Meissner-Like Currents of Photons in Anomalous Superradiant Phases (2503.01477v1)

Abstract: The Meissner effect, a signature feature of superconductors, involves circular surface currents that cancel an external field. In this study, we present our findings on Meissner-like currents of photons in highly tunable light-matter interaction systems. In a quantum Rabi zigzag chain exposed to a staggered magnetic field, we identify a Meissner superradiant phase, manifesting persistent chiral edge currents in the ground state. Counter-flowing edge currents arise in each species of cavities,leading to complete cancellation of net currents throughout the entire chain. This phenomenon is analogous to surface currents in the Meissner effect. The Meissner phase is signaled by the unusual scaling exponents of the lowest excitation energy, which exhibit anomalous criticality with and without geometric frustration in each species. Intriguingly, adjusting the staggered flux induces transitions from the Meissner phase to either the even-chiral or odd-chiral superradiant phases, where the chiral edge currents flow exclusively in even or odd cavities, respectively. Additionally, by enhancing interspecies interactions, chiral currents vanish in a ferromagnetic superradiant phase. Our realization of Meissner-like currents of photons opens avenues for exploring edge state interferometry and quantum Hall effects within light-matter coupling platforms.