Observation of intertwined charge density wave order and superconductivity in Janus monolayer

Abstract

Low-dimensional transition-metal dichalcogenides (TMDCs) provide an ideal platform for studying the emergence of charge density wave (CDW) and superconductivity. The discovery of emergent CDW order in 1T ZrTe2 monolayer raises an important question: does this instability persist when one Te chalcogen layer is substituted by Se? In the present work, we investigate the CDW (2×2×1) and superconducting instability in 1T ZrSeTe Janus monolayer using first-principles calculations. The phonon spectrum exhibits a pronounced anomaly at the M point of the irreducible Brillouin zone, arising from enhanced electron-phonon interaction together with electronic instabilities originating from both interband and intraband scattering. The resulting lattice distortion reconstructs the electronic structure, opening a small indirect band gap, driving the system from a semi-metallic to a semiconducting state. The energy gain associated with the distortion is significantly smaller than that of ZrTe2 monolayer, indicating that the replacement of one Te chalcogen layer with Se weakens the CDW instability. We have further investigated the effects of electronic correlation and biaxial strain, both acts as effective tuning parameters for the instabilities concerened. In the high temperature undistorted phase, ZrSeTe exhibits phonon mediated two-gap superconductivity. It originates primarily from the robust coupling between the soft phonon mode at M point and the electronic bands predominantly derived from Zr d and Te p orbitals crossing the Fermi level. Spin-orbit coupling (SOC) further modifies the electronic states and reduces the superconducting transition temperature.