Crosshole Radar Tomography in an Alluvial Aquifer Nearboise, Idaho

William P. Clement; Warren Barrash

Crosshole Radar Tomography in an Alluvial Aquifer Nearboise, Idaho

Boise State University

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

Abstract

To determine the distribution of heterogeneities in an unconfined aquifer in Boise, ID, we compute radar tomograms for three adjacent well pairs. The fluvial deposits consist of unconsolidated cobbles and sands. We used a curved-ray, finite-difference approximation to the eikonal equation to generate the forward model. The inversion uses a linearized, iterative scheme to determine the slowness distribution from the first arrival traveltimes. The tomograms consist of a sequence of layers representing the saturated aquifer. The velocities in this saturated zone range between 0.06 to 0.10 m/ns. We use a variety of methods to assess the reliability of our velocity models. Finally, we compare our results to neutron-derived porosity logs in the wells used for the tomograms. The comparison shows that the trends in porosity derived from the tomograms match well with the trends in porosity measured with the neutron probe.

Original language	American English
Journal	Symposium on the Application of Geophysics to Engineering and Environmental Problems Proceedings
State	Published - 1 Jan 2006

EGS Disciplines

Geophysics and Seismology

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title = "Crosshole Radar Tomography in an Alluvial Aquifer Nearboise, Idaho",

abstract = " To determine the distribution of heterogeneities in an unconfined aquifer in Boise, ID, we compute radar tomograms for three adjacent well pairs. The fluvial deposits consist of unconsolidated cobbles and sands. We used a curved-ray, finite-difference approximation to the eikonal equation to generate the forward model. The inversion uses a linearized, iterative scheme to determine the slowness distribution from the first arrival traveltimes. The tomograms consist of a sequence of layers representing the saturated aquifer. The velocities in this saturated zone range between 0.06 to 0.10 m/ns. We use a variety of methods to assess the reliability of our velocity models. Finally, we compare our results to neutron-derived porosity logs in the wells used for the tomograms. The comparison shows that the trends in porosity derived from the tomograms match well with the trends in porosity measured with the neutron probe.",

author = "Clement, {William P.} and Warren Barrash",

note = "William P. Clement and Warren Barrash. (2006). {"}Crosshole Radar Tomography in an Alluvial Aquifer Near Boise, Idaho{"}. In Symposium on the Application of Geophysics to Engineering and Environmental Problems Proceedings{"} (pp. 664-673). The Environmental and Engineering Geophysical Society (EEGS). https://doi.org/10.4133/1.2923704",

year = "2006",

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TY - JOUR

T1 - Crosshole Radar Tomography in an Alluvial Aquifer Nearboise, Idaho

AU - Clement, William P.

AU - Barrash, Warren

N1 - William P. Clement and Warren Barrash. (2006). "Crosshole Radar Tomography in an Alluvial Aquifer Near Boise, Idaho". In Symposium on the Application of Geophysics to Engineering and Environmental Problems Proceedings" (pp. 664-673). The Environmental and Engineering Geophysical Society (EEGS). https://doi.org/10.4133/1.2923704

PY - 2006/1/1

Y1 - 2006/1/1

N2 - To determine the distribution of heterogeneities in an unconfined aquifer in Boise, ID, we compute radar tomograms for three adjacent well pairs. The fluvial deposits consist of unconsolidated cobbles and sands. We used a curved-ray, finite-difference approximation to the eikonal equation to generate the forward model. The inversion uses a linearized, iterative scheme to determine the slowness distribution from the first arrival traveltimes. The tomograms consist of a sequence of layers representing the saturated aquifer. The velocities in this saturated zone range between 0.06 to 0.10 m/ns. We use a variety of methods to assess the reliability of our velocity models. Finally, we compare our results to neutron-derived porosity logs in the wells used for the tomograms. The comparison shows that the trends in porosity derived from the tomograms match well with the trends in porosity measured with the neutron probe.

AB - To determine the distribution of heterogeneities in an unconfined aquifer in Boise, ID, we compute radar tomograms for three adjacent well pairs. The fluvial deposits consist of unconsolidated cobbles and sands. We used a curved-ray, finite-difference approximation to the eikonal equation to generate the forward model. The inversion uses a linearized, iterative scheme to determine the slowness distribution from the first arrival traveltimes. The tomograms consist of a sequence of layers representing the saturated aquifer. The velocities in this saturated zone range between 0.06 to 0.10 m/ns. We use a variety of methods to assess the reliability of our velocity models. Finally, we compare our results to neutron-derived porosity logs in the wells used for the tomograms. The comparison shows that the trends in porosity derived from the tomograms match well with the trends in porosity measured with the neutron probe.

UR - https://scholarworks.boisestate.edu/cgiss_facpubs/244

M3 - Article

JO - Symposium on the Application of Geophysics to Engineering and Environmental Problems Proceedings

JF - Symposium on the Application of Geophysics to Engineering and Environmental Problems Proceedings

ER -

Crosshole Radar Tomography in an Alluvial Aquifer Nearboise, Idaho

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