English

Theoretical framework for the atomistic modeling of frequency-dependent liquid-solid friction

Soft Condensed Matter 2021-11-29 v1 Chemical Physics Fluid Dynamics

Abstract

Nanofluidics shows great promise for energy conversion and desalination applications. The performance of nanofluidic devices is controlled by liquid-solid friction, quantified by the Navier friction coefficient (FC). Despite decades of research, there is no well-established generic framework to determine the frequency dependent Navier FC from atomistic simulations. Here, we have derived analytical expressions to connect the Navier FC to the random force autocorrelation on the confining wall, from the observation that the random force autocorrelation can be related to the hydrodynamic boundary condition, where the Navier FC appears. The analytical framework is generic in the sense that it explicitly includes the system size dependence and also the frequency dependence of the FC, which enabled us to address (i) the long-standing plateau issue in the evaluation of the FC and (ii) the non-Markovian behavior of liquid-solid friction of a Lennard-Jones liquid and of water on various walls and at various temperatures, including the supercooled regime. This new framework opens the way to explore the frequency dependent FC for a wide range of complex liquids.

Keywords

Cite

@article{arxiv.2107.06113,
  title  = {Theoretical framework for the atomistic modeling of frequency-dependent liquid-solid friction},
  author = {Haruki Oga and Takeshi Omori and Cecilia Herrero and Samy Merabia and Laurent Joly and Yasutaka Yamaguchi},
  journal= {arXiv preprint arXiv:2107.06113},
  year   = {2021}
}

Comments

5 pages, 3 figures

R2 v1 2026-06-24T04:09:14.577Z