Zero-field dynamics stabilized by in-plane shape anisotropy in MgO-based spin-torque oscillators

2); (2) Institute of Solid State Physics; Alina M. Deac (1) ((1) Helmholtz-Zentrum Dresden - Rossendorf; Attila K\'akay (1); Ciar\'an Fowley (1); Dresden; Ewa Kowalska (1; Germany; Germany); Institute of Ion Beam Physics

arxiv: 1811.00106 · v1 · pith:O67QRHI2new · submitted 2018-10-05 · ❄️ cond-mat.mtrl-sci · cond-mat.mes-hall

Zero-field dynamics stabilized by in-plane shape anisotropy in MgO-based spin-torque oscillators

Ewa Kowalska (1 , 2) , Attila K\'akay (1) , Ciar\'an Fowley (1) , Volker Sluka (1) , J\"urgen Lindner (1) , J\"urgen Fassbender (1 , Alina M. Deac (1) ((1) Helmholtz-Zentrum Dresden - Rossendorf

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Institute of Ion Beam Physics Materials Research Dresden Germany (2) Institute of Solid State Physics TU Dresden Germany)

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classification ❄️ cond-mat.mtrl-sci cond-mat.mes-hall

keywords in-planeanisotropydynamicsout-of-planezero-fieldshapemagnetizationmgo-based

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Here we demonstrate numerically that shape anisotropy in MgO-based spin-torque nano-oscillators consisting of an out-of-plane magnetized free layer and an in-plane polarizer is necessary to stabilize out-of-plane magnetization precession without the need of external magnetic fields. As the in-plane anisotropy is increased, a gradual tilting of the magnetization towards the in-plane easy direction is introduced, favouring zero-field dynamics over static in-plane states. Above a critical value, zero-field dynamics are no longer observed. The optimum ratio of in-plane shape to out-of-plane uniaxial anisotropy, for which large angle out-of-plane zero-field dynamics occur within the widest current range, is reported.

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Zero-field dynamics stabilized by in-plane shape anisotropy in MgO-based spin-torque oscillators

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