A new interpretation for the nature and significance of mirror-like surfaces in experimental carbonate-hosted seismic faults

Pozzi, G.; De Paola, N.; Nielsen, S.B.; Holdsworth, R.E.; Bowen, L.

doi:10.1130/g40197.1

A new interpretation for the nature and significance of mirror-like surfaces in experimental carbonate-hosted seismic faults

Pozzi, G.; De Paola, N.; Nielsen, S.B.; Holdsworth, R.E.; Bowen, L.

Authors

G. Pozzi

Professor Nicola De Paola nicola.de-paola@durham.ac.uk
Professor

Professor Stefan Nielsen stefan.nielsen@durham.ac.uk
Professor

Professor Bob Holdsworth r.e.holdsworth@durham.ac.uk
Professor

Leon Bowen leon.bowen@durham.ac.uk
Senior Manager (Electron Microscopy)

Abstract

Highly reflective, continuous smooth surfaces, known as "mirror-like surfaces" (MSs), have been observed in experimental carbonate-hosted faults, which were sheared at both seismic and aseismic velocities. MSs produced during high-velocity friction experiments (>0.1 m s–1) are typically interpreted to be frictional principal slip surfaces, where weakening mechanisms are activated by shear heating. We re-examined this model by performing friction experiments in a rotary shear apparatus on calcite gouge, at seismic velocities up to v = 1.4 m s–1 and normal stress σn = 25 MPa, to analyze the evolution of microstructures as displacement increases. After the onset of dynamic weakening, when the friction coefficients are low (μ << 0.6), sheared gouges consistently develop a well-defined, porosity-free principal slip zone (PSZ) of constant finite thickness (a few tens of micrometers) composed of nanometric material, which displays polygonal grain shapes. MSs occur at both boundaries of the PSZ, where they mark a sharp contrast in grain size with the sintered, much coarser material on either side of the PSZ. Our observations suggest that, with the onset of dynamic weakening, MSs partition the deformation by separating strong, sintered wall rocks from a central weak, actively deforming viscous PSZ. Therefore, the MSs do not correspond to frictional slip surfaces in the classical sense, but constitute sharp rheological boundaries, while, in the PSZ, shear is enhanced by thermal and grain-size–dependent mechanisms.

Citation

Pozzi, G., De Paola, N., Nielsen, S., Holdsworth, R., & Bowen, L. (2018). A new interpretation for the nature and significance of mirror-like surfaces in experimental carbonate-hosted seismic faults. Geology, 46(7), 583-586. https://doi.org/10.1130/g40197.1

Journal Article Type	Article
Acceptance Date	Apr 25, 2018
Online Publication Date	May 30, 2018
Publication Date	May 30, 2018
Deposit Date	Apr 26, 2018
Publicly Available Date	May 31, 2018
Journal	Geology
Print ISSN	0091-7613
Electronic ISSN	1943-2682
Publisher	Geological Society of America
Peer Reviewed	Peer Reviewed
Volume	46
Issue	7
Pages	583-586
DOI	https://doi.org/10.1130/g40197.1
Public URL	https://durham-repository.worktribe.com/output/1328116