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Main Authors: Civello, Carmelo, Maffioli, Luca, Smith, Edward, Ewen, James, Daivis, Peter, Dini, Daniele, Todd, Billy
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2603.21907
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author Civello, Carmelo
Maffioli, Luca
Smith, Edward
Ewen, James
Daivis, Peter
Dini, Daniele
Todd, Billy
author_facet Civello, Carmelo
Maffioli, Luca
Smith, Edward
Ewen, James
Daivis, Peter
Dini, Daniele
Todd, Billy
contents The transient time correlation function method (TTCF) has emerged as a powerful methodology for accurately probing systems at low shear rates. In the present study, TTCF was used to evaluate the shear rate dependence of the slip length in a high-slip system consisting of water confined between graphene walls at experimentally accessible shear rates, for which classical nonequilibrium molecular dynamics (NEMD) is unfeasible. The corresponding Navier friction coefficient was computed for all shear rates spanning six orders of magnitude and compared with the equilibrium limit. We report for the first time NEMD results obtained at experimentally accessible shear rates using the TTCF approach for a system that has attracted significant interest over the past decades. The slip length calculated with TTCF is in good agreement with previous equilibrium molecular dynamics simulations and experiments. Our aim here is to highlight the extraordinary power of TTCF, particularly for high-slip (low strain-rate) systems, and to verify that equilibrium methods directly match NEMD measurements at experimentally accessible strain rates.
format Preprint
id arxiv_https___arxiv_org_abs_2603_21907
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Molecular dynamics simulation of high slip flow of water confined between graphene nanochannels at experimentally accessible strain rates
Civello, Carmelo
Maffioli, Luca
Smith, Edward
Ewen, James
Daivis, Peter
Dini, Daniele
Todd, Billy
Chemical Physics
Materials Science
The transient time correlation function method (TTCF) has emerged as a powerful methodology for accurately probing systems at low shear rates. In the present study, TTCF was used to evaluate the shear rate dependence of the slip length in a high-slip system consisting of water confined between graphene walls at experimentally accessible shear rates, for which classical nonequilibrium molecular dynamics (NEMD) is unfeasible. The corresponding Navier friction coefficient was computed for all shear rates spanning six orders of magnitude and compared with the equilibrium limit. We report for the first time NEMD results obtained at experimentally accessible shear rates using the TTCF approach for a system that has attracted significant interest over the past decades. The slip length calculated with TTCF is in good agreement with previous equilibrium molecular dynamics simulations and experiments. Our aim here is to highlight the extraordinary power of TTCF, particularly for high-slip (low strain-rate) systems, and to verify that equilibrium methods directly match NEMD measurements at experimentally accessible strain rates.
title Molecular dynamics simulation of high slip flow of water confined between graphene nanochannels at experimentally accessible strain rates
topic Chemical Physics
Materials Science
url https://arxiv.org/abs/2603.21907