English

Effective stick-slip parameter for structurally lubric 2D interface friction

Materials Science 2024-04-09 v1 Mesoscale and Nanoscale Physics

Abstract

The wear-free sliding of layers or flakes of graphene-like 2D materials, important in many experimental systems, may occur either smoothly or through stick-slip, depending on driving conditions, corrugation, twist angles, as well as edges and defects. No single parameter has been so far identified to discriminate a priori between the two sliding regimes. Such a parameter, η\eta, does exist in the ideal (Prandtl-Tomlinson) problem of a point particle sliding across a 1D periodic lattice potential. In that case η>1\eta >1 implies mechanical instability, generally leading to stick-slip, with η=2π2U0Kpa2\eta = \frac{2\pi^2 U_0}{K_\mathrm{p} a^2}, where U0U_0 is the potential magnitude, aa the lattice spacing, and KpK_\mathrm{p} the pulling spring constant. Here we show, supported by a repertoire of graphene flake/graphene sliding simulations, that a similar stick-slip predictor ηeff\eta_\mathrm{eff} can be defined with the same form but suitably defined UeffU_\mathrm{eff}, aeffa_\mathrm{eff} and KeffK_\mathrm{eff}. Remarkably, simulations show that aeff=aa_\mathrm{eff} = a of the substrate remains an excellent approximation, while KeffK_\mathrm{eff} is an effective stiffness parameter, combining equipment and internal elasticity. Only the effective energy barrier UeffU_\mathrm{eff} needs to be estimated in order to predict whether stick-slip sliding of a 2D island or extended layer is expected or not. In a misaligned defect-free circular graphene sliding island of contact area AA, we show that UeffU_\mathrm{eff}, whose magnitude for a micrometer size diameter is of order 1 eV, scales as A1/4A^{1/4}, thus increasing very gently with size. The PT-like parameter ηeff\eta_\mathrm{eff} is therefore proposed as a valuable tool in 2D layer sliding.

Keywords

Cite

@article{arxiv.2401.13780,
  title  = {Effective stick-slip parameter for structurally lubric 2D interface friction},
  author = {Jin Wang and Andrea Vanossi and Erio Tosatti},
  journal= {arXiv preprint arXiv:2401.13780},
  year   = {2024}
}

Comments

submitted to Physical Review B

R2 v1 2026-06-28T14:26:21.480Z