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| Hauptseite > Publikationsdatenbank > Granite sliding on granite: friction, wear rates, surface topography, and the scale-dependence of rate–state effects |
| Hauptseite > Publikationsdatenbank > Granite sliding on granite: friction, wear rates, surface topography, and the scale-dependence of rate–state effects |
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| Hybrid-OA | 0.00 | 0.00 | EUR | (Publish and Read) | ZB | |
| Sum | 0.00 | 0.00 | EUR | |||
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| Journal Article | FZJ-2026-02282 |
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2026
IOP Publ.
Bristol
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Please use a persistent id in citations: doi:10.1088/1361-6633/ae4b66 doi:10.34734/FZJ-2026-02282
Abstract: We study tribological granite–granite contacts as a model for tectonic faulting, combining experiments, theory, and molecular dynamics simulations. The high friction in this system is not dominated by particulate wear or plowing, as frequently assumed, but by cold welding within plastically deformed asperity junctions. We base this conclusion on the observation that wear is repeatedly high after cleaning contacts but decreases as gouge accumulates, while friction shows the opposite trend. Moreover, adding water reduces wear by a factor of ten but barely decreases friction. Thermal and rate-dependent effects—central to most earthquake models—are negligible: friction remains unchanged between - 40 °C and 20°C, across abrupt velocity steps, and after hours of stationary contact. The absence of rate–state effects in our macroscopic samples is rationalized by the scale-dependence of pre-slip. The evolution of surface topography shows that quartz grains become locally smooth, with height spectra isotropic for wavelength below 10 microns but anisotropic at longer wavelengths, similar to natural faults. The resulting gouge particles have the usual characteristic sizes near 100 nm. Molecular dynamics simulations of a rigid, amorphous silica tip sliding on α-quartz reproduce not only similar friction coefficients near unity but also other experimentally observed features, including stress-introduced transitions to phases observed in post-mortem faults, as well as theoretical estimates of local flash temperatures. Additionally, they reveal a marked decrease of interfacial shear strength above 600 °C.
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