Load-velocity-temperature relationship in frictional response of microscopic contacts
Wengen Ouyang, Yao Cheng, Ming Ma, Michael Urbakh

TL;DR
This paper presents an analytical model for microscopic frictional contacts that predicts how friction depends on velocity, temperature, and load, aligning with experimental observations and enabling extrapolation to nanoscale conditions.
Contribution
The authors developed a novel analytical framework for microscopic friction that accounts for multiple contact types and predicts new velocity-temperature dependencies.
Findings
Predicts velocity-temperature scaling based on contact rupture dynamics.
Identifies double-peaked friction dependencies for interfaces with two contact types.
Provides a method to extrapolate nanoscale friction behavior from experimental data.
Abstract
Frictional properties of interfaces with dynamic chemical bonds have been the subject of intensive experimental investigation and modeling, as it provides important insights into the molecular origin of the empirical rate and state laws, which have been highly successful in describing friction from nano to geophysical scales. Using previously developed theoretical approaches requires time-consuming simulations that are impractical for many realistic tribological systems. To solve this problem and set a framework for understanding microscopic mechanisms of friction at interfaces including multiple microscopic contacts, we developed an analytical approach for description of friction mediated by dynamical formation and rupture of microscopic interfacial contacts, which allows to calculate frictional properties on the time and length scales that are relevant to tribological experimental…
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