Charge-4e superconductor with parafermionic vortices: A path to universal topological quantum computation

Abstract

Topological superconductors (TSCs) provide a promising route to fault-tolerant quantum information processing. However, the canonical Majorana platform based on 2e TSCs remains computationally constrained. In this work, we find a 4e TSC that overcomes these constraints by combining a charge-4e condensate with an Abelian chiral Z3 topological order in an intertwined fashion. Remarkably, this 4e TSC can be obtained by proliferating vortex-antivortex pairs in a stack of two 2e p+ip TSCs, or by melting a =2/3 quantum Hall state. Specific to this TSC, the hc/(4e) fluxes act as charge-conjugation defects in the topological order, whose braiding with anyons transmutes anyons into their antiparticles. This symmetry enrichment leads to Z3 parafermion zero modes trapped in the elementary vortex cores, which naturally encode qutrits. Braiding the parafermion defects alone generates the full many-qutrit Clifford group. We further show that a single-probe interferometric measurement enables topologically protected magic-state preparation, promoting Clifford operations to a universal gate set. Because the non-Abelian modes are bound to flux defects, they can, in principle, be externally controlled using superconducting circuit-based technology. More broadly, our results highlight hierarchical electron aggregation, the formation and condensation of higher-charge electron clusters, as a design principle for topological quantum matter with increased computational capability.