Laboratory measurements of water saturation effects on the acoustic velocity and attenuation of sand packs in the 1–20 kHz frequency range
Laboratory measurements of water saturation effects on the acoustic velocity and attenuation of sand packs in the 1–20 kHz frequency range
We present novel experimental measurements of acoustic velocity and attenuation in unconsolidated sand with water saturation within the sonic (well-log analogue) frequency range of 1–20 kHz. The measurements were conducted on jacketed sand packs with 0.5-m length and 0.069-m diameter using a bespoke acoustic pulse tube (a water-filled, stainless steel, thick-walled tube) under 10 MPa of hydrostatic confining pressure and 0.1 MPa of atmospheric pore pressure. We assess the fluid distribution effect on our measurements through an effective medium rock physics model, using uniform and patchy saturation approaches. Our velocity and attenuation (Q
−1) are accurate to ±2.4% and ±5.8%, respectively, based on comparisons with a theoretical transmission coefficient model. Velocity decreases with increasing water saturation up to ∼75% and then increases up to the maximum saturation. The velocity profiles across all four samples show similar values with small differences observed around 70%–90% water saturation, then converging again at maximum saturation. In contrast, the attenuation increases at low saturation, followed by a slight decrease towards maximum saturation. Velocity increases with frequency across all samples, which contrasts with the complex frequency-dependent pattern of attenuation. These results provide valuable insights into understanding elastic wave measurements over a broad frequency spectrum, particularly in the sonic range.
acoustics, attenuation, pulse tube, rock physics, velocity
Sutiyoso, Hanif S.
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Sahoo, Sourav K.
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North, Laurence J.
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Minshull, Timothy A.
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Falcon-Suarez, Ismael Himar
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Best, Angus I.
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Sutiyoso, Hanif S.
b0aef29a-6e9c-4e2b-ba88-67eae43501f1
Sahoo, Sourav K.
6dab0376-36df-44c5-9f36-cb4a29d9b03b
North, Laurence J.
9dc2779f-0a6f-4619-8473-7f2eea6a83fc
Minshull, Timothy A.
bf413fb5-849e-4389-acd7-0cb0d644e6b8
Falcon-Suarez, Ismael Himar
f14858f6-d086-4761-9dc5-ba09bd89d95b
Best, Angus I.
f962ede8-2ff2-42b6-baa1-88d93dfb08dd
Sutiyoso, Hanif S., Sahoo, Sourav K., North, Laurence J., Minshull, Timothy A., Falcon-Suarez, Ismael Himar and Best, Angus I.
(2024)
Laboratory measurements of water saturation effects on the acoustic velocity and attenuation of sand packs in the 1–20 kHz frequency range.
Geophysical Prospecting.
(doi:10.1111/1365-2478.13607).
Abstract
We present novel experimental measurements of acoustic velocity and attenuation in unconsolidated sand with water saturation within the sonic (well-log analogue) frequency range of 1–20 kHz. The measurements were conducted on jacketed sand packs with 0.5-m length and 0.069-m diameter using a bespoke acoustic pulse tube (a water-filled, stainless steel, thick-walled tube) under 10 MPa of hydrostatic confining pressure and 0.1 MPa of atmospheric pore pressure. We assess the fluid distribution effect on our measurements through an effective medium rock physics model, using uniform and patchy saturation approaches. Our velocity and attenuation (Q
−1) are accurate to ±2.4% and ±5.8%, respectively, based on comparisons with a theoretical transmission coefficient model. Velocity decreases with increasing water saturation up to ∼75% and then increases up to the maximum saturation. The velocity profiles across all four samples show similar values with small differences observed around 70%–90% water saturation, then converging again at maximum saturation. In contrast, the attenuation increases at low saturation, followed by a slight decrease towards maximum saturation. Velocity increases with frequency across all samples, which contrasts with the complex frequency-dependent pattern of attenuation. These results provide valuable insights into understanding elastic wave measurements over a broad frequency spectrum, particularly in the sonic range.
Text
Accepted Manuscript - Sutiyoso et. al. (2024)
- Accepted Manuscript
Text
Geophysical Prospecting - 2024 - Sutiyoso - Laboratory measurements of water saturation effects on the acoustic velocity
- Version of Record
More information
Accepted/In Press date: 26 August 2024
e-pub ahead of print date: 12 September 2024
Keywords:
acoustics, attenuation, pulse tube, rock physics, velocity
Identifiers
Local EPrints ID: 494457
URI: http://eprints.soton.ac.uk/id/eprint/494457
ISSN: 0016-8025
PURE UUID: d5061126-3e5c-4d23-8ee3-ea009ea33f48
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Date deposited: 08 Oct 2024 16:49
Last modified: 09 Oct 2024 02:04
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Contributors
Author:
Sourav K. Sahoo
Author:
Laurence J. North
Author:
Ismael Himar Falcon-Suarez
Author:
Angus I. Best
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