First-principles comparative study on the interlayer adhesion and shear strength of transition-metal dichalcogenides and graphene
First-principles comparative study on the interlayer adhesion and shear strength of transition-metal dichalcogenides and graphene
Due to their layered structure, graphene and transition-metal dichalcogenides (TMDs) are easily sheared along the basal planes. Despite a growing attention towards their use as solid lubricants, so far no head-to-head comparison has been carried out. By means of ab initio modeling of a bilayer sliding motion, we show that graphene is characterized by a shallower potential energy landscape while more similarities are attained when considering the sliding forces; we propose that the calculated interfacial ideal shear strengths afford the most accurate information on the intrinsic sliding capability of layered materials. We also investigate the effect of an applied uniaxial load: in graphene, this introduces a limited increase in the sliding barrier while in TMDs it has a substantially different impact on the possible polytypes. The polytype presenting a parallel orientation of the layers (R0 ) bears more similarities to graphene while that with antiparallel orientation (R180 ) shows deep changes in the potential energy landscape and consequently a sharper increase of its sliding barrier
085434-[8pp]
Levita, G.
ef218c00-047c-4ec3-a056-b78237ca2e94
Molinari, E.
4b4dcaed-eeaa-4a3d-b850-59c02a467f0d
Polcar, T.
c669b663-3ba9-4e7b-9f97-8ef5655ac6d2
Righi, M.C.
0028a5e3-d7cc-4174-87b2-9f047f7d76de
31 August 2015
Levita, G.
ef218c00-047c-4ec3-a056-b78237ca2e94
Molinari, E.
4b4dcaed-eeaa-4a3d-b850-59c02a467f0d
Polcar, T.
c669b663-3ba9-4e7b-9f97-8ef5655ac6d2
Righi, M.C.
0028a5e3-d7cc-4174-87b2-9f047f7d76de
Levita, G., Molinari, E., Polcar, T. and Righi, M.C.
(2015)
First-principles comparative study on the interlayer adhesion and shear strength of transition-metal dichalcogenides and graphene.
Physical Review B, 92, .
(doi:10.1103/PhysRevB.92.085434).
Abstract
Due to their layered structure, graphene and transition-metal dichalcogenides (TMDs) are easily sheared along the basal planes. Despite a growing attention towards their use as solid lubricants, so far no head-to-head comparison has been carried out. By means of ab initio modeling of a bilayer sliding motion, we show that graphene is characterized by a shallower potential energy landscape while more similarities are attained when considering the sliding forces; we propose that the calculated interfacial ideal shear strengths afford the most accurate information on the intrinsic sliding capability of layered materials. We also investigate the effect of an applied uniaxial load: in graphene, this introduces a limited increase in the sliding barrier while in TMDs it has a substantially different impact on the possible polytypes. The polytype presenting a parallel orientation of the layers (R0 ) bears more similarities to graphene while that with antiparallel orientation (R180 ) shows deep changes in the potential energy landscape and consequently a sharper increase of its sliding barrier
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Published date: 31 August 2015
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nCATS Group
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Local EPrints ID: 382599
URI: http://eprints.soton.ac.uk/id/eprint/382599
ISSN: 1550-235X
PURE UUID: 51994978-6903-488b-af03-159fdbe5baf1
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Date deposited: 02 Nov 2015 13:36
Last modified: 15 Mar 2024 03:40
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Author:
G. Levita
Author:
E. Molinari
Author:
M.C. Righi
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