Signature of electron-magnon Umklapp scattering in L 10FePt probed by thermoelectric measurements

Xiaoxian Yan; Chang Huai; Hui Xing; James P. Parry; Yusen Yang; Guoxiong Tang; Chao Yao; Guohan Hu; Renat Sabirianov; Hao Zeng

doi:10.1063/5.0059591

Signature of electron-magnon Umklapp scattering in L 1₀FePt probed by thermoelectric measurements

Xiaoxian Yan, Chang Huai, Hui Xing, James P. Parry, Yusen Yang, Guoxiong Tang, Chao Yao, Guohan Hu, Renat Sabirianov, Hao Zeng

Physics

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

We report unconventional thermoelectric power (Seebeck coefficient, S) in L10 structured FePt films. The temperature dependence of S can be well fitted by a phenomenological expression consisting of electron diffusion and magnon-drag contributions. Interestingly, the magnon drag coefficient carries an opposite sign to that of electron diffusion, revealing a dominant contribution from the elusive electron-magnon Umklapp scattering. Density-functional theory calculations identify several bands crossing the Brillouin zone boundaries, facilitating the Umklapp process. The large spin-orbit coupling in FePt results in strong mixing of majority and minority spins among some of those bands, greatly enhancing the electron-magnon scattering.

Original language	English (US)
Article number	182402
Journal	Applied Physics Letters
Volume	119
Issue number	18
DOIs	https://doi.org/10.1063/5.0059591
State	Published - Nov 1 2021

ASJC Scopus subject areas

Physics and Astronomy (miscellaneous)

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title = "Signature of electron-magnon Umklapp scattering in L 10FePt probed by thermoelectric measurements",

abstract = "We report unconventional thermoelectric power (Seebeck coefficient, S) in L10 structured FePt films. The temperature dependence of S can be well fitted by a phenomenological expression consisting of electron diffusion and magnon-drag contributions. Interestingly, the magnon drag coefficient carries an opposite sign to that of electron diffusion, revealing a dominant contribution from the elusive electron-magnon Umklapp scattering. Density-functional theory calculations identify several bands crossing the Brillouin zone boundaries, facilitating the Umklapp process. The large spin-orbit coupling in FePt results in strong mixing of majority and minority spins among some of those bands, greatly enhancing the electron-magnon scattering.",

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T1 - Signature of electron-magnon Umklapp scattering in L 10FePt probed by thermoelectric measurements

AU - Yan, Xiaoxian

AU - Huai, Chang

AU - Xing, Hui

AU - Parry, James P.

AU - Yang, Yusen

AU - Tang, Guoxiong

AU - Yao, Chao

AU - Hu, Guohan

AU - Sabirianov, Renat

AU - Zeng, Hao

PY - 2021/11/1

Y1 - 2021/11/1

N2 - We report unconventional thermoelectric power (Seebeck coefficient, S) in L10 structured FePt films. The temperature dependence of S can be well fitted by a phenomenological expression consisting of electron diffusion and magnon-drag contributions. Interestingly, the magnon drag coefficient carries an opposite sign to that of electron diffusion, revealing a dominant contribution from the elusive electron-magnon Umklapp scattering. Density-functional theory calculations identify several bands crossing the Brillouin zone boundaries, facilitating the Umklapp process. The large spin-orbit coupling in FePt results in strong mixing of majority and minority spins among some of those bands, greatly enhancing the electron-magnon scattering.

AB - We report unconventional thermoelectric power (Seebeck coefficient, S) in L10 structured FePt films. The temperature dependence of S can be well fitted by a phenomenological expression consisting of electron diffusion and magnon-drag contributions. Interestingly, the magnon drag coefficient carries an opposite sign to that of electron diffusion, revealing a dominant contribution from the elusive electron-magnon Umklapp scattering. Density-functional theory calculations identify several bands crossing the Brillouin zone boundaries, facilitating the Umklapp process. The large spin-orbit coupling in FePt results in strong mixing of majority and minority spins among some of those bands, greatly enhancing the electron-magnon scattering.

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Signature of electron-magnon Umklapp scattering in L 1₀FePt probed by thermoelectric measurements

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