Recent advances in single-asperity nanotribology

Szlufarska, Izabela; Chandross, Michael; Carpick, Robert W.

doi:10.1088/0022-3727/41/12/123001

Cited by 403 publications

(358 citation statements)

References 329 publications

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“…In 2004, Urbakh et al summarised experimental and theoretical contributions to the fundamental understanding of both wet and dry friction [2]. 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.…”

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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“…Before doing so, in order to get a better insight on the problem we will briefly describe some of the main properties of the system for a perfect lattice ͑⑀ =0͒. 4,6,[8][9][10][11][12][13] For this case, the main results are shown in Fig. 2͑a͒ where we present the friction force as a function of the corrugation potential amplitude U o at small velocity ͑v s =10 nm/ s͒.…”

Section: Surface Disorder Without Temperaturementioning

confidence: 99%

“…Furthermore, as the interaction between two surfaces involves complex interactions among many asperities, the atomic force microscopy is an exceptional tool to better understand friction at nanoscale level since it can be described essentially as a single asperity dragged along a surface. 4,8 Most theoretical efforts to describe the force friction microscopy experiments have focused on the behavior of defect free and perfect periodic surfaces with or without the inclusion of thermal effects. [9][10][11][12] However, the study of the effect of substrate disorder or defects on atomic friction is particularly important since atomically flat surfaces represent ideal models and disorder and defects of different kind are always present in nature.…”

Section: Introductionmentioning

confidence: 99%

Effects of surface disorder and temperature on atomic friction

Fajardo

Mazo

2010

Phys. Rev. B

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We have investigated the effect of surface disorder on atomic friction in the stick-slip dynamical regime of a one-dimensional Prandtl-Tomlinson model. We find that disorder in the substrate potential can modify the mean slip length and then it changes the friction force of the system. In particular, the effect of the disorder is more important at low temperatures and close to dynamical transition points or at high loads. We show results for different values of temperature, amplitude of the corrugation potential, dragging velocity, and damping. Special care is put in the comparison between the results of the regular and the disordered cases at many different temperatures and in the understanding of the combined effect of disorder and temperature in the dynamics of the system. To finish, we present some results on the robustness of the results against a change in the effective damping of the system.

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“…The purpose of this work is to unveil the origin of wear for nt Cu at the nanoscale, which is expected to advance our understanding of the atomic nature of tribological behavior of nanostructured materials. [13][14][15][16][17][18] Recent experimental tests and atomistic simulations have shown that the strength of nt Cu has a strong dependence on twin boundary spacing (TBS). [19][20][21] The strength of nt Cu first increases with decreasing TBS in a Hall-Petch manner.…”

Section: Introductionmentioning

confidence: 99%

Twin boundary spacing-dependent friction in nanotwinned copper

et al. 2012

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The deformation mechanisms of nanotwinned Cu subjected to nanoscratching are investigated by means of molecular dynamics simulations. Scratching simulations on nanotwinned single-crystalline Cu with the twin planes parallel and perpendicular to the scratching direction are performed. Since the detwinning mechanism is completely suppressed in the former case, no apparent correlation between frictional coefficient and the twin spacing is observed. In samples where the twin planes are perpendicular to the scratching direction, the friction increases as the twin spacing decreases, and then decreases as the twin spacings become even smaller. It results from the competitive plastic deformation between the inclined dislocations and the detwinning mechanism. Subsequent simulations for nanotwinned polycrystalline Cu unveil that in addition to the grainboundary-associated deformation mechanism, dislocation-mediated detwinning plays a significant role in the plastic deformation of nanotwinned Cu. The twin boundary spacing in turn affects nanotwinned materials to resist scratching via plastic deformation. We demonstrate via the nanoscratching tests that there exists a critical twin boundary spacing for which the friction coefficient is maximized and that this transition results from the competing deformation mechanisms in those nanotwinned materials.

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Recent advances in single-asperity nanotribology

Cited by 403 publications

References 329 publications

Advances in nonequilibrium molecular dynamics simulations of lubricants and additives

Advances in nonequilibrium molecular dynamics simulations of lubricants and additives

Effects of surface disorder and temperature on atomic friction

Twin boundary spacing-dependent friction in nanotwinned copper

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