Affiliation:
1. School of Physics and Wuhan National High Magnetic Field Center Huazhong University of Science and Technology 430074 Wuhan China
2. Institute for Quantum Science and Engineering Huazhong University of Science and Technology Wuhan Hubei 430074 China
3. Hubei Key Laboratory of Optical Information and Pattern Recognition School of Optical Information and Energy Engineering Wuhan Institute of Technology 430073 Wuhan China
Abstract
AbstractWeyl phonons have long been regarded as an important kind of topological bosonic quasiparticle states. Previous investigations in this field mainly focus on Weyl phonons located at high‐symmetry points (HSPs) in Brillouin zone (BZ), while those located at high‐symmetry lines (HSLs, not including HSPs) are still rarely studied. Considering that their symmetry‐protected conditions are much different, we name them conventional and unconventional Weyl phonons, respectively. In this work, taking charge‐two Weyl phonons (CTWPs) as examples, the complete classifications of all unconventional CTWPs is summarized by performing symmetry analysis in all 230 space groups (SGs). Moreover, due to their different phononic dispersions, the unconventional CTWPs can be classified as Type‐I, Type‐II, and Type‐III ones. Particularly, thek·pmodel of unconventional CTWPs shows ak‐type feature along the invariant lines while ak2‐type feature along other directions. Additionally, we uncover that a real chiral crystal material, that is, CsBe2F5in SG 213, can exhibit well‐defined Type‐I and Type‐II unconventional CTWPs characterized by multiple double‐helicoid surface states. Our theoretical work not only puts forward an effective way for seeking for unconventional CTWPs, but also uncover the unique advantages of this kind of CTWPs toward realistic device applications.
Funder
National Natural Science Foundation of China
China Postdoctoral Science Foundation