Mapping sand layers in clayey till using crosshole ground-penetrating radar

Majken Caroline Looms Zibar; Anja Klotzsche; Jan  van der Kruk; Thomas Hauerberg Larsen; Anders Edsen; Nina Tuxen; Nancy Hamburger; Johanna Keskinen; Lars Nielsen

doi:10.1190/GEO2017-0297.1

Mapping sand layers in clayey till using crosshole ground-penetrating radar

Majken Caroline Looms Zibar, Anja Klotzsche, Jan van der Kruk, Thomas Hauerberg Larsen, Anders Edsen, Nina Tuxen, Nancy Hamburger, Johanna Keskinen, Lars Nielsen

Geologi

6 Citationer (Scopus)

Abstract

Fluid transport through clayey tills governs the quantity and quality of groundwater resources in the Northern Hemisphere. This transport is often controlled by a 3D network of macropores (biopores, fractures, and sand lenses) within the clayey till. At present, a nondestructive technique that can map and characterize the sand-lens network does not exist, and full excavation or extensive drilling is therefore the only solution. Acquisition and modeling of crosshole ground-penetrating radar (GPR) may provide the answer to this problem. We collected 1D and 2D crosshole GPR data at a field site in Denmark from four 8 m deep boreholes with horizontal distances varying between 2.64 and 5.05 m.We find that the depth, thickness, and tilt of a coherent sand layer within the clayey till (approximately 0.4-0.6 m thick), as well as the underlying sand formation, can be mapped accurately using GPR data. We efficiently identify the sand as a highly resistive section with high electromagnetic (EM) wave velocities, whereas the clayey till is conductive with lower EM wave velocities.We find that the exact location of the sand occurrences is better delineated by the increase in amplitude than the increase in EM wave velocity. We believe that crosshole GPR may contribute significantly to groundwater protection and contaminant remediation initiatives.

Originalsprog	Engelsk
Tidsskrift	Geophysics
Vol/bind	83
Udgave nummer	1
Sider (fra-til)	A21-A26
Antal sider	6
ISSN	0016-8033
DOI	https://doi.org/10.1190/GEO2017-0297.1
Status	Udgivet - 1 jan. 2018

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10.1190/GEO2017-0297.1

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title = "Mapping sand layers in clayey till using crosshole ground-penetrating radar",

abstract = "Fluid transport through clayey tills governs the quantity and quality of groundwater resources in the Northern Hemisphere. This transport is often controlled by a 3D network of macropores (biopores, fractures, and sand lenses) within the clayey till. At present, a nondestructive technique that can map and characterize the sand-lens network does not exist, and full excavation or extensive drilling is therefore the only solution. Acquisition and modeling of crosshole ground-penetrating radar (GPR) may provide the answer to this problem. We collected 1D and 2D crosshole GPR data at a field site in Denmark from four 8 m deep boreholes with horizontal distances varying between 2.64 and 5.05 m.We find that the depth, thickness, and tilt of a coherent sand layer within the clayey till (approximately 0.4-0.6 m thick), as well as the underlying sand formation, can be mapped accurately using GPR data. We efficiently identify the sand as a highly resistive section with high electromagnetic (EM) wave velocities, whereas the clayey till is conductive with lower EM wave velocities.We find that the exact location of the sand occurrences is better delineated by the increase in amplitude than the increase in EM wave velocity. We believe that crosshole GPR may contribute significantly to groundwater protection and contaminant remediation initiatives.",

author = "Zibar, {Majken Caroline Looms} and Anja Klotzsche and {van der Kruk}, Jan and Larsen, {Thomas Hauerberg} and Anders Edsen and Nina Tuxen and Nancy Hamburger and Johanna Keskinen and Lars Nielsen",

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T1 - Mapping sand layers in clayey till using crosshole ground-penetrating radar

AU - Zibar, Majken Caroline Looms

AU - Klotzsche, Anja

AU - van der Kruk, Jan

AU - Larsen, Thomas Hauerberg

AU - Edsen, Anders

AU - Tuxen, Nina

AU - Hamburger, Nancy

AU - Keskinen, Johanna

AU - Nielsen, Lars

PY - 2018/1/1

Y1 - 2018/1/1

N2 - Fluid transport through clayey tills governs the quantity and quality of groundwater resources in the Northern Hemisphere. This transport is often controlled by a 3D network of macropores (biopores, fractures, and sand lenses) within the clayey till. At present, a nondestructive technique that can map and characterize the sand-lens network does not exist, and full excavation or extensive drilling is therefore the only solution. Acquisition and modeling of crosshole ground-penetrating radar (GPR) may provide the answer to this problem. We collected 1D and 2D crosshole GPR data at a field site in Denmark from four 8 m deep boreholes with horizontal distances varying between 2.64 and 5.05 m.We find that the depth, thickness, and tilt of a coherent sand layer within the clayey till (approximately 0.4-0.6 m thick), as well as the underlying sand formation, can be mapped accurately using GPR data. We efficiently identify the sand as a highly resistive section with high electromagnetic (EM) wave velocities, whereas the clayey till is conductive with lower EM wave velocities.We find that the exact location of the sand occurrences is better delineated by the increase in amplitude than the increase in EM wave velocity. We believe that crosshole GPR may contribute significantly to groundwater protection and contaminant remediation initiatives.

AB - Fluid transport through clayey tills governs the quantity and quality of groundwater resources in the Northern Hemisphere. This transport is often controlled by a 3D network of macropores (biopores, fractures, and sand lenses) within the clayey till. At present, a nondestructive technique that can map and characterize the sand-lens network does not exist, and full excavation or extensive drilling is therefore the only solution. Acquisition and modeling of crosshole ground-penetrating radar (GPR) may provide the answer to this problem. We collected 1D and 2D crosshole GPR data at a field site in Denmark from four 8 m deep boreholes with horizontal distances varying between 2.64 and 5.05 m.We find that the depth, thickness, and tilt of a coherent sand layer within the clayey till (approximately 0.4-0.6 m thick), as well as the underlying sand formation, can be mapped accurately using GPR data. We efficiently identify the sand as a highly resistive section with high electromagnetic (EM) wave velocities, whereas the clayey till is conductive with lower EM wave velocities.We find that the exact location of the sand occurrences is better delineated by the increase in amplitude than the increase in EM wave velocity. We believe that crosshole GPR may contribute significantly to groundwater protection and contaminant remediation initiatives.

U2 - 10.1190/GEO2017-0297.1

DO - 10.1190/GEO2017-0297.1

M3 - Journal article

SN - 0016-8033

VL - 83

SP - A21-A26

JO - Geophysics

JF - Geophysics

IS - 1

ER -

Mapping sand layers in clayey till using crosshole ground-penetrating radar

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