Evolution from intralayer to interlayer superconductivity in a bilayer $t$-$J$ model
Abstract
Motivated by the bilayer cuprate superconductors and nickelate superconductor LaNiO, we investigate the evolution from intralayer to interlayer superconductivity based on a bilayer two-leg -- model, where is the in-plane electron hopping, is the in-plane spin interaction, and is the inter-plane spin interaction. By means of the density matrix renormalization group calculations, we obtain the quantum phase diagram of the system by tuning in a large doping range . We find that a large can always drive an interlayer superconductivity by coupling the two layers in both the Luther-Emery liquid and Luttinger liquid states. By coupling two Luther-Emery liquid states, the in-plane superconductivity evolves to inter-plane superconductivity either through an intermediate charge density wave (CDW) phase or directly, depending on doping ratio. This emergent CDW phase, which exists over a finite doping range, appears to develop from the CDW state of the two-leg ladder at . By coupling two Luttinger liquids, the in-plane Luttinger liquids show a transition to the inter-plane superconducting phase at large , as reported in previous literature. Interestingly, in the intermediate regime we find that while the in-plane Luttinger-liquid features remain stable, the inter-plane superconductivity can develop an enhanced quasi-long-range order with the power exponent . At last, we show that the interlayer superconductivity is also stable by coupling the bilayer three-leg - ladders by a strong interaction, from both the Luther-Emery liquid and Luttinger-liquid states.
Cite
@article{arxiv.2507.07545,
title = {Evolution from intralayer to interlayer superconductivity in a bilayer $t$-$J$ model},
author = {Yuan Yang and Xin Lu and Yuan Wan and Wei-Qiang Chen and Shou-Shu Gong},
journal= {arXiv preprint arXiv:2507.07545},
year = {2025}
}