Superconductivity, pair density wave, and Neel order in cuprates

Abstract

We investigate in underdoped cuprates possible coexistence of the superconducting (SC) order at zero momentum and pair density wave (PDW) at momentum Q=(π, π) in the presence of a Neel order. By symmetry, the d-wave uniform singlet pairing dS0 can coexist with the d-wave triplet PDW dT Q, and the p-wave singlet PDW pS Q can coexist with the p-wave uniform triplet pT0. At half filling, we find the novel pS Q+pT0 state is energetically more favorable than the dS0+dT Q state. At finite doping, however, the dS0+dT Q state is more favorable. In both types of states, the variational triplet parameters, dT Q and pT0, are of secondary significance. Our results point to a fully symmetric Z2 quantum spin liquid with spinon Fermi surface in proximity to the Neel order at zero doping, and to intertwined d-wave triplet PDW fluctuations and spin moment fluctuations along with the dominant d-wave singlet SC at finite doping. The results are obtained by variational quantum Monte Carlo simulations.