Litcius/Paper detail

Phonon-Limited Valley Polarization in Transition-Metal Dichalcogenides

Zuzhang Lin, Yizhou Liu, Zun Wang, Shengnan Xu, Siyu Chen, Wenhui Duan, Bartomeu Monserrat

2022Physical Review Letters46 citationsDOI

Abstract

The ability to selectively photoexcite at different Brillouin zone valleys forms the basis of valleytronics and other valley-related physics. Symmetry arguments combined with static lattice first-principles calculations suggest an ideal 100% valley polarization in transition-metal dichalcogenides under circularly polarized light. However, experimental reports of the valley polarization range from 32% to almost 100%. Possible explanations for this discrepancy include phonon-mediated transitions, which would place a fundamental limit to valley polarization, and defect-mediated transitions, which could, in principle, be reduced with cleaner samples. We explore the phonon-mediated fundamental limit by performing calculations of phonon-mediated optical absorption for circularly polarized light entirely from the first principles. We also use group theory to reveal the microscopic mechanisms behind the phonon-mediated excitations, discovering contributions from several individual phonon modes and from multiphonon processes. Overall, our calculations show that the phonon-limited valley polarization is around 70% at room temperature for state-of-the-art valleytronic materials including MoSe_{2}, MoS_{2}, WS_{2}, WSe_{2}, and MoTe_{2}. This fundamental limit implies that sufficiently pure transition-metal dichalcogenides are ideal candidates for valleytronics applications.

Topics & Concepts

Transition metalCondensed matter physicsMaterials sciencePhononPolarization (electrochemistry)PhysicsChemistryPhysical chemistryCatalysisBiochemistry2D Materials and ApplicationsHeusler alloys: electronic and magnetic propertiesOrganic and Molecular Conductors Research