Sediment microstructure and the establishment of gas migration pathways during bubble growth
Sediment microstructure and the establishment of gas migration pathways during bubble growth
Soft sediments exhibit complex and varied deformation behavior during in situ bubble growth; however, the sediment microstructure is often neglected when predicting bubble networking or fracture propagation dynamics. This study considers three chemically similar Mg(OH)2-rich sediments, which differ slightly in their particle size distributions and morphologies but exhibit significant differences in their porosity, stiffness, and pore throat dimensions at equivalent yield strengths. At low yield strengths, microstructure greatly influenced the size distribution and connectivity of spherical bubble populations, with narrow sedimentary pore throats promoting coarser bubbles with diminished connectivity. Increased connectivity of the bubble population appeared highly significant in limiting bed expansion, either by establishing pathways for gas release or by dissipating excess internal bubble pressure, thereby diminishing further growth. During in situ gas generation, each sediment demonstrated a critical fracture strength, which demarcated the populations with high void fractions (0.27 < ν < 0.4) of near-spherical bubbles from a fracturing regime supporting reduced void fractions (ν ≈ 0.15) of high aspect ratio cracks. However, critical fracture strengths varied significantly (in the 60–1000 Pa range) between sediments, with coarser-grained and higher porosity sediments promoting fracture at lower strengths. Fracture propagation greatly enhanced the connectivity and diminished the tortuosity of the void networks, thereby augmenting the continuous gas release flux.
12882-12892
Johnson, Michael
63c7d31d-7879-41d7-8080-90bf7a9e45a9
Peakall, Jeffrey
9bbaf650-71db-495c-9f01-19918cd2c81b
Fairweather, Michael
940f28af-e19b-45bd-8c22-05e46ea28d35
Barnes, Martyn
db6f7235-2bc5-48dc-a00e-61dc64f6aa39
Davison, Sushma
afef4229-29f3-46ac-a150-c48973e8a7ac
Jia, Xiaodong
c1b9d029-089a-4954-840a-0e4c03f63452
Clare, Michael A.
b26da858-9c08-4784-aaa9-7092efcd94bd
Harbottle, David
9e6cbfee-ea18-4648-9b2a-ab1ad1127c01
Hunter, Timothy N.
eff93732-ec27-4c46-8bbf-e4acb159d9cb
30 September 2019
Johnson, Michael
63c7d31d-7879-41d7-8080-90bf7a9e45a9
Peakall, Jeffrey
9bbaf650-71db-495c-9f01-19918cd2c81b
Fairweather, Michael
940f28af-e19b-45bd-8c22-05e46ea28d35
Barnes, Martyn
db6f7235-2bc5-48dc-a00e-61dc64f6aa39
Davison, Sushma
afef4229-29f3-46ac-a150-c48973e8a7ac
Jia, Xiaodong
c1b9d029-089a-4954-840a-0e4c03f63452
Clare, Michael A.
b26da858-9c08-4784-aaa9-7092efcd94bd
Harbottle, David
9e6cbfee-ea18-4648-9b2a-ab1ad1127c01
Hunter, Timothy N.
eff93732-ec27-4c46-8bbf-e4acb159d9cb
Johnson, Michael, Peakall, Jeffrey, Fairweather, Michael, Barnes, Martyn, Davison, Sushma, Jia, Xiaodong, Clare, Michael A., Harbottle, David and Hunter, Timothy N.
(2019)
Sediment microstructure and the establishment of gas migration pathways during bubble growth.
Environmental Science & Technology, 53 (21), .
(doi:10.1021/acs.est.9b03034).
Abstract
Soft sediments exhibit complex and varied deformation behavior during in situ bubble growth; however, the sediment microstructure is often neglected when predicting bubble networking or fracture propagation dynamics. This study considers three chemically similar Mg(OH)2-rich sediments, which differ slightly in their particle size distributions and morphologies but exhibit significant differences in their porosity, stiffness, and pore throat dimensions at equivalent yield strengths. At low yield strengths, microstructure greatly influenced the size distribution and connectivity of spherical bubble populations, with narrow sedimentary pore throats promoting coarser bubbles with diminished connectivity. Increased connectivity of the bubble population appeared highly significant in limiting bed expansion, either by establishing pathways for gas release or by dissipating excess internal bubble pressure, thereby diminishing further growth. During in situ gas generation, each sediment demonstrated a critical fracture strength, which demarcated the populations with high void fractions (0.27 < ν < 0.4) of near-spherical bubbles from a fracturing regime supporting reduced void fractions (ν ≈ 0.15) of high aspect ratio cracks. However, critical fracture strengths varied significantly (in the 60–1000 Pa range) between sediments, with coarser-grained and higher porosity sediments promoting fracture at lower strengths. Fracture propagation greatly enhanced the connectivity and diminished the tortuosity of the void networks, thereby augmenting the continuous gas release flux.
Text
acs.est.9b03034
- Accepted Manuscript
More information
Accepted/In Press date: 30 September 2019
Published date: 30 September 2019
Identifiers
Local EPrints ID: 437138
URI: http://eprints.soton.ac.uk/id/eprint/437138
ISSN: 0013-936X
PURE UUID: 17ad177e-7760-4a4d-b83c-f23372efc8e8
Catalogue record
Date deposited: 17 Jan 2020 17:35
Last modified: 16 Mar 2024 08:17
Export record
Altmetrics
Contributors
Author:
Michael Johnson
Author:
Jeffrey Peakall
Author:
Michael Fairweather
Author:
Martyn Barnes
Author:
Sushma Davison
Author:
Xiaodong Jia
Author:
Michael A. Clare
Author:
David Harbottle
Author:
Timothy N. Hunter
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics