# Bursty magnetic friction between polycrystalline thin films with domain   walls

**Authors:** Ilari Rissanen, Lasse Laurson

arXiv: 1906.06506 · 2019-10-09

## TL;DR

This paper investigates magnetic friction between polycrystalline thin films with domain walls using micromagnetic simulations, revealing how disorder and dynamics lead to energy dissipation bursts and influencing magnetization behavior.

## Contribution

It introduces a detailed simulation study of magnetic friction in disordered thin films, highlighting the role of domain wall pinning and depinning in energy dissipation.

## Key findings

- Bursts of magnetic activity linked to domain wall pinning and depinning.
- Energy dissipation peaks correlate with domain wall jumps.
- Polycrystalline structure properties significantly influence magnetization dynamics.

## Abstract

Two magnets in relative motion interact through their dipolar fields, making individual magnetic moments dynamically adapt to the changes in the energy landscape and bringing about collective magnetization dynamics. Some of the energy of the system is irrevocably lost through various coupling mechanisms between the spin degrees of freedom and those of the underlying lattice, resulting in magnetic friction. In this work, we use micromagnetic simulations to study magnetic friction in a system of two thin ferromagnetic films containing quenched disorder mimicking a polycrystalline structure. We observe bursts of magnetic activity resulting from repeated domain wall pinning due to the disorder and subsequent depinning triggered by the dipolar interaction between the moving films. These domain wall jumps result in strong energy dissipation peaks. We study how the properties of the polycrystalline structure such as grain size and strength of the disorder, along with the driving velocity and the width of the films, affect the magnetization dynamics, average energy dissipation as well as the statistical properties of the energy dissipation bursts.

## Full text

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## Figures

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## References

40 references — full list in the complete paper: https://tomesphere.com/paper/1906.06506/full.md

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Source: https://tomesphere.com/paper/1906.06506