Molecular dynamics simulation of atomic friction: A review and guide

Dong, Yalin; Li, Qunyang; Martini, Ashlie

doi:10.1116/1.4794357

Cited by 167 publications

(134 citation statements)

References 179 publications

(295 reference statements)

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“…Szlufarska et al reviewed experimental and theoretical studies of wet and dry friction specifically in the area of nanotribology in 2008 [11]. In 2013, Vanossi et al [12] summarised advances in nanoscale to mesoscale modelling of wet and dry friction while and in the same year Dong et al [13] discussed NEMD studies of dry friction in the context of atomic force microscopy (AFM) experiments. In 2014, Sawyer et al [14] provided a more general overview of recent advances in the understanding of dry friction, including the contribution of NEMD.…”

Section: The Modern Molecular Approach To Viscosity Proceeds Via the mentioning

confidence: 99%

Advances in nonequilibrium molecular dynamics simulations of lubricants and additives

2018

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Nonequilibrium molecular dynamics (NEMD) simulations have provided unique insights into the nanoscale behaviour of lubricants under shear. This review discusses the early history of NEMD and its progression from a tool to corroborate theories of the liquid state, to an instrument that can directly evaluate important fluid properties, towards a potential design tool in tribology. The key methodological advances which have allowed this evolution are also highlighted. This is followed by a summary of bulk and confined NEMD simulations of liquid lubricants and lubricant additives, as they have progressed from simple atomic fluids to ever more complex, realistic molecules. The future outlook of NEMD in tribology, including the inclusion of chemical reactivity for additives, and coupling to continuum methods for large systems, is also briefly discussed.

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Section: The Modern Molecular Approach To Viscosity Proceeds Via the mentioning

confidence: 99%

Advances in nonequilibrium molecular dynamics simulations of lubricants and additives

2018

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“…More importantly, the lack of a robust potential energy function to simulate elevated temperature contact loading processes of silicon is still a key problem. This is perhaps the reason that most of the atomic scale simulation studies on silicon using the MD simulation have been performed at low temperatures [1,12]. From the available literature, the two appropriate three body potentials which were evaluated for their use in this study are an analytical bond order potential (ABOP) [13] and a modified version of Tersoff potential [14].…”

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Influence of temperature on the anisotropic cutting behaviour of single crystal silicon: A molecular dynamics simulation investigation

Chavoshi

Goel

Luo

2016

Journal of Manufacturing Processes

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Using molecular dynamics (MD) simulation, this paper investigates anisotropic cutting behaviour of single crystal silicon in vacuum under a wide range of substrate temperatures (300 K, 500 K, 750 K, 850 K, 1173 K and 1500 K). Specific cutting energy, force ratio, stress in the cutting zone and cutting temperature were the indicators used to quantify the differences in the cutting behaviour of silicon. A key observation was that the specific cutting energy required to cut the (111) surface of silicon and the von Mises stress to yield the silicon reduces by 25% and 32%, respectively, at 1173 K compared to what is required at 300 K. The room temperature cutting anisotropy in the von Mises stress and the room temperature cutting anisotropy in the specific cutting energy (work done by the tool in removing unit volume of material) were obtained as 12% and 16% respectively. It was observed that this changes to 20% and 40%, respectively, when cutting was performed at 1500 K, signifying a very strong correlation between the anisotropy observed during cutting and the machining temperature.Furthermore, using the atomic strain criterion, the width of primary shear zone was found to vary with the orientation of workpiece surface and temperature i.e. it remains narrower while cutting the (111) surface of silicon or at higher machining temperatures. A major anecdote of 2 the study based on the potential function employed in the study is that, irrespective of the cutting plane or the cutting temperature, the state of the cutting edge of the diamond tool did not show direct diamond to graphitic phase transformation.

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“…However, validating models quantitatively, understanding how energy is dissipated, and describing the atomic-level processes by which slip occurs dynamically at the interface are beyond the capabilities of the PTT model and are challenging because of the inaccessibility of the buried interface in experiments. Therefore, stick-slip is often considered using molecular dynamics (MD) simulations, which provides a means of directly observing atomic interactions within the interface [14,15]. However, the scanning speeds of AFM and MD have yet to overlap.…”

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confidence: 99%

Dynamics of Atomic Stick-Slip Friction Examined with Atomic Force Microscopy and Atomistic Simulations at Overlapping Speeds

Liu

Dong

et al. 2015

Phys. Rev. Lett.

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Molecular dynamics simulation of atomic friction: A review and guide

Cited by 167 publications

References 179 publications

Advances in nonequilibrium molecular dynamics simulations of lubricants and additives

Advances in nonequilibrium molecular dynamics simulations of lubricants and additives

Influence of temperature on the anisotropic cutting behaviour of single crystal silicon: A molecular dynamics simulation investigation

Dynamics of Atomic Stick-Slip Friction Examined with Atomic Force Microscopy and Atomistic Simulations at Overlapping Speeds

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