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Main Authors: Mikhailova, Katya, Takana, Lerato, Qu, Guanxiong, Hofer, Juan A., Carruzzo, Hervé M., Schuller, Ivan K., Yu, Clare C., Suzuki, Yuri
Format: Preprint
Published: 2026
Subjects:
Online Access:https://arxiv.org/abs/2604.24094
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author Mikhailova, Katya
Takana, Lerato
Qu, Guanxiong
Hofer, Juan A.
Carruzzo, Hervé M.
Schuller, Ivan K.
Yu, Clare C.
Suzuki, Yuri
author_facet Mikhailova, Katya
Takana, Lerato
Qu, Guanxiong
Hofer, Juan A.
Carruzzo, Hervé M.
Schuller, Ivan K.
Yu, Clare C.
Suzuki, Yuri
contents The mechanisms underlying magnon damping are of fundamental and technological interest in low-damping materials. We find low-damping ferrimagnetic insulator Li$_{0.5}$Al$_{1.0}$Fe$_{1.5}$O$_4$ (LAFO) thin films to be a promising model system for probing these mechanisms because of its distinct temperature dependent spin diffusion length (SDL) trends for electrically and thermally generated magnons. With increasing temperature, the electrical SDL shows minimal change, while the thermal SDL decreases. We attribute these trends to distinct magnon populations and scattering mechanisms: thermally generated high $k$ magnons are limited by magnon-phonon scattering, whereas electrically generated low $k$ magnons are limited by relaxational scattering from magnetic impurities.
format Preprint
id arxiv_https___arxiv_org_abs_2604_24094
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Understanding Damping Mechanisms via Spin Diffusion Length in Low-damping Li$_{0.5}$Al$_{1.0}$Fe$_{1.5}$O$_4$ Spinel Ferrite Thin Films
Mikhailova, Katya
Takana, Lerato
Qu, Guanxiong
Hofer, Juan A.
Carruzzo, Hervé M.
Schuller, Ivan K.
Yu, Clare C.
Suzuki, Yuri
Materials Science
The mechanisms underlying magnon damping are of fundamental and technological interest in low-damping materials. We find low-damping ferrimagnetic insulator Li$_{0.5}$Al$_{1.0}$Fe$_{1.5}$O$_4$ (LAFO) thin films to be a promising model system for probing these mechanisms because of its distinct temperature dependent spin diffusion length (SDL) trends for electrically and thermally generated magnons. With increasing temperature, the electrical SDL shows minimal change, while the thermal SDL decreases. We attribute these trends to distinct magnon populations and scattering mechanisms: thermally generated high $k$ magnons are limited by magnon-phonon scattering, whereas electrically generated low $k$ magnons are limited by relaxational scattering from magnetic impurities.
title Understanding Damping Mechanisms via Spin Diffusion Length in Low-damping Li$_{0.5}$Al$_{1.0}$Fe$_{1.5}$O$_4$ Spinel Ferrite Thin Films
topic Materials Science
url https://arxiv.org/abs/2604.24094