材料科学
硫系化合物
纳米尺度
摩擦学
纳米核糖学
单层
硫族元素
晶格常数
纳米技术
过渡金属
分子动力学
化学物理
凝聚态物理
复合材料
结晶学
冶金
计算化学
化学
衍射
光学
催化作用
物理
生物化学
作者
Mohammad R. Vazirisereshk,Kathryn Hasz,Meng‐Qiang Zhao,A. T. Charlie Johnson,Robert W. Carpick,Ashlie Martini
出处
期刊:ACS Nano
[American Chemical Society]
日期:2020-10-22
卷期号:14 (11): 16013-16021
被引量:62
标识
DOI:10.1021/acsnano.0c07558
摘要
Despite extensive research on the tribological properties of MoS2, the frictional characteristics of other members of the transition-metal dichalcogenide (TMD) family have remained relatively unexplored. To understand the effect of the chalcogen on the tribological behavior of these materials and gain broader general insights into the factors controlling friction at the nanoscale, we compared the friction force behavior for a nanoscale single asperity sliding on MoS2, MoSe2, and MoTe2 in both bulk and monolayer forms through a combination of atomic force microscopy experiments and molecular dynamics simulations. Experiments and simulations showed that, under otherwise identical conditions, MoS2 has the highest friction among these materials and MoTe2 has the lowest. Simulations complemented by theoretical analysis based on the Prandtl–Tomlinson model revealed that the observed friction contrast between the TMDs was attributable to their lattice constants, which differed depending on the chalcogen. While the corrugation amplitudes of the energy landscapes are similar for all three materials, larger lattice constants permit the tip to slide more easily across correspondingly wider saddle points in the potential energy landscape. These results emphasize the critical role of the lattice constant, which can be the determining factor for frictional behavior at the nanoscale.
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