d-Wave pair density wave superconductivity in a two-orbital model

Abstract

Motivated by exploring superconductivity in multi-orbital systems, we study two orbital models of spinful fermions representing (px,py) or (dxz, dyz) orbitals on the square lattice. For minimal interorbital t-J or t-V on-site interactions, a random phase approximation uncovers regimes of instability towards incommensurate dxy pair density wave (d-PDW) superconductivity with driven by interband pairing. We study the competition of PDW order with uniform nodal dxy pairing states and magnetic and charge density wave (CDW) instabilities. At strong coupling, we derive an effective hard-core Cooper pair Hamiltonian which we study using a bosonic Gutzwiller ansatz to reveal a period-2 PDW over a wide range of fillings as well as a checkerboard CDW at quarter-filling. Our results apply to correlated multi-orbital materials with quasi-1D bands, Hubbard models on the square-octagon lattice, and atomic fermions in p-orbitals. Our work highlights the role of the orbital content and multiband Fermi surfaces in stabilizing interband PDW states.