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Strength behaviors of CH4 hydrate-bearing silty sediments during thermal decomposition

Strength behaviors of CH4 hydrate-bearing silty sediments during thermal decomposition
Strength behaviors of CH4 hydrate-bearing silty sediments during thermal decomposition

Predicting the mechanical response of methane hydrate-bearing sediments prior to and during gas production enable appropriate design and anticipate risk due to extraction process of methane from deep-ocean and permafrost setting. In this study, a series of triaxial drained shear tests followed by hydrate dissociation were performed on artificial hydrate-bearing silty sediments at given porosity and stress conditions. The peak strength of HBSS increases exponentially with hydrate saturation, which signifies proportional loss of strength due to hydrate dissociation by thermal decomposition. The peak strength of partially dissociated sediments is slightly lower than the strength of sediments with similar hydrate saturation freshly formed. The enhancement effect of CH4 hydrate on the strength behaviors of HBSS would be more obvious under higher effective confining pressures. The peak strength increase of HBSS was not only due to the increase in cohesion component but also frictional component for a given hydrate saturation and porosity. Thermal decomposition of HBSS is governed directly by its hydrate saturation rather than the confining stress, although with higher confining stress the dissipation of the released gas is affected by the permeability of the sediments thus slightly prolonging the dissociation process.

Cohesive force, Hydrate-bearing silty sediments, Peak strength, Thermal decomposition
1875-5100
Song, Yongchen
c77e399a-c9dc-4402-b643-a4693c1f17cc
Luo, Tingting
21d15802-f952-436a-9fdc-50a06f327af3
Madhusudhan, B. N.
e139e3d3-2992-4579-b3f0-4eec3ddae98c
Sun, Xiang
631fdf53-cf40-4396-9858-d337f377c74a
Liu, Yu
d9cd7e55-68e7-4ec6-94e3-868d5bcf5a18
Kong, Xianjing
9f4809be-c6e0-4161-a55e-7fb6770b1f48
Li, Yanghui
26a4f33e-744d-419f-aec2-b2dfabdd9a22
Song, Yongchen
c77e399a-c9dc-4402-b643-a4693c1f17cc
Luo, Tingting
21d15802-f952-436a-9fdc-50a06f327af3
Madhusudhan, B. N.
e139e3d3-2992-4579-b3f0-4eec3ddae98c
Sun, Xiang
631fdf53-cf40-4396-9858-d337f377c74a
Liu, Yu
d9cd7e55-68e7-4ec6-94e3-868d5bcf5a18
Kong, Xianjing
9f4809be-c6e0-4161-a55e-7fb6770b1f48
Li, Yanghui
26a4f33e-744d-419f-aec2-b2dfabdd9a22

Song, Yongchen, Luo, Tingting, Madhusudhan, B. N., Sun, Xiang, Liu, Yu, Kong, Xianjing and Li, Yanghui (2019) Strength behaviors of CH4 hydrate-bearing silty sediments during thermal decomposition. Journal of Natural Gas Science and Engineering, 72, [103031]. (doi:10.1016/j.jngse.2019.103031).

Record type: Article

Abstract

Predicting the mechanical response of methane hydrate-bearing sediments prior to and during gas production enable appropriate design and anticipate risk due to extraction process of methane from deep-ocean and permafrost setting. In this study, a series of triaxial drained shear tests followed by hydrate dissociation were performed on artificial hydrate-bearing silty sediments at given porosity and stress conditions. The peak strength of HBSS increases exponentially with hydrate saturation, which signifies proportional loss of strength due to hydrate dissociation by thermal decomposition. The peak strength of partially dissociated sediments is slightly lower than the strength of sediments with similar hydrate saturation freshly formed. The enhancement effect of CH4 hydrate on the strength behaviors of HBSS would be more obvious under higher effective confining pressures. The peak strength increase of HBSS was not only due to the increase in cohesion component but also frictional component for a given hydrate saturation and porosity. Thermal decomposition of HBSS is governed directly by its hydrate saturation rather than the confining stress, although with higher confining stress the dissipation of the released gas is affected by the permeability of the sediments thus slightly prolonging the dissociation process.

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More information

Accepted/In Press date: 6 October 2019
e-pub ahead of print date: 9 October 2019
Published date: 1 December 2019
Keywords: Cohesive force, Hydrate-bearing silty sediments, Peak strength, Thermal decomposition

Identifiers

Local EPrints ID: 437119
URI: http://eprints.soton.ac.uk/id/eprint/437119
DOI: doi:10.1016/j.jngse.2019.103031
ISSN: 1875-5100
PURE UUID: 12f43cc9-8857-40bb-b087-0bbaa53dd3d2
ORCID for B. N. Madhusudhan: ORCID iD orcid.org/0000-0002-2570-5934

Catalogue record

Date deposited: 17 Jan 2020 17:34
Last modified: 18 Mar 2024 03:29

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Contributors

Author: Yongchen Song
Author: Tingting Luo
Author: B. N. Madhusudhan ORCID iD
Author: Xiang Sun
Author: Yu Liu
Author: Xianjing Kong
Author: Yanghui Li

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