Broad fault zones enable deep fluid transport and limit earthquake magnitudes
Broad fault zones enable deep fluid transport and limit earthquake magnitudes
Constraining the controlling factors of fault rupture is fundamentally important. Fluids influence earthquake locations and magnitudes, although the exact pathways through the lithosphere are not well-known. Ocean transform faults are ideal for studying faults and fluid pathways given their relative simplicity. We analyse seismicity recorded by the Passive Imaging of the Lithosphere-Asthenosphere Boundary (PI-LAB) experiment, centred around the Chain Fracture Zone. We find earthquakes beneath morphological transpressional features occur deeper than the brittle-ductile transition predicted by simple thermal models, but elsewhere occur shallower. These features are characterised by multiple parallel fault segments and step overs, higher proportions of smaller events, gaps in large historical earthquakes, and seismic velocity structures consistent with hydrothermal alteration. Therefore, broader fault damage zones preferentially facilitate fluid transport. This cools themantle and reduces the potential for large earthquakes at localized barriers that divide the transform into shorter asperity regions, limiting earthquake magnitudes on the transform.
Leptokaropoulos, Konstantinos
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Rychert, Catherine A.
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Harmon, Nicholas
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Schlaphorst, David
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Grevemeyer, Ingo
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Kendall, John-Michael
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Singh, Satish C.
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16 September 2023
Leptokaropoulos, Konstantinos
6176f4d8-7af0-4575-bf2c-5aaba3d182ce
Rychert, Catherine A.
70cf1e3a-58ea-455a-918a-1d570c5e53c5
Harmon, Nicholas
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Schlaphorst, David
ce763c91-8236-4eac-b256-b35a8613d62b
Grevemeyer, Ingo
e96d5dfd-f06d-4f34-bd1e-949f5d051601
Kendall, John-Michael
3baf9e58-0af9-44ba-9547-89d91ee0f365
Singh, Satish C.
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Leptokaropoulos, Konstantinos, Rychert, Catherine A., Harmon, Nicholas, Schlaphorst, David, Grevemeyer, Ingo, Kendall, John-Michael and Singh, Satish C.
(2023)
Broad fault zones enable deep fluid transport and limit earthquake magnitudes.
Nature Communications, 14 (1), [5748].
(doi:10.1038/s41467-023-41403-6).
Abstract
Constraining the controlling factors of fault rupture is fundamentally important. Fluids influence earthquake locations and magnitudes, although the exact pathways through the lithosphere are not well-known. Ocean transform faults are ideal for studying faults and fluid pathways given their relative simplicity. We analyse seismicity recorded by the Passive Imaging of the Lithosphere-Asthenosphere Boundary (PI-LAB) experiment, centred around the Chain Fracture Zone. We find earthquakes beneath morphological transpressional features occur deeper than the brittle-ductile transition predicted by simple thermal models, but elsewhere occur shallower. These features are characterised by multiple parallel fault segments and step overs, higher proportions of smaller events, gaps in large historical earthquakes, and seismic velocity structures consistent with hydrothermal alteration. Therefore, broader fault damage zones preferentially facilitate fluid transport. This cools themantle and reduces the potential for large earthquakes at localized barriers that divide the transform into shorter asperity regions, limiting earthquake magnitudes on the transform.
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s41467-023-41403-6
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Accepted/In Press date: 1 September 2023
Published date: 16 September 2023
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Funding Information:
The authors acknowledge funding from the Natural Environment Research Council (NE/M003507/1) (K.L., C.A.R and N.H.) (NE/M004643/1) (J.M.K), the European Research Council (GA 638665) (K.L., C.A.R. and N.H.) and the National Science Foundation (grants NSF-EAR-2147918 and NSF-OCE-231613) (C.A.R). We thank the captain and crew of the R/V Marcus G. Langseth and the RRS Discovery, and the scientific technicians. The active source seismic data were acquired during the ILPAB-SPARC experiment on board the French R/V Pourquoi Pas? funded by the European Research Council Advanced Grant number 339442_TransAtlanticILAB. Refraction data were analyzed by Christian Filbrandt. We thank the editor, Dr. Sebastian Mueller and 4 anonymous reviewers for the constructive comments and suggestions.
Identifiers
Local EPrints ID: 483384
URI: http://eprints.soton.ac.uk/id/eprint/483384
ISSN: 2041-1723
PURE UUID: bf88ef17-3868-4c83-a416-cb37fecf310b
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Date deposited: 30 Oct 2023 12:32
Last modified: 18 Mar 2024 04:00
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Author:
David Schlaphorst
Author:
Ingo Grevemeyer
Author:
John-Michael Kendall
Author:
Satish C. Singh
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