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Inherited structural controls on fault geometry, architecture and hydrothermal activity: an example from Grimsel Pass, Switzerland

Inherited structural controls on fault geometry, architecture and hydrothermal activity: an example from Grimsel Pass, Switzerland
Inherited structural controls on fault geometry, architecture and hydrothermal activity: an example from Grimsel Pass, Switzerland

Exhumed faults hosting hydrothermal systems provide direct insight into relationships between faulting and fluid flow, which in turn are valuable for making hydrogeological predictions in blind settings. The Grimsel Breccia Fault (Aar massif, Central Swiss Alps) is a late Neogene, exhumed dextral strike-slip fault with a maximum displacement of 25–45 m, and is associated with both fossil and active hydrothermal circulation. We mapped the fault system and modelled it in three dimensions, using the distinctive hydrothermal mineralisation as well as active thermal fluid discharge (the highest elevation documented in the Alps) to reveal the structural controls on fluid pathway extent and morphology. With progressive uplift and cooling, brittle deformation inherited the mylonitic shear zone network at Grimsel Pass; preconditioning fault geometry into segmented brittle reactivations of ductile shear zones and brittle inter-shear zone linkages. We describe ‘pipe’-like, vertically oriented fluid pathways: (1) within brittle fault linkage zones and (2) through along-strike-restricted segments of formerly ductile shear zones reactivated by brittle deformation. In both cases, low-permeability mylonitic shear zones that escaped brittle reactivation provide important hydraulic seals. These observations show that fluid flow along brittle fault planes is not planar, but rather highly channelised into sub-vertical flow domains, with important implications for the exploration and exploitation of geothermal energy.

Brittle deformation, Crystalline basement, Fluid pathways, Geothermal, Structural inheritance, Structure
1661-8726
345-364
Belgrano, Thomas M.
6135b1b8-ca0f-41a6-a94a-6b6c3513dee3
Herwegh, Marco
8485d324-7e22-4842-bbe3-490850165921
Berger, Alfons
8397674a-7eb7-4881-9911-df7ae3c90079
Belgrano, Thomas M.
6135b1b8-ca0f-41a6-a94a-6b6c3513dee3
Herwegh, Marco
8485d324-7e22-4842-bbe3-490850165921
Berger, Alfons
8397674a-7eb7-4881-9911-df7ae3c90079

Belgrano, Thomas M., Herwegh, Marco and Berger, Alfons (2016) Inherited structural controls on fault geometry, architecture and hydrothermal activity: an example from Grimsel Pass, Switzerland. Swiss Journal of Geosciences, 109 (3), 345-364. (doi:10.1007/s00015-016-0212-9).

Record type: Article

Abstract

Exhumed faults hosting hydrothermal systems provide direct insight into relationships between faulting and fluid flow, which in turn are valuable for making hydrogeological predictions in blind settings. The Grimsel Breccia Fault (Aar massif, Central Swiss Alps) is a late Neogene, exhumed dextral strike-slip fault with a maximum displacement of 25–45 m, and is associated with both fossil and active hydrothermal circulation. We mapped the fault system and modelled it in three dimensions, using the distinctive hydrothermal mineralisation as well as active thermal fluid discharge (the highest elevation documented in the Alps) to reveal the structural controls on fluid pathway extent and morphology. With progressive uplift and cooling, brittle deformation inherited the mylonitic shear zone network at Grimsel Pass; preconditioning fault geometry into segmented brittle reactivations of ductile shear zones and brittle inter-shear zone linkages. We describe ‘pipe’-like, vertically oriented fluid pathways: (1) within brittle fault linkage zones and (2) through along-strike-restricted segments of formerly ductile shear zones reactivated by brittle deformation. In both cases, low-permeability mylonitic shear zones that escaped brittle reactivation provide important hydraulic seals. These observations show that fluid flow along brittle fault planes is not planar, but rather highly channelised into sub-vertical flow domains, with important implications for the exploration and exploitation of geothermal energy.

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More information

e-pub ahead of print date: 6 April 2016
Published date: 1 December 2016
Additional Information: Publisher Copyright: © 2016, Swiss Geological Society.
Keywords: Brittle deformation, Crystalline basement, Fluid pathways, Geothermal, Structural inheritance, Structure
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Identifiers

Local EPrints ID: 471180
URI: http://eprints.soton.ac.uk/id/eprint/471180
DOI: doi:10.1007/s00015-016-0212-9
ISSN: 1661-8726
PURE UUID: ceabed1d-841a-4c80-bcf5-1971ea1a422e

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Date deposited: 31 Oct 2022 17:31
Last modified: 16 Mar 2024 21:46

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Contributors

Author: Thomas M. Belgrano
Author: Marco Herwegh
Author: Alfons Berger

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