Josephson diode effect from Cooper pair momentum in a topological semimetal

In the presence of an external magnetic field Cooper pairs in noncentrosymmetric superconductors can acquire finite momentum. Recent theory predicts that such finite-momentum pairing can lead to an asymmetric critical current, where a dissipationless supercurrent can flow along one direction but not the opposite. However, to date this has not been observed. Here we report the discovery of a giant Josephson diode effect (JDE) in Josephson junctions formed from a type II Dirac semimetal, NiTe2. A distinguishing feature is that the asymmetry in the critical current depends sensitively on the magnitude and direction of an applied magnetic field and achieves its maximum value of ~60% when the magnetic field is perpendicular to the current and is of the order of just 10 mT. Moreover the asymmetry changes sign several times with increasing field. These characteristic features are accounted for in a theoretical model based on finite-momentum Cooper pairing derived from spin-helical topological surface states, in an otherwise centrosymmetric system. The finite pairing momentum is further established, and its value determined, from the evolution of the interference pattern under an in-plane magnetic field. The observed giant magnitude of the asymmetry in critical current and the clear exposition of its underlying mechanism paves the way to building novel superconducting computing devices using the Josephson diode effect.
Comment: 14 pages, 4 figures