Observation of a Zero-Field Josephson Diode Effect in a Helimagnet Josephson Junction

Abstract

Cr1/3NbS2 is a transition metal dichalcogenide that is also a chiral helimagnet, and so lacks inversion symmetry and has non-zero Berry curvature in position and momentum space. It is well known that the combination of broken time-reversal symmetry and broken inversion symmetry can generate non-reciprocal phenomena, but the interplay between these kinds of systems and superconductivity is not well known. We present Josephson junctions fabricated from Cr1/3NbS2 that give magnetic diffraction patterns with asymmetry in both the magnetic field and the critical current. The non-reciprocity in positive critical current and negative critical current, generally called the Josephson diode effect, has an efficiency of up to η=20\% in some parts of the magnetic diffraction pattern and persists even at zero applied field. We propose that pinned Abrikosov vortices are a main mechanism for the asymmetric magnetic field response in this system, and that the non-zero spin chirality of the Cr1/3NbS2 causes the diode effect. Simulations of magnetic diffraction patterns from Josephson junctions with vortices present show offsets from zero-field consistent with observations, while simulations of chiral spin structures with an out-of-plane canting show a diode effect.

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