Litcius/Paper detail

Cryogenic Memory Element Based on an Anomalous Josephson Junction

C. Guarcello, F.S. Bergeret

2020Physical Review Applied57 citationsDOIOpen Access PDF

Abstract

We propose a nonvolatile memory element based on a lateral ferromagnetic Josephson junction with spin-orbit coupling and out-of-plane magnetization. The interplay between the latter and the intrinsic exchange field of the ferromagnet leads to a magnetoelectric effect that couples the charge current through the junction and its magnetization, such that by applying a current pulse the direction of the magnetic moment in $F$ can be switched. The two memory states are encoded in the direction of the out-of-plane magnetization. With the aim to determine the optimal working temperature for the memory element, we explore the noise-induced effects on the averaged stationary magnetization by taking into account thermal fluctuations affecting both the Josephson phase and the magnetic moment dynamics. We investigate the switching process as a function of intrinsic parameters of the ferromagnet, such as the Gilbert damping and strength of the spin-orbit coupling, and propose a nondestructive readout scheme based on a dc superconducting quantum interference device. Additionally, we analyze a way to protect the memory state from external perturbations by voltage gating in systems with a both linear-in-momentum Rashba and Dresselhaus spin-orbit coupling.

Topics & Concepts

Josephson effectCondensed matter physicsPhysicsFerromagnetismPi Josephson junctionCoupling (piping)MagnetizationSuperconductivityMagnetic fieldMagnetic momentMoment (physics)VoltageThermal fluctuationsTunnel junctionNon-volatile memoryTunnel magnetoresistanceSquidQuantum fluctuationField (mathematics)Adiabatic processCoupling strengthQuantumMagnetoresistanceCommutationThermalCharge (physics)GatingTopological Materials and PhenomenaMagnetic properties of thin filmsQuantum and electron transport phenomena