Tunable , 0 and 0 Josephson junction

Abstract

We study a 0-π dc superconducting quantum interference device (SQUID) with asymmetric inductances and critical currents of the two Josephson junctions (JJs). By considering such a dc SQUID as a black box with two terminals, we calculate its effective current-phase relation Is() and the Josephson energy U(), where is the Josephson phase across the terminals. We show that there is a domain of parameters where the black box has the properties of a JJ with degenerate ground state phases =. The domain is rather large, so one can easily construct a JJ experimentally. We derive the current phase relation and show that it can be tuned in situ by applying an external magnetic flux resulting in a continuous transition between the systems with static solutions =, =0 (0 ≠ 0,π) and even =0. The dependence of 0 on applied magnetic flux is not 2π (one flux quantum) periodic.