Calculating shear viscosity with confined non-equilibrium molecular dynamics: a case study on hematite - PAO-2 lubricant
Calculating shear viscosity with confined non-equilibrium molecular dynamics: a case study on hematite - PAO-2 lubricant
The behaviour of confined lubricants at the atomic scale as affected by the interactions at the surface-lubricant interface is relevant in a range of technological applications in areas such as the automotive industry. In this paper, by performing fully atomistic molecular dynamics, we investigate the regime where the viscosity starts to deviate from the bulk behaviour, a topic of great practical and scientific relevance. The simulations consist of setting up a shear flow by confining the lubricant between iron oxide surfaces. By using confined Non-Equilibrium Molecular Dynamics (NEMD) simulations at a pressure range of 0.1-1.0 GPa at 100 °C, we demonstrate that the film thickness of the fluid affects the behaviour of viscosity. We find that by increasing the number of lubricant molecules, we approach the viscosity value of the bulk fluid derived from previously published NEMD simulations for the same system. These changes in viscosity occurred at film thicknesses ranging from 10.12 to 55.93 Å. The viscosity deviations at different pressures between the system with the greatest number of lubricant molecules and the bulk simulations varied from −16% to 41%. The choice of the utilized force field for treating the atomic interactions was also investigated.
33994-34002
Mathas, Dimitrios
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Sarpa, Davide
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Holweger, Walter
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Wolf, Marcus
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Bohnert, Christof
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Bakolas, Vasilios
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Procelewska, Joanna
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Franke, Joerg
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Rödel, Philipp
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Skylaris, Chris-Kriton
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Mathas, Dimitrios
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Sarpa, Davide
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Holweger, Walter
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Wolf, Marcus
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Bohnert, Christof
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Bakolas, Vasilios
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Procelewska, Joanna
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Franke, Joerg
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Rödel, Philipp
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Skylaris, Chris-Kriton
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Mathas, Dimitrios, Sarpa, Davide, Holweger, Walter, Wolf, Marcus, Bohnert, Christof, Bakolas, Vasilios, Procelewska, Joanna, Franke, Joerg, Rödel, Philipp and Skylaris, Chris-Kriton
(2023)
Calculating shear viscosity with confined non-equilibrium molecular dynamics: a case study on hematite - PAO-2 lubricant.
RSC Advances, 13 (48), .
(doi:10.1039/d3ra06929j).
Abstract
The behaviour of confined lubricants at the atomic scale as affected by the interactions at the surface-lubricant interface is relevant in a range of technological applications in areas such as the automotive industry. In this paper, by performing fully atomistic molecular dynamics, we investigate the regime where the viscosity starts to deviate from the bulk behaviour, a topic of great practical and scientific relevance. The simulations consist of setting up a shear flow by confining the lubricant between iron oxide surfaces. By using confined Non-Equilibrium Molecular Dynamics (NEMD) simulations at a pressure range of 0.1-1.0 GPa at 100 °C, we demonstrate that the film thickness of the fluid affects the behaviour of viscosity. We find that by increasing the number of lubricant molecules, we approach the viscosity value of the bulk fluid derived from previously published NEMD simulations for the same system. These changes in viscosity occurred at film thicknesses ranging from 10.12 to 55.93 Å. The viscosity deviations at different pressures between the system with the greatest number of lubricant molecules and the bulk simulations varied from −16% to 41%. The choice of the utilized force field for treating the atomic interactions was also investigated.
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d3ra06929j
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Submitted date: 11 October 2023
Accepted/In Press date: 8 November 2023
e-pub ahead of print date: 21 November 2023
Additional Information:
Funding Information: D. S. and D. M. acknowledge the funding support of Schaeffler Technologies AG & Co. KG for their PhD studentship. The authors acknowledge use of the IRIDIS 5 High Performance Computing facility at the University of Southampton. We are grateful for computational support from the UK national high performance computing service, ARCHER2, for which access was obtained via the UKCP consortium and funded by EPSRC grant ref. EP/X035956/1 and EP/X035891/1. We are grateful for computational support from the UK Materials and Molecular Modelling Hub, which is partially funded by EPSRC (EP/T022213/1, EP/W032260/1 and EP/P020194/1), for which access was obtained via the UKCP consortium. The authors also thank Dr James P. Ewen for helpful discussions.
This journal is © The Royal Society of Chemistry.
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Local EPrints ID: 486002
URI: http://eprints.soton.ac.uk/id/eprint/486002
ISSN: 2046-2069
PURE UUID: fad416e2-88b5-4e58-9495-56e41734074f
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Date deposited: 05 Jan 2024 17:44
Last modified: 30 Aug 2024 01:40
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Author:
Dimitrios Mathas
Author:
Davide Sarpa
Author:
Marcus Wolf
Author:
Christof Bohnert
Author:
Vasilios Bakolas
Author:
Joanna Procelewska
Author:
Joerg Franke
Author:
Philipp Rödel
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