TY - JOUR
T1 - Ground-penetrating radar for sedimentology: methodological advances and examples from the Usumacinta-Grijalva delta plain, Tabasco, México
AU - Van Dam, Remke
AU - Nooren, Kees
AU - Dogan, Mine
AU - Hoek, Wim
N1 - EGU General Assembly 2014
PY - 2014
Y1 - 2014
N2 - Ground-penetrating radar (GPR) is widely used as a tool for imaging
sedimentary structures and reconstructing depositional history in a
range of settings. Most GPR systems use a pair of dipole antennas to
transmit and receive electromagnetic energy, typically in the frequency
range of 0.025-1 GHz. Radar reflections result from contrasts in
dielectric properties, which can be induced by small textural variations
between layers. To generate cross sections of the subsurface, the
common-offset antenna pair is moved along surface transects. The GPR
method benefits from its relative ease of use and relatively limited
basic processing that is required for interpretation of field data.
Drawbacks include the high signal attenuation in electrically conductive
material such as clay and the trade-off between penetration depth and
resolution for different antenna frequencies. In recent years, various
equipment advances and novel field practices and processing strategies
have improved the ability of GPR to provide high-resolution data in a
wider range of settings and scenarios. Advances include multi-channel
systems for more efficient data collection, multi-offset data collection
and processing for improved signal-to-noise ratios, full-resolution and
multi-component imaging, and full-waveform inversion. In this
presentation, we will discuss some of these methodological advances and
present full-resolution field data from a highly heterogeneous fluvial
site in Mississippi, USA. We will also present GPR data from a project
focused on reconstructing depositional history of the
Usumacinta-Grijalva delta in Tabasco, México, which is the
world's largest beach ridge plain. Here we used common-offset GPR
antenna pairs at two frequencies to assess the varying thickness of the
eolian cover of individual beach ridges. We also characterized
systematic changes in the dip of beach face and foreshore deposits to
study its possible relation with temporal changes in coastal processes.
AB - Ground-penetrating radar (GPR) is widely used as a tool for imaging
sedimentary structures and reconstructing depositional history in a
range of settings. Most GPR systems use a pair of dipole antennas to
transmit and receive electromagnetic energy, typically in the frequency
range of 0.025-1 GHz. Radar reflections result from contrasts in
dielectric properties, which can be induced by small textural variations
between layers. To generate cross sections of the subsurface, the
common-offset antenna pair is moved along surface transects. The GPR
method benefits from its relative ease of use and relatively limited
basic processing that is required for interpretation of field data.
Drawbacks include the high signal attenuation in electrically conductive
material such as clay and the trade-off between penetration depth and
resolution for different antenna frequencies. In recent years, various
equipment advances and novel field practices and processing strategies
have improved the ability of GPR to provide high-resolution data in a
wider range of settings and scenarios. Advances include multi-channel
systems for more efficient data collection, multi-offset data collection
and processing for improved signal-to-noise ratios, full-resolution and
multi-component imaging, and full-waveform inversion. In this
presentation, we will discuss some of these methodological advances and
present full-resolution field data from a highly heterogeneous fluvial
site in Mississippi, USA. We will also present GPR data from a project
focused on reconstructing depositional history of the
Usumacinta-Grijalva delta in Tabasco, México, which is the
world's largest beach ridge plain. Here we used common-offset GPR
antenna pairs at two frequencies to assess the varying thickness of the
eolian cover of individual beach ridges. We also characterized
systematic changes in the dip of beach face and foreshore deposits to
study its possible relation with temporal changes in coastal processes.
M3 - Meeting Abstract
SN - 1029-7006
VL - 16
JO - Geophysical Research Abstracts
JF - Geophysical Research Abstracts
M1 - EGU2014-13051
T2 - 2014 General Assembly of the EGU
Y2 - 1 January 2014
ER -