Article ID | Journal | Published Year | Pages | File Type |
---|---|---|---|---|
799626 | Journal of the Mechanics and Physics of Solids | 2011 | 14 Pages |
The rate-and-state formulation of friction is well established as a phenomenological yet quantitative description of friction dynamics, in particular the onset of stick-slip instabilities arising from an oscillatory bifurcation. We first discuss the physical origins of two theories for the derivation of friction coefficients used in rate-and-state models, both derived from thermally activated rate processes. Secondly, we propose a general expression for the state evolution law in the form of a first order kinetics which describes the relaxation to a velocity dependent equilibrium interfacial state ϕss(v)ϕss(v) over a velocity dependent dynamic rejuvenation time-scale tϕ(v)tϕ(v). We show that the unknown relation ϕss(v)ϕss(v), defined as the ratio of tϕtϕ to a constant interfacial stationary healing time-scale t⁎⁎t⁎⁎, can be estimated directly from the experimental measurements of the steady-state friction coefficient and the critical stiffness for the onset of stick-slip behaviour of a spring-block system. Using a specific experimental dataset, we finally illustrate that this method provides the experimental measurements of the apparent memory length La(v)=vt⁎⁎ϕss(v) and the constant characteristic relaxation time t⁎⁎t⁎⁎ from which a constant intrinsic memory length L=V⁎t⁎⁎L=V⁎t⁎⁎ can be defined once a slip rate of reference V⁎V⁎ is chosen. As a result the complete state evolution law can be experimentally characterised.