Josephson diode effect: a phenomenological perspective

Abstract

As a novel quantum phenomenon with nonreciprocal supercurrent, the Josephson diode effect was intensively studied in recent years. Here, we construct a generalized resistively capacitance shunted junction (RCSJ) model as a low-energy effective/phenomenological theory for a general Josephson junction. For the ideal diode effect defined by unequal critical currents |Ic+||Ic-|, both inversion I and time-reversal T symmetries are required to be broken. It can be further divided into two classes: intrinsic (T-breaking for the junction itself) and extrinsic (T-breaking under external current reversion). In addition, a pseudo diode effect (T-breaking not necessary) can be defined by |Ic+|=|Ic-| but unequal retrapping currents |Ir+||Ir-|, for which noise current is further shown to produce the diode feature effectively. Finally, when radio-frequency AC external current exists, the Shapiro steps appear and can be used to distinguish the above three types of the diode effect. Our work provides a unified framework for studying the Josephson diode effect and can be applied to design workable superconducting circuits incorporating the Josephson diode as a fundamental circuit element.