Strong phonon softening and avoided crossing in aliovalence-doped heavy-band thermoelectrics

Strong phonon softening and avoided crossing in aliovalence-doped heavy-band thermoelectrics

Aliovalent doping is a way to optimize the electrical properties of semiconductors, but its impact on the phonon structure and propagation is seldom considered properly. Here we show that aliovalent doping can be much more effective in reducing the lattice thermal conductivity of thermoelectric semi...

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Bibliographic Details
Published in:Nature physics Vol. 19; no. 11; pp. 1649 - 1657
Main Authors: Han, Shen, Dai, Shengnan, Ma, Jie, Ren, Qingyong, Hu, Chaoliang, Gao, Ziheng, Duc Le, Manh, Sheptyakov, Denis, Miao, Ping, Torii, Shuki, Kamiyama, Takashi, Felser, Claudia, Yang, Jiong, Fu, Chenguang, Zhu, Tiejun
Format: Journal Article
Language:English
Published: London Nature Publishing Group UK 01-11-2023
Nature Publishing Group
Subjects:
119/118
639/301/119/1000
639/766/119/1000
Alloying
Atomic
Classical and Continuum Physics
Complex Systems
Condensed Matter Physics
Current carriers
Deceleration
Dopants
Doping
Electrical properties
Heat conductivity
Heat transfer
Mathematical and Computational Physics
Molecular
Optical and Plasma Physics
Phonons
Physics
Physics and Astronomy
Reduction
Semiconductors
Softening
Theoretical
Thermal conductivity
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Summary:Aliovalent doping is a way to optimize the electrical properties of semiconductors, but its impact on the phonon structure and propagation is seldom considered properly. Here we show that aliovalent doping can be much more effective in reducing the lattice thermal conductivity of thermoelectric semiconductors than the commonly employed isoelectronic alloying strategy. We demonstrate this in the heavy-band NbFeSb system, finding that a reduction of 65% in the lattice thermal conductivity is achieved through only 10% aliovalent Hf doping, compared with the four times higher isoelectronic Ta alloying. We show that aliovalent doping introduces free charge carriers and enhances screening, leading to the softening and deceleration of optical phonons. Moreover, the heavy dopant can induce the avoided crossing of acoustic and optical phonon branches, decelerating the acoustic phonons. These results highlight the significant role of aliovalent dopants in regulating the phonon structure and suppressing the phonon propagation of semiconductors. Aliovalent doping affects the electrical properties of semiconductors, but its effect on phonons is unclear. Now, strong softening and deceleration of phonons, causing a significant reduction in lattice thermal conductivity, is reported for Hf-doped NbFeSb.
ISSN:1745-2473
1745-2481
DOI:10.1038/s41567-023-02188-z