Stress Engineering of Thermal Fluctuation of Magnetization and Noise Spectra in Low Barrier Nanomagnets Used as Analog and Binary Stochastic Neurons

TL;DR

This paper explores how stress can be used to control the magnetic noise spectra in nanomagnets, enabling transition from binary to analog stochastic neurons and potential applications in signal processing.

Contribution

It demonstrates stress-induced tuning of magnetization fluctuations from telegraph noise to white noise in nanomagnets, introducing a method for noise engineering in magnetic devices.

Findings

Stress reduces the energy barrier, transitioning noise from telegraph to white noise.

Noise spectral density follows a 1/f^beta pattern with beta decreasing under stress.

Magnetization fluctuations can be tuned for signal processing applications.

Abstract

A single-domain nanomagnet, shaped like a thin elliptical disk with small eccentricity, has a double well potential profile with two degenerate energy minima separated by a small barrier of a few kT (k = Boltzmann constant and T = absolute temperature). The two minima correspond to the magnetization pointing along the two mutually anti-parallel directions along the major axis. At room temperature, the magnetization fluctuates between the two minima mimicking telegraph noise. This makes the nanomagnet act as a "binary" stochastic neuron (BSN) with the neuronal state encoded in the magnetization orientation. If the nanomagnet is magnetostrictive, then the barrier can be depressed further by applying (electrically generated) uniaxial stress along the ellipse's major axis, thereby gradually eroding the double well shape. When the barrier almost vanishes, the magnetization begins to randomly assume any arbitrary orientation (not just along the major axis), making the nanomagnet act as an "analog" stochastic neuron (ASN). The magnetization fluctuation then begins to increasingly resemble white noise. The full-width-at-half-maximum (FWHM) of the noise auto-correlation function decreases with increasing stress, as the fluctuation gradually transforms from telegraph noise to white noise. The noise spectral density exhibits a 1/f^(beta) spectrum (at high frequencies) with "beta" decreasing with increasing stress, which is again characteristic of the transition from telegraph to white noise. Stress can thus not only reconfigure a BSN to an ASN, which has its own applications, but it can also perform "noise engineering", i.e., tune the auto-correlation function and power spectral density. That can have applications in signal processing.