Magnon-Mediated Superconductivity in the Infinite-U Triangular Lattice

Abstract

We demonstrate that the infinite-U triangular-lattice Hubbard model supports a superconducting state built from tightly bound Cooper pairs composed of two holes and one magnon (2h1m). Building on the seminal prediction of repulsively bound 2h1m states, we show that next-nearest-neighbor hopping t2 coherently mixes symmetry-related configurations, stabilizing an s-wave bound state with substantial binding energy and a light effective mass. Large-scale DMRG calculations at finite doping identify a magnetization plateau corresponding to a gas of such bound states and quasi--long--range superconducting order with power-law 2h1m pair correlations. Our results establish a magnon-mediated superconducting mechanism driven by kinetic frustration, with immediate detectable signatures for moir\'e Hubbard materials and ultracold-atom simulators.