Abstract
The mechanical behaviour of antigorite strongly influences the strength and deformation of the subduction interface. Although there is microstructural evidence elucidating the nature of brittle deformation at low pressures, there is often conflicting evidence regarding the potential for plastic deformation in the ductile regime at higher pressures. Here, we present a series of spherical nanoindentation experiments on aggregates of natural antigorite. These experiments effectively investigate the single-crystal mechanical behaviour because the volume of deformed material is significantly smaller than the grain size. Individual indents reveal elastic loading followed by yield and strain hardening. The magnitude of the yield stress is a function of crystal orientation, with lower values associated with indents parallel to the basal plane. Unloading paths reveal more strain recovery than expected for purely elastic unloading. The magnitude of inelastic strain recovery is highest for indents parallel to the basal plane. We also imposed indents with cyclical loading paths, and observed strain energy dissipation during unloading–loading cycles conducted up to a fixed maximum indentation load and depth. The magnitude of this dissipated strain energy was highest for indents parallel to the basal plane. Subsequent scanning electron microscopy revealed surface impressions accommodated by shear cracks and a general lack of dislocation-induced lattice misorientation. Based on these observations, we suggest that antigorite deformation at high pressures is dominated by sliding on shear cracks. We develop a microphysical model that is able to quantitatively explain Young’s modulus and dissipated strain energy data during cyclic loading experiments, based on either frictional or cohesive sliding of an array of cracks contained in the basal plane. This article is part of a discussion meeting issue ‘Serpentinite in the earth system’.
| Original language | English (US) |
|---|---|
| Article number | 20190197 |
| Journal | Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences |
| Volume | 378 |
| Issue number | 2165 |
| DOIs | |
| State | Published - Feb 21 2020 |
| Externally published | Yes |
Bibliographical note
Funding Information:Data accessibility. Experimental data are available from the UK National Geoscience Data Centre (http://www. bgs.ac.uk/services/ngdc/) or upon request to the corresponding author. Authors’ contributions. L.N.H. and N.B. designed the study. L.N.H. conducted the nanoindentation experiments and processed the data. E.C.D. and N.B. developed the model. L.N.H. and D.W. conducted the microscopy analysis. All authors contributed to data interpretation and writing the manuscript. Competing interests. We declare we have no competing interests. Funding. This work was supported by the Natural Environment Research Council through grant no. NE/M016471/1 to L.N.H. and N.B., and by the European Research Council under the European Union’s Horizon 2020 research and innovation programme (project RockDEaF, grant agreement no. 804685). Acknowledgements. We are grateful to Kathryn Kumamoto and Christopher Thom for useful discussions of nanoindentation. Luiz Morales provided useful insight into EBSD indexing of antigorite.
Publisher Copyright:
© 2020 The Author(s) Published by the Royal Society. All rights reserved.
Keywords
- Antigorite
- Cyclic loading
- Nanoindentation
- Shear cracks