Josephson Currents and Spin Transfer Torques in Ballistic SFSFS Nanojunctions

TL;DR

This paper investigates how charge and spin supercurrents, as well as spin transfer torques, can be controlled in a ballistic SFSFS Josephson junction using a microscopic BdG approach, revealing potential for superconducting magnetic devices.

Contribution

It provides a detailed microscopic analysis of charge and spin currents in SFSFS junctions, demonstrating their tunability via phase differences and magnetization orientations, and explores their application in superconducting magnetic torque transistors.

Findings

Spin and charge supercurrents are tunable by phase differences.

Spin transfer torques reveal proximity effect details.

The SFSFS structure can function as a superconducting magnetic torque transistor.

Abstract

Utilizing a full microscopic Bogoliubov-de Gennes (BdG) approach, we study the equilibrium charge and spin currents in ballistic $SFSFS$ Josephson systems, where $F$ is a uniformly magnetized ferromagnet and $S$ is a conventional $s$-wave superconductor. From the spatially varying spin currents, we also calculate the associated equilibrium spin transfer torques. Through variations in the relative phase differences between the three $S$ regions, and magnetization orientations of the ferromagnets, our study demonstrates tunability and controllability of the spin and charge supercurrents. The spin transfer torques are shown to reveal details of the proximity effects that play a crucial role in these types of hybrid systems. The proposed $SFSFS$ nanostructure is discussed within the context of a superconducting magnetic torque transistor.