Reciprocal Phase Transition Electro-Optic Modulation
Spin-orbit torque efficiency improved by BiSePt alloy
Ge0.92Sn0.08/Ge multi-quantum-well LEDs operated at...
The Editorial
MSM UV photodetector with low dark current based on GaInO/ SrTiO3 heteroj...
Single-mode InGaAsP/InP BH lasers based on high-order slotted surface gra...
Phosphor-free micro-pyramid InGaN-based white light-emitting diode with a...
A Low Power BJT-Based CMOS Temperature Sensor Using Dynamic-Distributing-...
Migration-Enhanced Epitaxial Growth of InAs/GaAs Short-Period Superlattic...
Doping a metal-organic framework material (ZIF-8) on a perovskite photoco...
官方微信
友情链接

Microwave-assisted unidirectional superconductivity in Al-InAs nanowire-Al junctions under magnetic fields

2024-03-12


Su, Haitian; Wang, Ji-Yin; Gao, Han; Luo, Yi; Yan, Shili; Wu, Xingjun; Li, Guoan; Shen, Jie; Lu, Li; Pan, Dong; Zhao, Jianhua; Zhang, Po; Xu, H.Q. Source: arXiv, February 3, 2024;

Abstract:

Under certain symmetry-breaking conditions, a superconducting system exhibits asymmetric critical currents, dubbed the "superconducting diode effect" (SDE). Recently, systems with the ideal superconducting diode efficiency or unidirectional superconductivity (USC) have received considerable interest. In this work, we report the study of Al-InAs nanowire-Al Josephson junctions under microwave irradiation and magnetic fields. We observe an enhancement of SDE under microwave driving, featured by a horizontal offset of the zero-voltage step in the voltage-current characteristic that increases with microwave power. Devices reach the USC regime at sufficiently high driving amplitudes. The offset changes sign with the reversal of the magnetic field direction. Meanwhile, the offset magnitude exhibits a roughly linear response to the microwave power in dBm when both the power and the magnetic field are large. The signatures observed are reminiscent of a recent theoretical proposal using the resistively shunted junction (RSJ) model. However, the experimental results are not fully explained by the RSJ model, indicating a new mechanism for USC that is possibly related to non-equilibrium dynamics in periodically driven superconducting systems.

© 2024, CC BY. (54 refs.)




关于我们
下载视频观看
联系方式
通信地址

北京市海淀区清华东路甲35号(林大北路中段) 北京912信箱 (100083)

电话

010-82304210/010-82305052(传真)

E-mail

semi@semi.ac.cn

交通地图
版权所有 中国科学院半导体研究所

备案号:京ICP备05085259-1号 京公网安备110402500052 中国科学院半导体所声明