Effects of instrument orientation on small-loop electromagnetic induction surveys of localized 2D conductive targets

Frequency-domain electromagnetic induction (EMI) systems, composed of two coplanar small coils separated by a fixed distance (EMI or SLEM), enable the rapid detection of a great variety of near-surface structures. One coil generates a controlled, primary magnetic field and the other records the vari...

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Detalles Bibliográficos
Publicado: 2011
Materias:
electromagnetic induction
instrument orientation
inversion
lateral filtering
localized 2D objects
small loop
data inversion
electrical conductivity
electromagnetic survey
geoelectric field
magnetic field
one-dimensional modeling
subsoil
two-dimensional modeling
visualization
Acceso en línea:https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_17422132_v8_n4_p579_Robledo
http://hdl.handle.net/20.500.12110/paper_17422132_v8_n4_p579_Robledo
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Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
id paper:paper_17422132_v8_n4_p579_Robledo
record_format dspace
spelling paper:paper_17422132_v8_n4_p579_Robledo2023-06-08T16:27:01Z Effects of instrument orientation on small-loop electromagnetic induction surveys of localized 2D conductive targets electromagnetic induction instrument orientation inversion lateral filtering localized 2D objects small loop data inversion electrical conductivity electromagnetic survey geoelectric field magnetic field one-dimensional modeling subsoil two-dimensional modeling visualization Frequency-domain electromagnetic induction (EMI) systems, composed of two coplanar small coils separated by a fixed distance (EMI or SLEM), enable the rapid detection of a great variety of near-surface structures. One coil generates a controlled, primary magnetic field and the other records the variations of the induced field while the instrument is moved over the studied area. The most usual acquisition configuration corresponds to horizontal coils, with the instrument axis parallel to the prospection lines. Usually, the interpretation is based on the direct visualization of the plan-views of the data measured at each frequency. In addition, to characterize the subsoil structure in-depth, 1D inversion methods are generally applied. The aim of this work is to analyse how the system orientation affects the ability of the method to detect localized, 2D conductive structures, buried at shallow depths, and the possibility of adequately characterizing these targets through 1D inversions. We performed a survey at a test site that contains two known structures of this type, buried in almost perpendicular directions. We performed parallel prospection lines in the direction of each structure, employing, aside from the usual configuration described before, other configurations that included horizontal and vertical coils, with the instrument axis parallel and perpendicular to the lines. For comparison, we also performed a geoelectric dipole-dipole line crossing one of the targets. The features of the anomalies observed in the graphs of the EMI apparent conductivity data strongly depend on the instrument orientation. In the horizontal coil configurations, a decrease of the apparent conductivity is observed just over the targets. Besides, each vertical configuration practically detects only the target aligned with the plane of the coils, as an important positive anomaly. Through numerical simulations, performed using a 2D forward modelling method, we demonstrate that these features are indeed 2D effects associated with the localized character of the studied conductive objects. Then, we applied to the data a 1D inversion method and drawing together the results generated pseudo 3D models of the subsoil. We found that the models obtained for the vertical coil configurations provide better results. They detect the targets as conductive structures and provide a rather good estimation of their depths. Finally, we compare the EMI results with the image obtained from the 2D inversion of the geoelectrical data and analyse the causes of the observed differences. © 2011 Nanjing Geophysical Research Institute. 2011 https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_17422132_v8_n4_p579_Robledo http://hdl.handle.net/20.500.12110/paper_17422132_v8_n4_p579_Robledo
institution Universidad de Buenos Aires
institution_str I-28
repository_str R-134
collection Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic electromagnetic induction
instrument orientation
inversion
lateral filtering
localized 2D objects
small loop
data inversion
electrical conductivity
electromagnetic survey
geoelectric field
magnetic field
one-dimensional modeling
subsoil
two-dimensional modeling
visualization
spellingShingle electromagnetic induction
instrument orientation
inversion
lateral filtering
localized 2D objects
small loop
data inversion
electrical conductivity
electromagnetic survey
geoelectric field
magnetic field
one-dimensional modeling
subsoil
two-dimensional modeling
visualization
Effects of instrument orientation on small-loop electromagnetic induction surveys of localized 2D conductive targets
topic_facet electromagnetic induction
instrument orientation
inversion
lateral filtering
localized 2D objects
small loop
data inversion
electrical conductivity
electromagnetic survey
geoelectric field
magnetic field
one-dimensional modeling
subsoil
two-dimensional modeling
visualization
description Frequency-domain electromagnetic induction (EMI) systems, composed of two coplanar small coils separated by a fixed distance (EMI or SLEM), enable the rapid detection of a great variety of near-surface structures. One coil generates a controlled, primary magnetic field and the other records the variations of the induced field while the instrument is moved over the studied area. The most usual acquisition configuration corresponds to horizontal coils, with the instrument axis parallel to the prospection lines. Usually, the interpretation is based on the direct visualization of the plan-views of the data measured at each frequency. In addition, to characterize the subsoil structure in-depth, 1D inversion methods are generally applied. The aim of this work is to analyse how the system orientation affects the ability of the method to detect localized, 2D conductive structures, buried at shallow depths, and the possibility of adequately characterizing these targets through 1D inversions. We performed a survey at a test site that contains two known structures of this type, buried in almost perpendicular directions. We performed parallel prospection lines in the direction of each structure, employing, aside from the usual configuration described before, other configurations that included horizontal and vertical coils, with the instrument axis parallel and perpendicular to the lines. For comparison, we also performed a geoelectric dipole-dipole line crossing one of the targets. The features of the anomalies observed in the graphs of the EMI apparent conductivity data strongly depend on the instrument orientation. In the horizontal coil configurations, a decrease of the apparent conductivity is observed just over the targets. Besides, each vertical configuration practically detects only the target aligned with the plane of the coils, as an important positive anomaly. Through numerical simulations, performed using a 2D forward modelling method, we demonstrate that these features are indeed 2D effects associated with the localized character of the studied conductive objects. Then, we applied to the data a 1D inversion method and drawing together the results generated pseudo 3D models of the subsoil. We found that the models obtained for the vertical coil configurations provide better results. They detect the targets as conductive structures and provide a rather good estimation of their depths. Finally, we compare the EMI results with the image obtained from the 2D inversion of the geoelectrical data and analyse the causes of the observed differences. © 2011 Nanjing Geophysical Research Institute.
title Effects of instrument orientation on small-loop electromagnetic induction surveys of localized 2D conductive targets
title_short Effects of instrument orientation on small-loop electromagnetic induction surveys of localized 2D conductive targets
title_full Effects of instrument orientation on small-loop electromagnetic induction surveys of localized 2D conductive targets
title_fullStr Effects of instrument orientation on small-loop electromagnetic induction surveys of localized 2D conductive targets
title_full_unstemmed Effects of instrument orientation on small-loop electromagnetic induction surveys of localized 2D conductive targets
title_sort effects of instrument orientation on small-loop electromagnetic induction surveys of localized 2d conductive targets
publishDate 2011
url https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_17422132_v8_n4_p579_Robledo
http://hdl.handle.net/20.500.12110/paper_17422132_v8_n4_p579_Robledo
_version_ 1768542287423340544

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