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Title
Effects of vdW Interaction and Electric Field on Friction in MoS2
Authors
Keywords
First principles, Friction, Sliding, MoS<sub>2</sub>, Electric field, vdW interaction
Journal
TRIBOLOGY LETTERS
Volume 59, Issue 1, Pages -
Publisher
Springer Nature
Online
2015-05-21
DOI
10.1007/s11249-015-0531-4
References
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- (2014) G. Levita et al. Journal of Physical Chemistry C
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- Advancements in superlubricity
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