Electrical properties of methane hydrate + sediment mixtures
Electrical properties of methane hydrate + sediment mixtures
Knowledge of the electrical properties of multicomponent systems with gas hydrate, sediments, and pore water is needed to help relate electromagnetic (EM) measurements to specific gas hydrate concentration and distribution patterns in nature. Toward this goal, we built a pressure cell capable of measuring in situ electrical properties of multicomponent systems such that the effects of individual components and mixing relations can be assessed. We first established the temperature-dependent electrical conductivity (?) of pure, single-phase methane hydrate to be ~5 orders of magnitude lower than seawater, a substantial contrast that can help differentiate hydrate deposits from significantly more conductive water-saturated sediments in EM field surveys. Here we report ? measurements of two-component systems in which methane hydrate is mixed with variable amounts of quartz sand or glass beads. Sand by itself has low ? but is found to increase the overall ? of mixtures with well-connected methane hydrate. Alternatively, the overall ? decreases when sand concentrations are high enough to cause gas hydrate to be poorly connected, indicating that hydrate grains provide the primary conduction path. Our measurements suggest that impurities from sand induce chemical interactions and/or doping effects that result in higher electrical conductivity with lower temperature dependence. These results can be used in the modeling of massive or two-phase gas-hydrate-bearing systems devoid of conductive pore water. Further experiments that include a free water phase are the necessary next steps toward developing complex models relevant to most natural systems.
gas hydrates, electrical conductivity, methane, ice, ionic impurities, controlled source electromagnetics
4773-4783
Du Frane, Wyatt L.
21723751-e489-4753-a418-fd13b7308ef0
Stern, Laura A.
388e8e42-d758-43f2-947d-61dc1ff24346
Constable, Steven
f2ffd9c4-3738-435b-8a88-38dee97de7cc
Weitemeyer, Karen A.
22c524f6-b24d-4d2a-a46d-16b06c70a5d1
Smith, Megan M.
7c158386-bd92-42dc-8578-0796fdbe0136
Roberts, Jeffery J.
7e0ef107-b900-4597-b014-a18ec28cb6ed
July 2015
Du Frane, Wyatt L.
21723751-e489-4753-a418-fd13b7308ef0
Stern, Laura A.
388e8e42-d758-43f2-947d-61dc1ff24346
Constable, Steven
f2ffd9c4-3738-435b-8a88-38dee97de7cc
Weitemeyer, Karen A.
22c524f6-b24d-4d2a-a46d-16b06c70a5d1
Smith, Megan M.
7c158386-bd92-42dc-8578-0796fdbe0136
Roberts, Jeffery J.
7e0ef107-b900-4597-b014-a18ec28cb6ed
Du Frane, Wyatt L., Stern, Laura A., Constable, Steven, Weitemeyer, Karen A., Smith, Megan M. and Roberts, Jeffery J.
(2015)
Electrical properties of methane hydrate + sediment mixtures.
Journal of Geophysical Research: Solid Earth, 120 (7), .
(doi:10.1002/2015JB011940).
Abstract
Knowledge of the electrical properties of multicomponent systems with gas hydrate, sediments, and pore water is needed to help relate electromagnetic (EM) measurements to specific gas hydrate concentration and distribution patterns in nature. Toward this goal, we built a pressure cell capable of measuring in situ electrical properties of multicomponent systems such that the effects of individual components and mixing relations can be assessed. We first established the temperature-dependent electrical conductivity (?) of pure, single-phase methane hydrate to be ~5 orders of magnitude lower than seawater, a substantial contrast that can help differentiate hydrate deposits from significantly more conductive water-saturated sediments in EM field surveys. Here we report ? measurements of two-component systems in which methane hydrate is mixed with variable amounts of quartz sand or glass beads. Sand by itself has low ? but is found to increase the overall ? of mixtures with well-connected methane hydrate. Alternatively, the overall ? decreases when sand concentrations are high enough to cause gas hydrate to be poorly connected, indicating that hydrate grains provide the primary conduction path. Our measurements suggest that impurities from sand induce chemical interactions and/or doping effects that result in higher electrical conductivity with lower temperature dependence. These results can be used in the modeling of massive or two-phase gas-hydrate-bearing systems devoid of conductive pore water. Further experiments that include a free water phase are the necessary next steps toward developing complex models relevant to most natural systems.
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e-pub ahead of print date: 30 July 2015
Published date: July 2015
Keywords:
gas hydrates, electrical conductivity, methane, ice, ionic impurities, controlled source electromagnetics
Organisations:
Geology & Geophysics
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Local EPrints ID: 380031
URI: http://eprints.soton.ac.uk/id/eprint/380031
PURE UUID: 51ed701b-abc0-45c5-9b8f-d4a1e99f6015
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Date deposited: 04 Aug 2015 09:23
Last modified: 14 Mar 2024 20:53
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Contributors
Author:
Wyatt L. Du Frane
Author:
Laura A. Stern
Author:
Steven Constable
Author:
Karen A. Weitemeyer
Author:
Megan M. Smith
Author:
Jeffery J. Roberts
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