Tidal height and frequency dependence of acoustic velocity and attenuation in shallow gassy marine sediments
Tidal height and frequency dependence of acoustic velocity and attenuation in shallow gassy marine sediments
Remote prediction of gassy marine sediment properties is important for geohazard assessment. Gas bubble resonance theory suggests that gassy sediments exhibit acoustic wave velocity-frequency and attenuation-frequency relationships that depend on gas bubble size, gas content, and sediment elastic properties. An acoustic monitoring experiment to investigate gas bubble resonance effects was undertaken at an intertidal site at Dibden Bay, Southampton, United Kingdom. A vertical hydrophone array was positioned to straddle the top of the gassy zone identified on acoustic reflection profiles at about 1 m below the seabed. A miniboomer in the seabed above the array was used to generate broadband (600 Hz to 3000 Hz) acoustic signals every 10 min during a 24 hour period with water depths varying between 0 m (subaerial exposure) at low tide and 2.35 m at high tide. The calculated frequency spectra of compressional wave attenuation coefficient show an attenuation maximum (over 200 dB/m) that shifts in frequency from 1050 Hz at low tide to 1250 Hz at high tide, thus for the first time providing direct evidence of in situ gas bubble resonance in marine sediments. Modeling suggests that effective gas bubble radii of 11 mm to 13 mm are responsible for the attenuation maximum, supported by X-ray computed tomography scan observations on a pressure core (which also indicate that bubble shape depends on sediment type). Modeling of bubble size fluctuations due to pressure equilibration cannot reproduce the observed frequency shift of the attenuation maximum, implying that gas diffusion and nonspherical bubbles are significant.
acoustic, velocity, attenuation, gassy marine sediments
1-17
Best, A.I.
cad03726-10f8-4f90-a3ba-5031665234c9
Tuffin, M.D.J.
28ea968e-9a62-42a8-91f3-2fe361d184cd
Dix, J.K.
efbb0b6e-7dfd-47e1-ae96-92412bd45628
Bull, J.M.
974037fd-544b-458f-98cc-ce8eca89e3c8
5 August 2004
Best, A.I.
cad03726-10f8-4f90-a3ba-5031665234c9
Tuffin, M.D.J.
28ea968e-9a62-42a8-91f3-2fe361d184cd
Dix, J.K.
efbb0b6e-7dfd-47e1-ae96-92412bd45628
Bull, J.M.
974037fd-544b-458f-98cc-ce8eca89e3c8
Best, A.I., Tuffin, M.D.J., Dix, J.K. and Bull, J.M.
(2004)
Tidal height and frequency dependence of acoustic velocity and attenuation in shallow gassy marine sediments.
Journal of Geophysical Research, 109 (B8), .
(doi:10.1029/2003JB002748).
Abstract
Remote prediction of gassy marine sediment properties is important for geohazard assessment. Gas bubble resonance theory suggests that gassy sediments exhibit acoustic wave velocity-frequency and attenuation-frequency relationships that depend on gas bubble size, gas content, and sediment elastic properties. An acoustic monitoring experiment to investigate gas bubble resonance effects was undertaken at an intertidal site at Dibden Bay, Southampton, United Kingdom. A vertical hydrophone array was positioned to straddle the top of the gassy zone identified on acoustic reflection profiles at about 1 m below the seabed. A miniboomer in the seabed above the array was used to generate broadband (600 Hz to 3000 Hz) acoustic signals every 10 min during a 24 hour period with water depths varying between 0 m (subaerial exposure) at low tide and 2.35 m at high tide. The calculated frequency spectra of compressional wave attenuation coefficient show an attenuation maximum (over 200 dB/m) that shifts in frequency from 1050 Hz at low tide to 1250 Hz at high tide, thus for the first time providing direct evidence of in situ gas bubble resonance in marine sediments. Modeling suggests that effective gas bubble radii of 11 mm to 13 mm are responsible for the attenuation maximum, supported by X-ray computed tomography scan observations on a pressure core (which also indicate that bubble shape depends on sediment type). Modeling of bubble size fluctuations due to pressure equilibration cannot reproduce the observed frequency shift of the attenuation maximum, implying that gas diffusion and nonspherical bubbles are significant.
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Accepted/In Press date: 8 June 2004
Published date: 5 August 2004
Keywords:
acoustic, velocity, attenuation, gassy marine sediments
Identifiers
Local EPrints ID: 11161
URI: http://eprints.soton.ac.uk/id/eprint/11161
ISSN: 0148-0227
PURE UUID: 18b61984-91a0-4d0d-899c-7dc89981c58c
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Date deposited: 28 Oct 2004
Last modified: 16 Mar 2024 02:45
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Author:
A.I. Best
Author:
M.D.J. Tuffin
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