Influence of MgO tunnel barrier thickness on spin-transfer ferromagnetic resonance and torque in magnetic tunnel junctions

TL;DR

This study investigates how varying MgO tunnel barrier thickness affects spin-transfer ferromagnetic resonance and torque in magnetic tunnel junctions, revealing that torque magnitude remains unaffected by barrier thickness.

Contribution

It provides experimental and theoretical analysis showing that tunnel barrier thickness does not influence the magnitude of spin-transfer torque in MTJs.

Findings

Torque values are independent of MgO barrier thickness.

Coupling effects influence ST-FMR signals and torkances.

Experimental results align with free-electron model calculations.

Abstract

Spin-transfer ferromagnetic resonance (ST-FMR) in symmetric magnetic tunnel junctions (MTJs) with a varied thickness of the MgO tunnel barrier (0.75 nm < $t_{MgO}$ < 1.05 nm) is studied using the spin-torque diode effect. The application of an RF current into nanosized MTJs generates a DC mixing voltage across the device when the frequency is in resonance with the resistance oscillations arising from the spin transfer torque. Magnetization precession in the free and reference layers of the MTJs is analyzed by comparing ST-FMR signals with macrospin and micromagnetic simulations. From ST-FMR spectra at different DC bias voltage, the in-plane and perpendicular torkances are derived. The experiments and free-electron model calculations show that the absolute torque values are independent of tunnel barrier thickness. The influence of coupling between the free and reference layer of the MTJs on the ST-FMR signals and the derived torkances are discussed.