Pair-density-wave superconductor from doping Haldane chain and rung-singlet ladder

We report the numerical discovery of a Luther-Emery liquid with pair-density-wave (PDW) correlations from doping either (i) a spin-one Haldane chain or (ii) a two-leg ladder in the rung-singlet phase in which the doped charges occupy a single leg. We model these systems using a generalized Kondo model. The itinerant electrons are correlated and described by the t-J model, and are further coupled to a spin-1/2 Heisenberg model through the Kondo coupling JK. When the density of electrons x is one, the Mott insulator is in a Haldane phase or in a rung-singlet phase depending on whether JK is negative or positive. Upon doping, a pair-density-wave with Q = ?? can emerge for both signs of JK. In the JK ??? ?????? limit, the model reduces to the recently proposed type II t-J model. We also identify a composite order parameter for the superconductor, which can be understood as a Cooper pair formed by two nearby fermionic spin-polarons. Our model and the predicted PDW phase can be experimentally realized by doping S = 1 chains formed by Ni2+ in a solid-state system or a two-leg ladder of fermionic cold atoms with a potential bias between legs, which preferentially dopes carriers into a single leg. Long-range order of the PDW can be achieved in quasi-one-dimensional system with finite interwire coupling.

Automated summary

We report on the numerical discovery of a Luther-Emery liquid with pair-density-wave (PDW) correlations in doped spin-one Haldane chains or two-leg ladders. Our model, based on a generalized Kondo model, shows that a PDW with Q = ?? can emerge upon doping, regardless of the sign of the Kondo coupling JK. We also identify a composite order parameter for the superconductor, which can be experimentally realized in solid-state systems or fermionic cold atoms.