Discrete element modelling of geomechanical behaviour of methane hydrate soils with pore-filling hydrate distribution

J. Brugada; Y. P. Cheng; K. Soga; Juan Carlos Santamarina

doi:10.1007/s10035-010-0210-y

Discrete element modelling of geomechanical behaviour of methane hydrate soils with pore-filling hydrate distribution

J. Brugada^*, Y. P. Cheng, K. Soga, Juan Carlos Santamarina

^*Corresponding author for this work

Physical Sciences and Engineering

Research output: Contribution to journal › Article › peer-review

138 Scopus citations

Abstract

Methane hydrate soil is a natural soil deposit that contains methane hydrate in its pores. The micro-scale processes of the geomechanical behaviour of methane hydrate-bearing soils are investigated by the Discrete Element method (DEM). A series of DEM simulations of triaxial compression tests were performed to study the influence of methane hydrate saturation (S _h ) on the stress-strain relationship, the volumetric response and on the macroscopic geomechanical properties such as friction and dilation angle. Results of the numerical simulations are compared with laboratory triaxial test data performed on sandy methane hydrate samples. The simulations showed that for the pore-filling case, the hydrate contribution to the strength of the sediment is of a frictional nature, rather than of a cohesive nature.

Original language	English (US)
Pages (from-to)	517-525
Number of pages	9
Journal	Granular Matter
Volume	12
Issue number	5
DOIs	https://doi.org/10.1007/s10035-010-0210-y
State	Published - Oct 1 2010

Keywords

Discrete element
Methane hydrates
Pore-filling
Triaxial drained tests

ASJC Scopus subject areas

Materials Science(all)
Mechanics of Materials
Physics and Astronomy(all)

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10.1007/s10035-010-0210-y

Cite this

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title = "Discrete element modelling of geomechanical behaviour of methane hydrate soils with pore-filling hydrate distribution",

abstract = "Methane hydrate soil is a natural soil deposit that contains methane hydrate in its pores. The micro-scale processes of the geomechanical behaviour of methane hydrate-bearing soils are investigated by the Discrete Element method (DEM). A series of DEM simulations of triaxial compression tests were performed to study the influence of methane hydrate saturation (S h ) on the stress-strain relationship, the volumetric response and on the macroscopic geomechanical properties such as friction and dilation angle. Results of the numerical simulations are compared with laboratory triaxial test data performed on sandy methane hydrate samples. The simulations showed that for the pore-filling case, the hydrate contribution to the strength of the sediment is of a frictional nature, rather than of a cohesive nature.",

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T1 - Discrete element modelling of geomechanical behaviour of methane hydrate soils with pore-filling hydrate distribution

AU - Brugada, J.

AU - Cheng, Y. P.

AU - Soga, K.

AU - Santamarina, Juan Carlos

PY - 2010/10/1

Y1 - 2010/10/1

N2 - Methane hydrate soil is a natural soil deposit that contains methane hydrate in its pores. The micro-scale processes of the geomechanical behaviour of methane hydrate-bearing soils are investigated by the Discrete Element method (DEM). A series of DEM simulations of triaxial compression tests were performed to study the influence of methane hydrate saturation (S h ) on the stress-strain relationship, the volumetric response and on the macroscopic geomechanical properties such as friction and dilation angle. Results of the numerical simulations are compared with laboratory triaxial test data performed on sandy methane hydrate samples. The simulations showed that for the pore-filling case, the hydrate contribution to the strength of the sediment is of a frictional nature, rather than of a cohesive nature.

AB - Methane hydrate soil is a natural soil deposit that contains methane hydrate in its pores. The micro-scale processes of the geomechanical behaviour of methane hydrate-bearing soils are investigated by the Discrete Element method (DEM). A series of DEM simulations of triaxial compression tests were performed to study the influence of methane hydrate saturation (S h ) on the stress-strain relationship, the volumetric response and on the macroscopic geomechanical properties such as friction and dilation angle. Results of the numerical simulations are compared with laboratory triaxial test data performed on sandy methane hydrate samples. The simulations showed that for the pore-filling case, the hydrate contribution to the strength of the sediment is of a frictional nature, rather than of a cohesive nature.

KW - Discrete element

KW - Methane hydrates

KW - Pore-filling

KW - Triaxial drained tests

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Discrete element modelling of geomechanical behaviour of methane hydrate soils with pore-filling hydrate distribution

Abstract

Keywords

ASJC Scopus subject areas

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