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Literature DB >> 25180979

Superlubricity of two-dimensional fluorographene/MoS2 heterostructure: a first-principles study.

Lin-Feng Wang¹, Tian-Bao Ma, Yuan-Zhong Hu, Quanshui Zheng, Hui Wang, Jianbin Luo.

Abstract

The atomic-scale friction of the fluorographene (FG)/MoS2 heterostructure is investigated using first-principles calculations. Due to the intrinsic lattice mismatch and formation of periodic Moiré patterns, the potential energy surface of the FG/MoS2 heterostructure is ultrasmooth and the interlayer shear strength is reduced by nearly two orders of magnitude, compared with both FG/FG and MoS2/MoS2 bilayers, entering the superlubricity regime. The size dependency of superlubricity is revealed as being based on the relationship between the emergence of Moiré patterns and the lattice mismatch ratio for heterostructures.

Entities: Chemical

Year: 2014 PMID： 25180979 DOI： 10.1088/0957-4484/25/38/385701

Source DB: PubMed Journal: Nanotechnology ISSN： 0957-4484 Impact factor: 3.874

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Cited

7 in total

Superlubricity of two-dimensional fluorographene/MoS2 heterostructure: a first-principles study.

Review 1. Recent Progress on Wear-Resistant Materials: Designs, Properties, and Applications.

2. Macroscale Robust Superlubricity on Metallic NbB₂.

3. Experimental study and modeling of atomic-scale friction in zigzag and armchair lattice orientations of MoS₂.

4. Ultralow Interlayer Friction of Layered Electride Ca₂N: A Potential Two-Dimensional Solid Lubricant Material.

5. Atomic-Scale Superlubricity in Ti₂CO₂@MoS₂ Layered Heterojunctions Interface: A First Principles Calculation Study.

6. Sliding friction of graphene/hexagonal -boron nitride heterojunctions: a route to robust superlubricity.

7. High-throughput screening of the static friction and ideal cleavage strength of solid interfaces.

Superlubricity of two-dimensional fluorographene/MoS2 heterostructure: a first-principles study.

Review 1. Recent Progress on Wear-Resistant Materials: Designs, Properties, and Applications.

2. Macroscale Robust Superlubricity on Metallic NbB2.

3. Experimental study and modeling of atomic-scale friction in zigzag and armchair lattice orientations of MoS2.

4. Ultralow Interlayer Friction of Layered Electride Ca₂N: A Potential Two-Dimensional Solid Lubricant Material.

5. Atomic-Scale Superlubricity in Ti2CO2@MoS2 Layered Heterojunctions Interface: A First Principles Calculation Study.

6. Sliding friction of graphene/hexagonal -boron nitride heterojunctions: a route to robust superlubricity.

7. High-throughput screening of the static friction and ideal cleavage strength of solid interfaces.

2. Macroscale Robust Superlubricity on Metallic NbB₂.

3. Experimental study and modeling of atomic-scale friction in zigzag and armchair lattice orientations of MoS₂.

5. Atomic-Scale Superlubricity in Ti₂CO₂@MoS₂ Layered Heterojunctions Interface: A First Principles Calculation Study.