Prediction of phonon-mediated high-T_C superconductivity in monolayer Mg₂B₄C₂

We theoretically design a novel two-dimensional material - Mg₂B₄C₂, which is predicted to exhibit superconductivity with critical temperature T_C estimated in the 67-84 K range (predicted using the isotropic Migdal-Eliashberg theory) without any tuning of external parameters such as doping, strain, or substrate-induced effects. This 2D material is stable and it belongs to the family of the conventional high-T_C bulk superconductor MgB₂. It is obtained after replacing the chemically active boron layers in MgB₂ with chemically inactive boron-carbon layers. The key feature in 2D Mg₂B₄C₂ is the fact that, unlike in bulk MgB₂, more than just two E_2g phonon modes strongly couple to the electronic states near the Fermi level, thus resulting in a substantially large electron-phonon coupling (λ = 1.75), as compared to the bulk MgB₂ (λ_bulk = 0.6-0.7). This material also features a topologically nontrivial electronic bandstructure (Dirac metal). Interestingly, we find that the key features of this material remain essentially unchanged when its thickness is increased by modestly increasing the number of inner MgB₂ layers.