Josephson effects in twisted cuprate bilayers
Abstract
Twisted bilayers of high- cuprate superconductors have been argued to form topological phases with spontaneously broken time reversal symmetry 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 -wave order parameter. The onset of the -broken phase near twist is marked by a crossover from the conventional -periodic Josephson relation to a -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 and temperature implying that a measurement of alone will not be a litmus test for the -broken phase. To obtain clear signatures of the -broken phase one must measure 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- cuprate superconductor BiSrCaCuO.
Keywords
Cite
@article{arxiv.2108.13457,
title = {Josephson effects in twisted cuprate bilayers},
author = {Tarun Tummuru and Stephan Plugge and Marcel Franz},
journal= {arXiv preprint arXiv:2108.13457},
year = {2022}
}
Comments
14 pages, 9 figures (including appendices)