There are currently Postdoctoral positions available in our group, with joint support from Wuhan University. Topics of interest include, but are not limited to, the following:

Project 1. High-resolution In-situ Measurement of Nanoscale Friction and Wear
Research Content
i） Develop high-resolution in-situ methods for measuring friction and wear;
ii）Conduct precise in-situ measurements and characterization of the friction and wear properties of hard alloy interfaces/coatings and vdW interfaces；
iii) Design materials/interfaces and coatings with ultra-low friction and superior wear resistance.

Project 2. Non-Equilibrium Dynamics of van der Waals Interfaces
Research Content
i）Develop efficient computational methods to accurately describe non-equilibrium dynamic processes at van der Waals interfaces, including force-electric coupling, electron-phonon coupling, and other collective phenomena;
ii）Establish theoretical models to elucidate the mechanisms underlying these dynamic processes at van der Waals interfaces;
iii）Create an open-source software package optimized for efficient parallel computation, facilitating large-scale simulations and analysis, serving the relevant scientific community, and encouraging broad collaboration.

Project 3. Multi-Scale Computational Methods for the Simulation and Design of Structural Superlubricity Systems
Research Content
i）Develop advanced cross-scale computational methods to accurately model and simulate friction and wear processes in structural superlubric systems, bridging atomic-level interactions with macroscopic behavior;
ii）Design and implement a high-performance, open-source software package optimized for efficient parallel computation, enabling large-scale simulations of superlubric systems;
iii) Utilize the developed algorithms and software package to conduct comprehensive studies on the friction and wear performance of superlubricity systems. Investigate key influencing factors and provide reliable theoretical frameworks for designing and achieving stable structural superlubric systems, with direct implications for next-generation MEMS devices.