Theoretical spin transport analysis for a spin pseudovalve-type Lj/semiconductor/Lj trilayer (with Lj = ferromagnetic)

Abstract

In this work, a theoretical study of spin transport in a pseudovalve spin (PSV) heterostructure is conducted. For the semiconductor (SC), the conduction band at the point of reciprocal space and spin-orbit coupling (SOC) are considered. For the ferromagnetic (FM) electrodes on the left (l) and right (r), the internal exchange energy (j, where j = (l,r)) and the magnetization normal vector (nj) on the barrier plane are taken into account. An analytical expression for the transmission probability as a function of nj direction was obtained from the Schr\"odinger-Pauli equations with the boundary conditions. Furthermore, the tunnel magnetoresistance (TMR) at T ≈ 0 K was calculated, depending on the direction of the crystallographic axis favoring the magnetization (θm) of the FM and the thickness of the SC, using the Landauer-B\"uttiker formula for a single channel. It is observed that the TMR reaches its maximum value when the nl direction is parallel to θm. Applying this physico-mathematical model to the Fe/SC/Fe PSV, with SC as GaAs, GaSb, and InAs, it was found that the Dresselhaus SOC does not significantly contribute to the TMR.