Topological & Weyl Quantum Materials: Chiral Transport and CPGE
Topological & Weyl Quantum Materials: Chiral Transport and CPGE
Symmetry-breaking light–matter interactions in low-dimensional quantum materials
Overview
We investigate topology-driven chiral charge transport in topological and Weyl quantum materials under circularly polarized optical excitation. Broken inversion and time-reversal symmetries give rise to Berry curvature–induced photocurrents, including the circular photogalvanic effect (CPGE). By combining polarization-resolved optical spectroscopy with electrical transport measurements, we directly probe helicity-dependent carrier dynamics and symmetry-protected transport phenomena. Our studies clarify how topological band structures govern optoelectronic responses without external bias. This research bridges fundamental topological physics with functional chiral optoelectronic devices.
Scientific Motivation
Topological quantum materials host robust electronic states protected by band topology rather than conventional symmetries. When coupled to circularly polarized light, these materials exhibit unique chiral transport phenomena that cannot arise in trivial systems. Understanding how topology and optical helicity interact is essential for exploiting topological materials in next-generation optoelectronic and quantum devices.
Key Research Topics
Circular photogalvanic effect (CPGE) in Weyl materials
Helicity-dependent photocurrent generation
Topological band structure and optical responses
Chiral optoelectronic device concepts
Methods & Experimental Platforms
Polarization- and helicity-resolved photocurrent measurements
Optical spectroscopy under controlled polarization states
Electrical transport measurements in topological devices
Confocal microscopy and Raman spectroscopy
Temperature- and thickness-dependent studies
Device fabrication based on topological and Weyl materials
Representative Results
Observation of helicity-dependent photocurrents
Identification of topology-driven chiral transport mechanisms
Correlation between band topology and optoelectronic response
Demonstration of CPGE-based device functionalities
