Your search keyword '"Inverse Shear (ISHE)"' showing total 2 results

1. Ultra-fast artificial neuron: generation of picosecond-duration spikes in a current-driven antiferromagnetic auto-oscillator

Author

Roman Khymyn, Ivan Lisenkov, James Voorheis, Olga Sulymenko, Oleksandr Prokopenko, Vasil Tiberkevich, Johan Akerman, and Andrei Slavin

Subjects

Biaxial Magnetic Anisotropy, Spike Generation, Neel Vector, Slave Neuron, Inverse Shear (ISHE), Medicine, Science

Abstract

Abstract We demonstrate analytically and numerically, that a thin film of an antiferromagnetic (AFM) material, having biaxial magnetic anisotropy and being driven by an external spin-transfer torque signal, can be used for the generation of ultra-short “Dirac-delta-like” spikes. The duration of the generated spikes is several picoseconds for typical AFM materials and is determined by the inplane magnetic anisotropy and the effective damping of the AFM material. The generated output signal can consist of a single spike or a discrete group of spikes (“bursting”), which depends on the repetition (clock) rate, amplitude, and shape of the external control signal. The spike generation occurs only when the amplitude of the control signal exceeds a certain threshold, similar to the action of a biological neuron in response to an external stimulus. The “threshold” behavior of the proposed AFM spike generator makes possible its application not only in the traditional microwave signal processing but also in the future neuromorphic signal processing circuits working at clock frequencies of tens of gigahertz.

Published

2018

2. Ultra-fast artificial neuron: generation of picosecond-duration spikes in a current-driven antiferromagnetic auto-oscillator

Author

Ivan Lisenkov, Roman Khymyn, Andrei Slavin, Olga Sulymenko, James Voorheis, Vasil Tiberkevich, Johan Åkerman, and Oleksandr Prokopenko

Subjects

Science, FOS: Physical sciences, Action Potentials, 02 engineering and technology, 01 natural sciences, Article, Bursting, Magnetics, Biomimetics, 0103 physical sciences, Mesoscale and Nanoscale Physics (cond-mat.mes-hall), Artificial neuron, Inverse Shear (ISHE), Torque, Thin film, 010306 general physics, Physics, Neurons, Multidisciplinary, Condensed Matter - Mesoscale and Nanoscale Physics, Quantitative Biology::Neurons and Cognition, business.industry, Slave Neuron, Spike Generation, Signal Processing, Computer-Assisted, 021001 nanoscience & nanotechnology, Magnetic anisotropy, Amplitude, Neuromorphic engineering, Picosecond, Magnets, Optoelectronics, Medicine, Anisotropy, Biaxial Magnetic Anisotropy, 0210 nano-technology, business, Neel Vector

Abstract

We demonstrate analytically and numerically, that a thin film of an antiferromagnetic (AFM) material, having biaxial magnetic anisotropy and being driven by an external spin-transfer torque signal, can be used for the generation of ultra-short “Dirac-delta-like” spikes. The duration of the generated spikes is several picoseconds for typical AFM materials and is determined by the inplane magnetic anisotropy and the effective damping of the AFM material. The generated output signal can consist of a single spike or a discrete group of spikes (“bursting”), which depends on the repetition (clock) rate, amplitude, and shape of the external control signal. The spike generation occurs only when the amplitude of the control signal exceeds a certain threshold, similar to the action of a biological neuron in response to an external stimulus. The “threshold” behavior of the proposed AFM spike generator makes possible its application not only in the traditional microwave signal processing but also in the future neuromorphic signal processing circuits working at clock frequencies of tens of gigahertz.

Published

2018