Granular Vortex Spin-Torque Nano Oscillator for Reservoir Computing

Author:

Shreya Sonal1,Jenkins Alex2,Rezaeiyan Yasser1,Li Ren1,Bohnert Tim2,Ferreira Ricardo2,Moradi Farshad1,Farkhani Hooman1

Affiliation:

1. Aarhus University

2. International Iberian Nanotechnology Laboratory (INL), 4715-31 Braga, Portugal

Abstract

Abstract In this paper, we investigate the granularity in the free layer of the magnetic tunnel junctions (MTJ) and its potential to function as a reservoir for reservoir computing where grains act as oscillatory neurons while the device is in the vortex state. The input of the reservoir is applied in the form of a magnetic field which can pin the vortex core into different grains of the device in the magnetic vortex state. The oscillation frequency and MTJ resistance vary across different grains in a non-linear fashion making them great candidates to be served as the reservoir's outputs for classification objectives. Hence, we propose an experimentally validated area-efficient single granular vortex spin-torque nano oscillator (GV-STNO) device in which pinning sites work as random reservoirs that can emulate neuronal functions. We harness the nonlinear oscillation frequency and resistance exhibited by the vortex core granular pinning of the GV-STNO reservoir computing system to demonstrate waveform classification.

Publisher

Research Square Platform LLC

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