Proximity engineering and interferometric quantification of a non-volatile anomalous phase-shift in zero-field polarity-reversible Josephson diodes

Abstract: The recent realization of zero-field polarity-reversible supercurrent rectification in proximity-magnetized Rashba(-type) Pt Josephson junctions (JJs)5 promises its practical applications for superconducting logic circuits and cryogenic memories. Here, by substituting the Pt Josephson barrier for either 5d or 4d element proximity layer with different (para-)magnetic susceptibility, spin-orbit coupling and electronic band structure, we identify the proximity role of the Josephson barrier in determining the zero-field diode properties. Ta (W) JJs reveal the zero-field diode efficiency of ~17 (~5)% at 2 K, slightly (much) smaller than that of the Pt JJs. Notably, the zero-field diode polarity of Ta and W JJs turns out to be opposite to the Pt JJs. Our results, along with a large zero-field diode efficiency found in highly magnetic-susceptible Pd JJs and a non-volatile anomalous phase-shift {\phi}_0 probed by superconducting quantum interferometry, demonstrate the {\phi}_0-tuning of zero-field diode performance via proximity engineering of interface magnetic ordering and Rashba effect.