Synthesizing Strong-Coupling Kohn-Luttinger Superconductivity in 2D Van der Waals materials

Abstract

The Kohn-Luttinger (KL) mechanism of pairing, which describes superconductivity emergent from repulsive interactions, typically yields Cooper pairs at high angular-momentum ( > 0) and extremely low transition temperatures (Tc). Here, we reveal an inter-layer s-wave (=0) KL superconductivity with greatly elevated Tc in a multi-layer Hubbard model, which prototypes stacked two-dimensional (2D) electrons in layered van der Waals materials. By employing determinant quantum Monte Carlo and dynamical mean-field theory simulations, we show that a strong pairing attraction V*, without the mediation of collective modes, can emerge between inter-layer electrons in the system. As inter-layer repulsion U increases, V* evolves from a conventional KL relation of V* -U2, to a linear strong-coupling scaling of V* -U, resulting in enhanced superconductivity at large U. This strong-coupling KL pairing is robust against changes in lattice geometries and dimensionalities, and it can persist, in the presence of a large remnant Coulomb repulsion U* between pairing electrons. Using ab initio calculations, we propose a few 2D layered van der Waals materials that can potentially realize and control this unconventional superconductivity.