An anisotropic model for the electrical resistivity of two-phase geologic materials
An anisotropic model for the electrical resistivity of two-phase geologic materials
Electrical and electromagnetic surveys of the seafloor provide valuable information about the macro and microscopic properties of subseafloor sediments. Sediment resistivity is highly variable and governed by a wide range of properties including pore-fluid salinity, pore-fluid saturation, porosity, pore geometry, and temperature. A new anisotropic, twophase, effective medium model describes the electrical resistivity of porous rocks and sediments. The only input parameters required are the resistivities of the solid and fluid components, their volume fractions and grain shape. The approach makes use of the increase in path length taken by an electrical current through an idealized granular medium comprising of aligned ellipsoidal grains. The model permits both solid and fluid phases to have a finite conductivity useful for dealing with surface charge conduction effects associated with clay minerals and gives results independent of grain size hence, valid for a wide range of sediment types. Furthermore, the model can be used to investigate the effects of grain aspect ratio and alignment on electrical resistivity anisotropy. Good agreement was found between the model predictions and laboratory measurements of resistivity and porosity on artificial sediments with known physical properties.
E161-E170
Ellis, Michelle H.
469e4852-7d33-49c3-a5bb-b9c9e19933bf
Sinha, Martin C.
794c3012-d0e8-4d2f-b328-c8cfd56c5976
Minshull, Tim A.
bf413fb5-849e-4389-acd7-0cb0d644e6b8
Sothcott, Jeremy
71ab4088-7b13-46d6-9e28-67538a02d595
Best, Angus I.
cad03726-10f8-4f90-a3ba-5031665234c9
November 2010
Ellis, Michelle H.
469e4852-7d33-49c3-a5bb-b9c9e19933bf
Sinha, Martin C.
794c3012-d0e8-4d2f-b328-c8cfd56c5976
Minshull, Tim A.
bf413fb5-849e-4389-acd7-0cb0d644e6b8
Sothcott, Jeremy
71ab4088-7b13-46d6-9e28-67538a02d595
Best, Angus I.
cad03726-10f8-4f90-a3ba-5031665234c9
Ellis, Michelle H., Sinha, Martin C., Minshull, Tim A., Sothcott, Jeremy and Best, Angus I.
(2010)
An anisotropic model for the electrical resistivity of two-phase geologic materials.
Geophysics, 75 (6), .
(doi:10.1190/1.3483875).
Abstract
Electrical and electromagnetic surveys of the seafloor provide valuable information about the macro and microscopic properties of subseafloor sediments. Sediment resistivity is highly variable and governed by a wide range of properties including pore-fluid salinity, pore-fluid saturation, porosity, pore geometry, and temperature. A new anisotropic, twophase, effective medium model describes the electrical resistivity of porous rocks and sediments. The only input parameters required are the resistivities of the solid and fluid components, their volume fractions and grain shape. The approach makes use of the increase in path length taken by an electrical current through an idealized granular medium comprising of aligned ellipsoidal grains. The model permits both solid and fluid phases to have a finite conductivity useful for dealing with surface charge conduction effects associated with clay minerals and gives results independent of grain size hence, valid for a wide range of sediment types. Furthermore, the model can be used to investigate the effects of grain aspect ratio and alignment on electrical resistivity anisotropy. Good agreement was found between the model predictions and laboratory measurements of resistivity and porosity on artificial sediments with known physical properties.
Text
Electrical_resistivity_v5.pdf
- Author's Original
More information
Published date: November 2010
Organisations:
Marine Geoscience
Identifiers
Local EPrints ID: 173633
URI: http://eprints.soton.ac.uk/id/eprint/173633
ISSN: 0016-8033
PURE UUID: 1d4ecc6c-cebd-4dc1-bfed-7f4d27b086a4
Catalogue record
Date deposited: 04 Feb 2011 13:34
Last modified: 14 Mar 2024 02:43
Export record
Altmetrics
Contributors
Author:
Michelle H. Ellis
Author:
Martin C. Sinha
Author:
Jeremy Sothcott
Author:
Angus I. Best
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
