020/5/13

N2 - We present results from complementary geological, topographic, seismic and electrical resistivity surveys at the Sagebrush Flat (SGB) site along the Clark fault (CF) strand of the San Jacinto fault zone trifurcation area southeast of Anza, California. Joint interpretation of these data sets, each with unique spatiotemporal sensitivities, allow us to better characterize the shallow (<100 m) fault zone at this structurally complex site. Geological mapping at the surface shows the CF has three main subparallel strands within a <100 m zone with varying degrees of rock damage. These strands intersect units of banded gneiss and tonalite, and various sedimentary units. Near the surface, the weathered but more intact tonalite and gneiss to the southwest have relatively high VP. The low-lying flat sedimentary basins around the two southwestern-most CF strands and elevated damaged gneiss to the northeast have lowest VP <500 m s-1. The high relief of the northeast gneiss unit may in part be explained by its extensive damage and inferred increased relative rock uplift. Resistivity imaging shows the unconsolidated dry basin sediments (maximum >1300 Ohm.m) contrasted against the compacted fine-grained (potentially wet) materials within the CF core and the Bautista Formation (minimum <40 Ohm.m), which is slightly elevated above the flat basins. The inverse relationship between VP (increases) and resistivity (decreases) in the uppermost ∼15 m can be characterized as log-log linear with slopes of -2.6 to -4. At depths >30 m, the velocity heterogeneity near the surface merges into larger-scale structures that are generally slower on the northeast side of the CF core compared to the southwest side (as much as ∼40 per cent reduction in average VP). A previous study revealed a 20-37 per cent variability in peak ground velocities across the SGB site from local earthquakes. The upper end of that range is associated with the near-surface unconsolidated sedimentary basins and northeast damaged gneiss unit. Preliminary analysis of time-dependent topography mostly shows effects of changing vegetation and anthropogenic activity.

AB - We present results from complementary geological, topographic, seismic and electrical resistivity surveys at the Sagebrush Flat (SGB) site along the Clark fault (CF) strand of the San Jacinto fault zone trifurcation area southeast of Anza, California. Joint interpretation of these data sets, each with unique spatiotemporal sensitivities, allow us to better characterize the shallow (<100 m) fault zone at this structurally complex site. Geological mapping at the surface shows the CF has three main subparallel strands within a <100 m zone with varying degrees of rock damage. These strands intersect units of banded gneiss and tonalite, and various sedimentary units. Near the surface, the weathered but more intact tonalite and gneiss to the southwest have relatively high VP. The low-lying flat sedimentary basins around the two southwestern-most CF strands and elevated damaged gneiss to the northeast have lowest VP <500 m s-1. The high relief of the northeast gneiss unit may in part be explained by its extensive damage and inferred increased relative rock uplift. Resistivity imaging shows the unconsolidated dry basin sediments (maximum >1300 Ohm.m) contrasted against the compacted fine-grained (potentially wet) materials within the CF core and the Bautista Formation (minimum <40 Ohm.m), which is slightly elevated above the flat basins. The inverse relationship between VP (increases) and resistivity (decreases) in the uppermost ∼15 m can be characterized as log-log linear with slopes of -2.6 to -4. At depths >30 m, the velocity heterogeneity near the surface merges into larger-scale structures that are generally slower on the northeast side of the CF core compared to the southwest side (as much as ∼40 per cent reduction in average VP). A previous study revealed a 20-37 per cent variability in peak ground velocities across the SGB site from local earthquakes. The upper end of that range is associated with the near-surface unconsolidated sedimentary basins and northeast damaged gneiss unit. Preliminary analysis of time-dependent topography mostly shows effects of changing vegetation and anthropogenic activity.

KW - Earthquake hazards

KW - Electrical resistivity tomography (ERT)

KW - Fractures, faults, and high strain deformation zones

KW - Image processing

KW - Seismic tomography

KW - Structure of the Earth

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Characterizing the uppermost 100 m structure of the San Jacinto fault zone southeast of Anza, California, through joint analysis of geological, topographic, seismic and resistivity data

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