拓扑材料体系拥有奇特的电子特性，因而近年来吸引了研究者广泛的兴趣。基于我们过于的研究经历和近期实验的相关进展，我们计划系统研究拓扑半金属和二维拓扑材料体系中的量子输运特性，具体包括以下三个方面：（1）试图解释实验上发现的拓扑半金属的诸多奇特的输运特性，例如高迁移率、量子极限下的磁阻、电子-空穴共存的拓扑半金属的输运特性等；（2）试图给出量子自旋霍尔效应体系中自旋退相干的微观机制，并进一步研究量子反常霍尔效应体系中电子-电子相互作用引起的退相干效应；（3）针对“为何量子反常霍尔效应仅能在极低温下被观测到？”这个问题，给出合理的物理解释。我们希望通过该项目的研究，不仅可以对拓扑材料体系的多项奇特的输运性质给出合理的物理解释，同时也希望可以为将来的实验提供参考建议。

Topological systems have generated great research interest due to the exotic electronic properties. Based on our previous research experience and current experimental findings, we propose to systematically study the quantum transport properties of topological semimetals and two dimensional topological systems. The whole project consists of three parts: (i) explaining the anomalous transport behaviors of topological semimetals, which includes the high mobility property, the quantum magneto-resistance under quantum limit and the exotic role of electron-hole interaction in topological semimetals; (ii) figuring out the microscopic origin of spin dephasing mechanism in quantum spin Hall systems and studying electron-electron interaction induced normal dephasing in quantum anomalous Hall systems; (iii) providing a complete interpretation for why quantum anomalous phase only exists under ultra-low temperature. We hope our studies can not only provide physical explanations for the exotic transport properties of these topological systems, but can also shed light on further experimental studies.