个人信息Personal Information
教授
博士生导师
硕士生导师
性别:男
毕业院校:天津大学
学位:博士
所在单位:机械工程学院
学科:机械制造及其自动化. 机械设计及理论
办公地点:机械工程学院知方楼5055
联系方式:zzy@dlut.edu.cn
电子邮箱:zzy@dlut.edu.cn
Macroscale Superlubricity Enabled by Graphene-Coated Surfaces
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论文类型:期刊论文
发表时间:2020-02-01
发表刊物:ADVANCED SCIENCE
收录刊物:EI、SCIE
卷号:7
期号:4
页面范围:1903239
关键字:ambient conditions; graphene; macroscale superlubricity; macroscale surfaces; molecular dynamics
摘要:Friction and wear remain the primary modes for energy dissipation in moving mechanical components. Superlubricity is highly desirable for energy saving and environmental benefits. Macroscale superlubricity was previously performed under special environments or on curved nanoscale surfaces. Nevertheless, macroscale superlubricity has not yet been demonstrated under ambient conditions on macroscale surfaces, except in humid air produced by purging water vapor into a tribometer chamber. In this study, a tribological system is fabricated using a graphene-coated plate (GCP), graphene-coated microsphere (GCS), and graphene-coated ball (GCB). The friction coefficient of 0.006 is achieved in air under 35 mN at a sliding speed of 0.2 mm s(-1) for 1200 s in the developed GCB/GCS/GCP system. To the best of the knowledge, for the first time, macroscale superlubricity on macroscale surfaces under ambient conditions is reported. The mechanism of macroscale superlubricity is due to the combination of exfoliated graphene flakes and the swinging and sliding of the GCS, which is demonstrated by the experimental measurements, ab initio, and molecular dynamics simulations. These findings help to bridge macroscale superlubricity to real world applications, potentially dramatically contributing to energy savings and reducing the emission of carbon dioxide to the environment.