Topological Charge-2ne Superconductors

Abstract

Charge-4e superconductors are phases where quartets of electrons condense in the absence of Cooper pairing condensation. They exhibit distinctive signatures including fractional flux quantization and anomalous Josephson effects, and are actively being explored in strongly correlated systems, such as moiré materials. In this work we develop a general framework for topological charge-2ne superconductors based on both wavefunction and field theory approaches. In particular, we generate topological charge-2ne superconductors from charge-2e ingredients, and by breaking the charge U(1) symmetry in certain classes of quantum Hall states, in both spinless and spinful systems. Via bulk-edge correspondence, we further construct the corresponding edge conformal field theory and bulk topological quantum field theory for topological charge-2ne superconductors that suggests fermionic nonabelian topological orders. Our results provide a unified low-energy description of the topological charge-2ne superconductivity, offer a concrete platform for studying symmetry breaking and enrichment in interacting topological phases of matter, and have direct implications for experimental probes such as quasiparticle interferometry.