Atomistic simulations of magnetoelastic effects on sound velocity

P. Nieves; J. Tranchida; S. Nikolov; Alberto Fraile; D. Legut

doi:10.1103/PhysRevB.105.134430

Atomistic simulations of magnetoelastic effects on sound velocity

P. Nieves, J. Tranchida, S. Nikolov, Alberto Fraile, D. Legut

School of Computer Science & Engineering

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Abstract

In this work, we leverage atomistic spin-lattice simulations to examine how magnetic interactions impact the propagation of sound waves through a ferromagnetic material. To achieve this, we characterize the sound wave velocity in BCC iron, a prototypical ferromagnetic material, using three different approaches that are based on the oscillations of kinetic energy, finite-displacement derived forces, and corrections to the elastic constants, respectively. Successfully applying these methods within the spin-lattice framework, we find good agreement with the Simon effect including high-order terms. In analogy to experiments, morphic coefficients associated with the transverse and longitudinal waves propagating along the [001] direction are extracted from fits to the fractional change in sound velocity data. The present efforts represent an advancement in magnetoelastic modeling capabilities which can expedite the design of future magnetoacoustic devices.

Original language	English
Article number	134430
Number of pages	20
Journal	Physical Review B
Volume	105
Issue number	13
DOIs	https://doi.org/10.1103/PhysRevB.105.134430
Publication status	Published - 26 Apr 2022

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AU - Nieves, P.

AU - Tranchida, J.

AU - Nikolov, S.

AU - Fraile, Alberto

AU - Legut, D.

PY - 2022/4/26

Y1 - 2022/4/26

N2 - In this work, we leverage atomistic spin-lattice simulations to examine how magnetic interactions impact the propagation of sound waves through a ferromagnetic material. To achieve this, we characterize the sound wave velocity in BCC iron, a prototypical ferromagnetic material, using three different approaches that are based on the oscillations of kinetic energy, finite-displacement derived forces, and corrections to the elastic constants, respectively. Successfully applying these methods within the spin-lattice framework, we find good agreement with the Simon effect including high-order terms. In analogy to experiments, morphic coefficients associated with the transverse and longitudinal waves propagating along the [001] direction are extracted from fits to the fractional change in sound velocity data. The present efforts represent an advancement in magnetoelastic modeling capabilities which can expedite the design of future magnetoacoustic devices.

AB - In this work, we leverage atomistic spin-lattice simulations to examine how magnetic interactions impact the propagation of sound waves through a ferromagnetic material. To achieve this, we characterize the sound wave velocity in BCC iron, a prototypical ferromagnetic material, using three different approaches that are based on the oscillations of kinetic energy, finite-displacement derived forces, and corrections to the elastic constants, respectively. Successfully applying these methods within the spin-lattice framework, we find good agreement with the Simon effect including high-order terms. In analogy to experiments, morphic coefficients associated with the transverse and longitudinal waves propagating along the [001] direction are extracted from fits to the fractional change in sound velocity data. The present efforts represent an advancement in magnetoelastic modeling capabilities which can expedite the design of future magnetoacoustic devices.

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Atomistic simulations of magnetoelastic effects on sound velocity

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