2014
DOI: 10.1021/jp4098099
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Sliding Properties of MoS2 Layers: Load and Interlayer Orientation Effects

Abstract: Among the members of the transition metal dichalcogenides (TMD) family, molybdenum disulfide has the most consolidated application outcomes in tribological fields. However, despite the growing usage as nanostructured solid lubricant due to its lamellar structure, little is known about the atomistic interactions taking place at the interface between two MoS2 sliding layers, especially at high loads. By means of ab initio modeling of the static potential energy surface and charge distribution analysis, we demons… Show more

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Cited by 120 publications
(120 citation statements)
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“…In Table 3 we also report calculated nanomechanical properties (E bind , γ and τ y ) that underpin bilayer shear behaviour. Values for MoS 2 are in good agreement with previous DFT results reported by Levita et al 32,33 Focusing on MoX 2 stoichiometries, the electronic contributions to the interlayer attraction (repulsion) at the global energy minimum (maximum) are evident in the charge density difference plots: § presented in Fig 5 are the charge density difference isosurfaces for the global energy minimum and maximum of MoS 2 , and the corresponding plane-averaged charge density profiles for all MoX 2 stoichiometries are shown in Fig 6. For extra clarity, individual charge density profiles for each TMD, showing atomic positions within the cell, can be found in the ESI. Further detailed analysis of the potential energy vs. charge density relationship is also provided in the ESI, in which we detail the changes in potential energy vs. the integral of charge density accumulation at the interface for each unique geometry.…”
Section: Commensurate Bilayerssupporting
confidence: 91%
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“…In Table 3 we also report calculated nanomechanical properties (E bind , γ and τ y ) that underpin bilayer shear behaviour. Values for MoS 2 are in good agreement with previous DFT results reported by Levita et al 32,33 Focusing on MoX 2 stoichiometries, the electronic contributions to the interlayer attraction (repulsion) at the global energy minimum (maximum) are evident in the charge density difference plots: § presented in Fig 5 are the charge density difference isosurfaces for the global energy minimum and maximum of MoS 2 , and the corresponding plane-averaged charge density profiles for all MoX 2 stoichiometries are shown in Fig 6. For extra clarity, individual charge density profiles for each TMD, showing atomic positions within the cell, can be found in the ESI. Further detailed analysis of the potential energy vs. charge density relationship is also provided in the ESI, in which we detail the changes in potential energy vs. the integral of charge density accumulation at the interface for each unique geometry.…”
Section: Commensurate Bilayerssupporting
confidence: 91%
“…In concurrence with previous density functional calculations, 32,33 generating the sliding potential energy profile entails calculating the potential energy as the origin of the upper MX 2 layer is shifted along the long-diagonal of the unit cell, corresponding to the [1100] direction, represented by distance 'y' in Fig 2. Incommensurate bilayers were attained using accidental angular commensurations.…”
Section: Methodsmentioning
confidence: 66%
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