2 research outputs found
Testing Electron-phonon Coupling for the Superconductivity in Kagome Metal
In crystalline materials, electron-phonon coupling (EPC) is a ubiquitous
many-body interaction that drives conventional Bardeen-Cooper-Schrieffer
superconductivity. Recently, in a new kagome metal ,
superconductivity that possibly intertwines with time-reversal and spatial
symmetry-breaking orders is observed. Density functional theory calculations
predicted weak EPC strength,, supporting an unconventional pairing
mechanism in . However, experimental determination of
is still missing, hindering a microscopic understanding of the intertwined
ground state of . Here, using 7-eV laser-based angle-resolved
photoemission spectroscopy and Eliashberg function analysis, we determine an
intermediate =0.45~0.6 at T=6 K for both Sb 5p and V 3d electronic
bands, which can support a conventional superconducting transition temperature
on the same magnitude of experimental value in . Remarkably,
the EPC on the V 3d-band enhances to ~0.75 as the superconducting
transition temperature elevated to 4.4 K in .
Our results provide an important clue to understand the pairing mechanism in
the Kagome superconductor .Comment: To appear in Nature Communication
Testing electron–phonon coupling for the superconductivity in kagome metal CsV3Sb5
Electron-phonon coupling is thought to be too weak to be responsible for the superconducting Cooper pairing of the kagome metals AV3Sb5, but an experimental measurement is lacking. Here, the authors use ARPES measurements to find that electron-phonon coupling in CsV3Sb5 is strong enough to support the experimental superconducting transition