Toward error-free scaled spin torque majority gates | Zendy

Adrien Vaysset | Zendy; Mauricio Manfrini | Zendy; Dmitri E. Nikonov | Zendy; Sasikanth Manipatruni | Zendy; Ian A. Young | Zendy; Geoffrey Pourtois | Zendy; Iuliana Radu | Zendy; Aaron Thean | Zendy

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Toward error-free scaled spin torque majority gates

Author(s) -

Adrien Vaysset,

Mauricio Manfrini,

Dmitri E. Nikonov,

Sasikanth Manipatruni,

Ian A. Young,

Geoffrey Pourtois,

Iuliana Radu,

Aaron Thean

Publication year - 2016

Publication title -

aip advances

Language(s) - English

Resource type - Journals

SCImago Journal Rank - 0.421

H-Index - 58

ISSN - 2158-3226

DOI - 10.1063/1.4953672

Subject(s) - torque , domain wall (magnetism) , spin (aerodynamics) , micromagnetics , condensed matter physics , mode (computer interface) , range (aeronautics) , physics , phase (matter) , mechanics , materials science , computer science , magnetization , magnetic field , quantum mechanics , composite material , thermodynamics , operating system

The functionality of a cross-shaped Spin Torque Majority Gate is explored by means of micromagnetic simulations. The different input combinations are simulated varying material parameters, current density and size. The main failure mode is identified: above a critical size, a domain wall can be pinned at the center of the cross, preventing further propagation of the information. By simulating several phase diagrams, the key parameters are obtained and the operating condition is deduced. A simple relation between the domain wall width and the size of the Spin Torque Majority Gate determines the working range. Finally, a correlation is found between the energy landscape and the main failure mode. We demonstrate that a macrospin behavior ensures a reliable majority gate operation

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