Abstract
Electron–phonon mediated superconductivity is deeply investigated in two boron based monolayer materials, namely, B3S$B_{3}S$, a metal exhibiting the ability to superconduct, and a new metal, B3Se$B_{3}Se$, presenting perfect kinetic stability. Calculations based on density functional perturbation theory combined with the maximally localized Wannier function also reveal that both materials exhibit anisotropic planar hexagonal structure like graphene. The key parameters involved in the superconductor behavior are all calculated. The electronic density in the Fermi surface is given to provide the environment for enhanced electron–phonon coupling. The longitudinal and transverse vibration modes of optical phonons mainly contribute to the electron–phonon coupling strength. Furthermore, the binding energy between the bosonic Cooper pair superfluid is quantified and determined. The critical temperature for the two materials is 20 and 10.5 K, respectively. The results obtained show the potential use of such materials for superconducting applications.
Two kinds of boron monolayer materials, B3S$B_{3}S$ and B3Se$B_{3}Se$, having an anisotropic planar hexagon stable structure, are proposed as single gap superconductors. The electron–phonon mediated superconductivity study determines their key parameters, including critical temperature and decay process, which promote the integration of these new 2D nanomaterials in potential superconducting applications.