Chiral cavity control of superconducting diode-like nonlinearities

Abstract

Time reversal symmetry breaking is an important piece in controlling nonreciprocal responses which are crucial in advancing the utility of quantum materials in device operations. Here, we propose cavity control of superconducting diode-like nonreciprocities where time reversal breaking is achieved via chirality of the cavity modes. With twisted bilayer graphene (TBG) as an example, we demonstrate the general principles of cavity control of band dispersion and geometry using chiral microwave photons which are valid for modes in a split-ring resonator or for modes emulated on a qubit lattice. In particular, we show that time reversal breaking by chiral modes enables superconducting diode-like nonlinearities in TBG by valley polarized states and their skewed quantum geometry. Strikingly, we find sizeable nonreciprocities at par with those obtained in magnetic field trained TBG Jospephson junction devices. The cavity control of superconducting nonreciprocities offers non-invasive means of exploring new functionalities in quantum circuits with in-situ implementation. This can serve as an important contribution to the toolbox for nonreciprocal models in circuit quantum electrodynamics to be harnessed for quantum computing and sensing.