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Electric-Field Control of the Interlayer Exchange Coupling for Magnetization Switching

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arxiv 1911.00183 v1 pith:TRTR5NJI submitted 2019-11-01 cond-mat.mes-hall

Electric-Field Control of the Interlayer Exchange Coupling for Magnetization Switching

classification cond-mat.mes-hall
keywords switchingmaterialspacerstructurecouplingelectric-fieldexertedexhibit
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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We propose an electric-field-controlled mechanism for magnetization switching assisted solely by the interlayer-exchange coupling (IEC) between the fixed and the free magnets, which are separated by two oxide barriers sandwiching a spacer material known for exhibiting large IEC. The basic idea relies on the formation of a quantum-well (QW) within the spacer material and controlling the transmission coefficient across the structure with an electric-field via the resonant tunneling phenomena. Using non-equilibrium Green's function (NEGF) method, we show that the structure can exhibit a bias-dependent oscillatory IEC that can switch the free magnet to have either a parallel or an antiparallel configuration with respect to the fixed magnet, depending on the sign of the IEC. Such bi-directional switching can be achieved with the same voltage polarity but different magnitudes. With proper choice of the spacer material, the current in the structure can be significantly reduced. Due to the conservative nature of the exerted torque by the IEC, the switching threshold of the proposed mechanism is decoupled from the switching speed, while the conventional spin-torque devices exhibit a trade-off due to the non-conservative nature of the exerted torque.

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