Bond-strength engineering beyond mass fluctuation: unraveling the dominant mechanism of lattice thermal conductivity suppression in neighboring-site doped β-FeSi2 thermoelectrics

Shengnan Dai; Jinyang Xi; Chin‐Wei Wang; Tōru Ishigaki; Yuting Li; Lu Gan; Jie Ma

doi:10.1039/d5ta03600c

Bond-strength engineering beyond mass fluctuation: unraveling the dominant mechanism of lattice thermal conductivity suppression in neighboring-site doped β-FeSi2 thermoelectrics

Shengnan Dai, Jinyang Xi(Shanghai Research Institute of Materials), Chin‐Wei Wang(National Synchrotron Radiation Research Center), Tōru Ishigaki(Comprehensive Research Organization for Science and Society), Yuting Li(Wuhan University of Science and Technology), Lu Gan(Shanghai Research Institute of Materials), Jie Ma(Dalian Institute of Chemical Physics)

Journal of Materials Chemistry A

January 1, 2025

10.1039/d5ta03600c

Cited by 1

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Bond-strength engineering beyond mass fluctuation: unraveling the dominant mechanism of lattice thermal conductivity suppression in neighboring-site doped β-FeSi<sub>2</sub> thermoelectrics

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