Phase jumps in Josephson junctions with time-dependent spin-orbit coupling
Abstract
Planar Josephson junctions (JJs), based on common superconductors and III-V semiconductors, are sought for Majorana states and fault-tolerant quantum computing. However, with gate-tunable spin-orbit coupling (SOC), we show that the range of potential applications of such JJs becomes much broader. The time-dependent SOC offers unexplored mechanisms for switching JJs, accompanied by the -phase jumps and the voltage pulses corresponding to the single-flux-quantum transitions, key to high-speed and low-power superconducting electronics. In a constant applied magnetic field, with Rashba and Dresselhaus SOC, anharmonic current-phase relations, calculated microscopically in these JJs, yield a nonreciprocal transport and superconducting diode effect. Together with the time-dependent SOC, this allows us to identify a switching mechanism at no applied current bias which supports fractional-flux-quantum superconducting circuits and neuromorphic computing.
Cite
@article{arxiv.2407.01847,
title = {Phase jumps in Josephson junctions with time-dependent spin-orbit coupling},
author = {David Monroe and Chenghao Shen and Dario Tringali and Mohammad Alidoust and Tong Zhou and Igor Žutić},
journal= {arXiv preprint arXiv:2407.01847},
year = {2024}
}
Comments
7 pages, 4 figures, Invited to APL Special Topic Issue: "Josephson Junctions and Related Proximity Effects: From Basic Science to Emerging Applications in Advanced Technologies", accepted version