Josephson effects in twisted cuprate bilayers

Abstract

Twisted bilayers of high-Tc cuprate superconductors have been argued to form topological phases with spontaneously broken time reversal symmetry T for certain twist angles. With the goal of helping to identify unambiguous signatures of these topological phases in transport experiments, we theoretically investigate a suite of Josephson phenomena between twisted layers. We find an unusual non-monotonic temperature dependence of the critical current at intermediate twist angles which we attribute to the unconventional sign structure of the d-wave order parameter. The onset of the T-broken phase near 45 twist is marked by a crossover from the conventional 2π-periodic Josephson relation J() Jc to a π-periodic function as the single-pair tunneling becomes dominated by a second order process that involves two Cooper pairs. Despite this fundamental change, the critical current remains a smooth function of the twist angle θ and temperature T implying that a measurement of Jc alone will not be a litmus test for the T-broken phase. To obtain clear signatures of the T-broken phase one must measure Jc in the presence of an applied magnetic field or radio-frequency drive, where the resulting Fraunhofer patterns and Shapiro steps are altered in a characteristic manner. We discuss these results in light of recent experiments on twisted bilayers of the high-Tc cuprate superconductor Bi2Sr2CaCu2O8+δ.