Investigation of methane gas bubble dynamics and hydrate film growth during hydrate formation using 4-D time-lapse synchrotron X-ray computed tomography
Investigation of methane gas bubble dynamics and hydrate film growth during hydrate formation using 4-D time-lapse synchrotron X-ray computed tomography
We present a time-lapse 4-D high-resolution synchrotron imaging study of the morphological evolution of methane gas bubbles and hydrate film growth on these bubbles. Methane gas and partially water-saturated sand were used to form hydrate with a maximum hydrate saturation of 60%. We investigated the transient evolution of gas bubble size distribution during hydrate formation and observed three distinct stages: a) nucleation and hydrate film formation, b) rapid bubble break-up, c) gas bubble coalescence and hydrate framework formation. Our results show that the average gas bubble size distribution decreases from 34.17 µm (during hydrate nucleation) to 8.87 µm (during secondary bubble formation). The small-size methane bubble population (mean diameter below 10 µm) initially increases at the expense of the larger methane bubble population (mean diameter above 50 µm) due to breakage of the larger bubbles and coalescence of the smaller bubbles. We quantified that the average hydrate film thickness increases from 3.51 to 14.7 µm by tracking the evolution of a particular gas bubble. This thickness increase agrees with an analytical model with an average deviation error of 3.3%. This study provides insights into gas bubble distribution and hydrate film growth during hydrate formation, both of which impact the geophysical and mechanical properties of hydrate-bearing sediments.
XRCT, gas bubble dynamics, hydrate film, hydrate formation, methane hydrate
Khan, Shadman H.
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Sahoo, Sourav Kumar
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Falcon-Suarez, Ismael Himar
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Marin-Moreno, Hector
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Sutiyoso, Hanif
b0aef29a-6e9c-4e2b-ba88-67eae43501f1
Madhusudhan, B.N.
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Majumder, C.B.
6868ace7-1d19-499c-8dd5-72990dd7f46d
Arora, Amit
a134aa08-39be-4fd7-82a1-5897f80ad10a
Best, Angus I.
f962ede8-2ff2-42b6-baa1-88d93dfb08dd
16 August 2024
Khan, Shadman H.
93785f76-dbe6-40dc-9def-77fc7ac32601
Sahoo, Sourav Kumar
6dab0376-36df-44c5-9f36-cb4a29d9b03b
Falcon-Suarez, Ismael Himar
f5cdbc61-326b-424d-a90f-593a8698a4d2
Marin-Moreno, Hector
e466cafd-bd5c-47a1-8522-e6938e7086a4
Sutiyoso, Hanif
b0aef29a-6e9c-4e2b-ba88-67eae43501f1
Madhusudhan, B.N.
e139e3d3-2992-4579-b3f0-4eec3ddae98c
Majumder, C.B.
6868ace7-1d19-499c-8dd5-72990dd7f46d
Arora, Amit
a134aa08-39be-4fd7-82a1-5897f80ad10a
Best, Angus I.
f962ede8-2ff2-42b6-baa1-88d93dfb08dd
Khan, Shadman H., Sahoo, Sourav Kumar, Falcon-Suarez, Ismael Himar, Marin-Moreno, Hector, Sutiyoso, Hanif, Madhusudhan, B.N., Majumder, C.B., Arora, Amit and Best, Angus I.
(2024)
Investigation of methane gas bubble dynamics and hydrate film growth during hydrate formation using 4-D time-lapse synchrotron X-ray computed tomography.
Frontiers in Earth Science, 12, [1438185].
(doi:10.3389/feart.2024.1438185).
Abstract
We present a time-lapse 4-D high-resolution synchrotron imaging study of the morphological evolution of methane gas bubbles and hydrate film growth on these bubbles. Methane gas and partially water-saturated sand were used to form hydrate with a maximum hydrate saturation of 60%. We investigated the transient evolution of gas bubble size distribution during hydrate formation and observed three distinct stages: a) nucleation and hydrate film formation, b) rapid bubble break-up, c) gas bubble coalescence and hydrate framework formation. Our results show that the average gas bubble size distribution decreases from 34.17 µm (during hydrate nucleation) to 8.87 µm (during secondary bubble formation). The small-size methane bubble population (mean diameter below 10 µm) initially increases at the expense of the larger methane bubble population (mean diameter above 50 µm) due to breakage of the larger bubbles and coalescence of the smaller bubbles. We quantified that the average hydrate film thickness increases from 3.51 to 14.7 µm by tracking the evolution of a particular gas bubble. This thickness increase agrees with an analytical model with an average deviation error of 3.3%. This study provides insights into gas bubble distribution and hydrate film growth during hydrate formation, both of which impact the geophysical and mechanical properties of hydrate-bearing sediments.
Text
feart-12-1438185
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Accepted/In Press date: 29 July 2024
Published date: 16 August 2024
Keywords:
XRCT, gas bubble dynamics, hydrate film, hydrate formation, methane hydrate
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Local EPrints ID: 493600
URI: http://eprints.soton.ac.uk/id/eprint/493600
PURE UUID: 0f896bac-01ea-476b-98ed-30a19b99aee3
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Date deposited: 09 Sep 2024 16:38
Last modified: 12 Sep 2024 02:07
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Contributors
Author:
Shadman H. Khan
Author:
Sourav Kumar Sahoo
Author:
Ismael Himar Falcon-Suarez
Author:
Hector Marin-Moreno
Author:
C.B. Majumder
Author:
Amit Arora
Author:
Angus I. Best
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