The spatial cross-correlation method for dispersive surface waves

Andrew P. Lamb; Kasper van Wijk; Lee M. Liberty; T. Dylan Mikesell

doi:10.1093/gji/ggu237

The spatial cross-correlation method for dispersive surface waves

Andrew P. Lamb, Kasper van Wijk, Lee M. Liberty, T. Dylan Mikesell

Geosciences Department

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

10 Scopus citations

Abstract

Dispersive surface waves are routinely used to estimate the subsurface shear-wave velocity distribution, at all length scales. In the well-known Spatial Autocorrelation method, dispersion information is gained from the correlation of seismic noise signals recorded on the vertical (or radial) components. We demonstrate practical advantages of including the cross-correlation between radial and vertical components of the wavefield in a spatial cross-correlation method. The addition of cross-correlation information increases the resolution and robustness of the phase velocity dispersion information, as demonstrated in numerical simulations and a near-surface field study with active seismic sources, where our method confirms the presence of a fault-zone conduit in a geothermal field.

Original language	English
Pages (from-to)	1-10
Number of pages	10
Journal	Geophysical Journal International
Volume	199
Issue number	1
DOIs	https://doi.org/10.1093/gji/ggu237
State	Published - 1 Oct 2014

Keywords

Hydrothermal systems
Interferometry
North America
Surface waves and free oscillations

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10.1093/gji/ggu237

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title = "The spatial cross-correlation method for dispersive surface waves",

abstract = "Dispersive surface waves are routinely used to estimate the subsurface shear-wave velocity distribution, at all length scales. In the well-known Spatial Autocorrelation method, dispersion information is gained from the correlation of seismic noise signals recorded on the vertical (or radial) components. We demonstrate practical advantages of including the cross-correlation between radial and vertical components of the wavefield in a spatial cross-correlation method. The addition of cross-correlation information increases the resolution and robustness of the phase velocity dispersion information, as demonstrated in numerical simulations and a near-surface field study with active seismic sources, where our method confirms the presence of a fault-zone conduit in a geothermal field.",

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AU - van Wijk, Kasper

AU - Liberty, Lee M.

AU - Mikesell, T. Dylan

PY - 2014/10/1

Y1 - 2014/10/1

N2 - Dispersive surface waves are routinely used to estimate the subsurface shear-wave velocity distribution, at all length scales. In the well-known Spatial Autocorrelation method, dispersion information is gained from the correlation of seismic noise signals recorded on the vertical (or radial) components. We demonstrate practical advantages of including the cross-correlation between radial and vertical components of the wavefield in a spatial cross-correlation method. The addition of cross-correlation information increases the resolution and robustness of the phase velocity dispersion information, as demonstrated in numerical simulations and a near-surface field study with active seismic sources, where our method confirms the presence of a fault-zone conduit in a geothermal field.

AB - Dispersive surface waves are routinely used to estimate the subsurface shear-wave velocity distribution, at all length scales. In the well-known Spatial Autocorrelation method, dispersion information is gained from the correlation of seismic noise signals recorded on the vertical (or radial) components. We demonstrate practical advantages of including the cross-correlation between radial and vertical components of the wavefield in a spatial cross-correlation method. The addition of cross-correlation information increases the resolution and robustness of the phase velocity dispersion information, as demonstrated in numerical simulations and a near-surface field study with active seismic sources, where our method confirms the presence of a fault-zone conduit in a geothermal field.

KW - Hydrothermal systems

KW - Interferometry

KW - North America

KW - Surface waves and free oscillations

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VL - 199

SP - 1

EP - 10

JO - Geophysical Journal International

JF - Geophysical Journal International

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The spatial cross-correlation method for dispersive surface waves

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Keywords

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