The influence of sedimentary architecture on the formation of earthquake-induced liquefaction features: A case study in the New Madrid seismic zone

The influence of sedimentary architecture on the formation of earthquake-induced liquefaction features: A case study in the New Madrid seismic zone

This study is aimed at understanding how the arrangement of fluvial sedimentary deposits and their physical properties influences the formation and location of liquefaction features resulting from earthquake strong ground motions. The study site is located in the Mississippi River floodplain in the...

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Published in:Engineering geology Vol. 312; p. 106946
Main Authors: Güven, Can, Wolf, Lorraine W., Tuttle, Martitia P., Rogers, Stephanie R.
Format: Journal Article
Language:English
Published: Elsevier B.V 01-01-2023
Subjects:
Earthquake hazard
Electrical resistivity tomography
Fluvial sedimentary environments
Liquefaction susceptibility
Paleoseismology
Satellite imagery
Satellite imagery
Electrical resistivity tomography
Fluvial sedimentary environments
Earthquake hazard
Paleoseismology
Liquefaction susceptibility
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Abstract This study is aimed at understanding how the arrangement of fluvial sedimentary deposits and their physical properties influences the formation and location of liquefaction features resulting from earthquake strong ground motions. The study site is located in the Mississippi River floodplain in the New Madrid seismic zone of the central United States, an area that hosts abundant liquefaction deposits resulting from both historic and prehistoric earthquake sequences. We combine satellite imagery, electrical resistivity tomography, soil textural analyses and ditch exposures of liquefaction features to develop a model of how the spatial distribution of sedimentary deposits, such as point bars, overbank, levee, backswamp and channel-fill, contribute to pore pressure build-up and subsequent development of liquefaction features, such as sand dikes and sand blows, as water and entrained sediment forcefully flow toward the surface. The model helps to explain (1) the abundance of earthquake-induced liquefaction features present in the Mississippi River valley, where fine- to medium-grained saturated sands are interbedded with or overlain by fine-grained portions of channel-fill, levee, overbank or backswamp deposits, and (2) the concentration of liquefaction features along the margins of abandoned-channel fill, point bar and overbank deposits, as seen in other locations worldwide. This understanding can contribute to identifying areas where liquefaction may be a threat to engineered structures and limiting the extent of areas in which detailed engineering geology measurements (e.g., in situ testing) may be necessary. •Arrangement of fluvial sediments strongly influences the location of liquefaction features.•Satellite data are used to identify potential locations for liquefaction investigations.•Resistivity models explain liquefaction occurrence along abandoned stream channels margins.•The model explains the relations of sand blows in the Mississippi River floodplain deposits.
AbstractList This study is aimed at understanding how the arrangement of fluvial sedimentary deposits and their physical properties influences the formation and location of liquefaction features resulting from earthquake strong ground motions. The study site is located in the Mississippi River floodplain in the New Madrid seismic zone of the central United States, an area that hosts abundant liquefaction deposits resulting from both historic and prehistoric earthquake sequences. We combine satellite imagery, electrical resistivity tomography, soil textural analyses and ditch exposures of liquefaction features to develop a model of how the spatial distribution of sedimentary deposits, such as point bars, overbank, levee, backswamp and channel-fill, contribute to pore pressure build-up and subsequent development of liquefaction features, such as sand dikes and sand blows, as water and entrained sediment forcefully flow toward the surface. The model helps to explain (1) the abundance of earthquake-induced liquefaction features present in the Mississippi River valley, where fine- to medium-grained saturated sands are interbedded with or overlain by fine-grained portions of channel-fill, levee, overbank or backswamp deposits, and (2) the concentration of liquefaction features along the margins of abandoned-channel fill, point bar and overbank deposits, as seen in other locations worldwide. This understanding can contribute to identifying areas where liquefaction may be a threat to engineered structures and limiting the extent of areas in which detailed engineering geology measurements (e.g., in situ testing) may be necessary. •Arrangement of fluvial sediments strongly influences the location of liquefaction features.•Satellite data are used to identify potential locations for liquefaction investigations.•Resistivity models explain liquefaction occurrence along abandoned stream channels margins.•The model explains the relations of sand blows in the Mississippi River floodplain deposits.
ArticleNumber 106946
Author Tuttle, Martitia P.
Wolf, Lorraine W.
Güven, Can
Rogers, Stephanie R.
Author_xml – sequence: 1
  givenname: Can
  surname: Güven
  fullname: Güven, Can
  email: canguvn@gmail.com
  organization: Department of Geosciences, 2050 Beard Eaves Coliseum, Auburn University, Auburn, AL 36849, United States of America
– sequence: 2
  givenname: Lorraine W.
  surname: Wolf
  fullname: Wolf, Lorraine W.
  email: wolflor@auburn.edu
  organization: Department of Geosciences, 2050 Beard Eaves Coliseum, Auburn University, Auburn, AL 36849, United States of America
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  givenname: Martitia P.
  surname: Tuttle
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  givenname: Stephanie R.
  surname: Rogers
  fullname: Rogers, Stephanie R.
  email: s.rogers@auburn.edu
  organization: Department of Geosciences, 2050 Beard Eaves Coliseum, Auburn University, Auburn, AL 36849, United States of America
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crossref_primary_10_1016_j_enggeo_2024_107609
crossref_primary_10_3208_jgssp_v10_OS_5_05
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Keywords Satellite imagery
Electrical resistivity tomography
Fluvial sedimentary environments
Earthquake hazard
Paleoseismology
Liquefaction susceptibility
Language English
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Snippet This study is aimed at understanding how the arrangement of fluvial sedimentary deposits and their physical properties influences the formation and location of...
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StartPage 106946
SubjectTerms Earthquake hazard
Electrical resistivity tomography
Fluvial sedimentary environments
Liquefaction susceptibility
Paleoseismology
Satellite imagery
Title The influence of sedimentary architecture on the formation of earthquake-induced liquefaction features: A case study in the New Madrid seismic zone
URI https://dx.doi.org/10.1016/j.enggeo.2022.106946
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