Microscopic mechanism of room-temperature superconductivity in compressed LaH10
- Authors
- Liu, Liangliang; Wang, Chongze; Yi, Seho; Kim, Kun Woo; Kim, Jaeyong; Cho, Jun-Hyung
- Issue Date
- Apr-2019
- Publisher
- AMER PHYSICAL SOC
- Citation
- PHYSICAL REVIEW B, v.99, no.14, pp.1 - 5
- Indexed
- SCIE
SCOPUS
- Journal Title
- PHYSICAL REVIEW B
- Volume
- 99
- Number
- 14
- Start Page
- 1
- End Page
- 5
- URI
- https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/148058
- DOI
- 10.1103/PhysRevB.99.140501
- ISSN
- 2469-9950
- Abstract
- Room-temperature superconductivity has been one of the most challenging subjects in modern physics. Recent experiments reported that lanthanum hydride LaH10 +/- x (x < 1) raises a superconducting transition temperature T-c up to similar to 260 (or 250) K at high pressures around 190 (170) GPa. Here, based on first-principles calculations, we reveal that compressed LaH10 has symmetry-protected Dirac-nodal-line states, which split into holelike and electronlike bands at the high-symmetry points near the Fermi energy (E-F), thereby producing a van Hove singularity (vHs). The crystalline symmetry and the band topology around the high-symmetry points near E-F are thus demonstrated to be important for room-temperature superconductivity. Further, we identify that the electronic states at the vHs are composed of strongly hybridized La f and H s orbitals, giving rise to a peculiar characteristic of electrical charges with anionic La and both anionic and cationic H species. Consequently, a large number of electronic states at the vHs are strongly coupled to the H-derived high-frequency phonon modes that are induced via the unusual, intricate bonding network of LaH10, therefore yielding a high T-c. Our findings elucidate the microscopic mechanism of the observed high-T-c BCS-type superconductivity in LaH10, which can be generic to another recently observed high-T-c hydride H3S.
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