Measurement and Modeling of High‐Frequency Acoustic Properties in Fine Sandy Sediments

Measurement and Modeling of High‐Frequency Acoustic Properties in Fine Sandy Sediments

Abstract The object of this study was to obtain the acoustic properties of fine sandy sediments with approximately 22% clay content from the East China Sea Shelf. This study conducted the in situ acoustic measurement to measure the sound speed and attenuation, and eight sediment cores were collected...

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Main Authors: G. Li, J. Wang, B. Liu, X. Meng, G. Kan, Y. Pei
Format: Article
Language:English
Published: American Geophysical Union (AGU) 2019-11-01
Series:Earth and Space Science
Subjects:
seafloor sediments
sound speed
attenuation
in situ measurement
Online Access:https://doi.org/10.1029/2019EA000656
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spelling doaj-6d6fd94330ce4ecb84d20499e9586d792020-11-24T21:25:20ZengAmerican Geophysical Union (AGU)Earth and Space Science2333-50842019-11-016112057207010.1029/2019EA000656Measurement and Modeling of High‐Frequency Acoustic Properties in Fine Sandy SedimentsG. Li0J. Wang1B. Liu2X. Meng3G. Kan4Y. Pei5Key Laboratory of Marine Sedimentology and Environmental Geology First Institute of Oceanography, MNR Qingdao ChinaKey Laboratory of Marine Sedimentology and Environmental Geology First Institute of Oceanography, MNR Qingdao ChinaLaboratory for Marine Geology Qingdao National Laboratory for Marine Science and Technology Qingdao ChinaKey Laboratory of Marine Sedimentology and Environmental Geology First Institute of Oceanography, MNR Qingdao ChinaKey Laboratory of Marine Sedimentology and Environmental Geology First Institute of Oceanography, MNR Qingdao ChinaKey Laboratory of Marine Sedimentology and Environmental Geology First Institute of Oceanography, MNR Qingdao ChinaAbstract The object of this study was to obtain the acoustic properties of fine sandy sediments with approximately 22% clay content from the East China Sea Shelf. This study conducted the in situ acoustic measurement to measure the sound speed and attenuation, and eight sediment cores were collected and measured the wet bulk density, porosity, and mean grain size in laboratory environment. The correlations between in situ sound speed ratio and physical properties show good accordance with two empirical equations, while the in situ attenuation factor deviated the regression curves. Both the sound speed ratio and the attenuation data show the obvious change against the measurement frequency. The comparisons of the measured sound speed ratio and attenuation to the Biot‐Stoll model predictions were performed. The sound speed ratio dispersion agrees well with the model prediction, when the permeability and pore size were calculated using the extended Kozeny‐Carman's equation and the extended Hovem's equation. The attenuation data in this study accords better with the prediction curves reported for fine sediments than that for coarse sediments from the 1999 Sediment Acoustics Experiment.https://doi.org/10.1029/2019EA000656seafloor sedimentssound speedattenuationin situ measurement
collection DOAJ
language English
format Article
sources DOAJ
author G. Li
J. Wang
B. Liu
X. Meng
G. Kan
Y. Pei
spellingShingle G. Li
J. Wang
B. Liu
X. Meng
G. Kan
Y. Pei
Measurement and Modeling of High‐Frequency Acoustic Properties in Fine Sandy Sediments
Earth and Space Science
seafloor sediments
sound speed
attenuation
in situ measurement
author_facet G. Li
J. Wang
B. Liu
X. Meng
G. Kan
Y. Pei
author_sort G. Li
title Measurement and Modeling of High‐Frequency Acoustic Properties in Fine Sandy Sediments
title_short Measurement and Modeling of High‐Frequency Acoustic Properties in Fine Sandy Sediments
title_full Measurement and Modeling of High‐Frequency Acoustic Properties in Fine Sandy Sediments
title_fullStr Measurement and Modeling of High‐Frequency Acoustic Properties in Fine Sandy Sediments
title_full_unstemmed Measurement and Modeling of High‐Frequency Acoustic Properties in Fine Sandy Sediments
title_sort measurement and modeling of high‐frequency acoustic properties in fine sandy sediments
publisher American Geophysical Union (AGU)
series Earth and Space Science
issn 2333-5084
publishDate 2019-11-01
description Abstract The object of this study was to obtain the acoustic properties of fine sandy sediments with approximately 22% clay content from the East China Sea Shelf. This study conducted the in situ acoustic measurement to measure the sound speed and attenuation, and eight sediment cores were collected and measured the wet bulk density, porosity, and mean grain size in laboratory environment. The correlations between in situ sound speed ratio and physical properties show good accordance with two empirical equations, while the in situ attenuation factor deviated the regression curves. Both the sound speed ratio and the attenuation data show the obvious change against the measurement frequency. The comparisons of the measured sound speed ratio and attenuation to the Biot‐Stoll model predictions were performed. The sound speed ratio dispersion agrees well with the model prediction, when the permeability and pore size were calculated using the extended Kozeny‐Carman's equation and the extended Hovem's equation. The attenuation data in this study accords better with the prediction curves reported for fine sediments than that for coarse sediments from the 1999 Sediment Acoustics Experiment.
topic seafloor sediments
sound speed
attenuation
in situ measurement
url https://doi.org/10.1029/2019EA000656
work_keys_str_mv AT gli measurementandmodelingofhighfrequencyacousticpropertiesinfinesandysediments
AT jwang measurementandmodelingofhighfrequencyacousticpropertiesinfinesandysediments
AT bliu measurementandmodelingofhighfrequencyacousticpropertiesinfinesandysediments
AT xmeng measurementandmodelingofhighfrequencyacousticpropertiesinfinesandysediments
AT gkan measurementandmodelingofhighfrequencyacousticpropertiesinfinesandysediments
AT ypei measurementandmodelingofhighfrequencyacousticpropertiesinfinesandysediments
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