The dc-Josephson effect with more than four superconducting leads

Abstract

By definition, the p-terminal dc-Josephson current is sensitive to the superconducting phase variables of p terminals. In the paper, we establish protocol for direct detection of the p-terminal dc-Josephson effect with p 3 in a device containing N superconducting leads S1,\,S2,\,...,\,SN having the phase variables 1,\,2,\,...,\,N. The calculated signal (N) can be probed in microwave experiments, and it corresponds to the higher-order nonlocal inverse inductance obtained from differentiating the current I1 through S1 with respect to the remaining N-2 independent phase differences 2-N,\,3-N,\, ...,N-1-N. We find that the values p N-2 do not contribute to (N), and that (N) 0 implies evidence for the p=N-1 or the p=N-terminal dc-Josephson currents. For N=4 superconducting leads, we demonstrate that (4) 0 implies evidence for the p=3 or p=4 dc-Josephson effect, irrespective of the p=2-terminal dc-Josephson current. Thus, we provide a way to demonstrate the dc-Josephson effect with more than three terminals (i.e. with p 3) in a device containing more than four superconducting leads (i.e. with N 4). The predicted (4) is "yes or no" answer to the p 3 dc-Josephson effect, i.e. for N=4, nonvanishingly small (4) 0 implies the p=3 or p=4-terminal dc-Josephson effect and vanishingly small (4)=0 implies absence of the p=3 and p=4-terminal dc-Josephson effect. The paper can be viewed as generalizing the recently considered -junctions in Andreev molecules to arbitrary number N of the superconducting leads, and it relies on basic properties of the dc-Josephson effect that are not directly related to nontrivial topology and Weyl point singularities.