Underlying topological Dirac nodal line mechanism of anomalously large electron-phonon coupling strength on Be (0001) surface

Abstract

Beryllium was recently discovered to harbor a Dirac nodal line (DNL) in its bulk phase and the DNL-induced non-trivial drumhead-like surface states (DNSSs) on its (0001) surface, rationalizing several already-existing historic puzzles [Phys. Rev. Lett., 117, 096401 (2016)]. However, to date the underlying mechanism, as to why its (0001) surface exhibits an anomalously large electron-phonon coupling effect (λe-phs ≈ 1.0), remains unresolved. Here, by means of first-principles calculations we have evidenced that the coupling of the DNSSs with the phononic states mainly contributes to its novel surface e-ph enhancement. Besides that the experimentally observed λe-phs and the main Eliashberg coupling function (ECF) peaks have been reproduced well, we have decomposed the ECF, α2F(k,q;v), and the e-ph coupling strength λ(k,q;v) as a function of each electron momentum (k), each phonon momentum (q) and each phonon mode (v), evidencing the robust connection between the DNSSs and both α2F(k,q;v) and λ(k,q;v). The results reveal the strong e-ph coupling between the DNSSs and the phonon modes, which contributes over 80\% of the λe-phs coefficient on the Be (0001) surface. It highlights that the anomalously large e-ph coefficient on the Be (0001) surface can be attributed to the presence of its DNL-induced DNSSs, clarifying the long-term debated mechanism.