Theory of Topological Superconductivity and Antiferromagnetic Correlated Insulators in Twisted Bilayer WSe2

Abstract

Since the very recent discovery of unconventional superconductivity in twisted WSe2 homobilayers at filling =-1, considerable interest has arisen in revealing its mechanism. In this paper, we developed a three-band tight-binding model with non-trivial band topology by direct Wannierization of the low-energy continuum model. Incorporating both onsite Hubbard repulsion and next-nearest-neighbor attraction, we then performed a mean-field analysis of the microscopic model and obtained a phase diagram qualitatively consistent with the experiment results. For zero or weak displacement field, the ground state is a Chern number C= 2 topological superconductor in the Altland-Zirnbauer A-class (breaking time-reversal but preserving total Sz symmetry) with inter-valley pairing dominant in dxy idx2-y2-wave (mixing with a subdominant px i py-wave) component. For a relatively strong displacement field, the ground state is a correlated insulator with the 120 antiferromagnetic order. Our results provide new insights into the nature of the twisted WSe2 systems and suggest the need for further theoretical and experimental explorations.