Studies of vacancy-mediated anomalous transport properties have flourished in diverse fields since these properties endow solid materials with fascinating photoelectric, ferroelectric, and spin-electric behaviors. Although phononic and electronic transport underpin the physical origin of thermoelectrics, vacancy has only played a stereotyped role as a scattering center. Here we reveal the multifunctionality of vacancy in tailoring the transport properties of an emerging thermoelectric material, defective n-type ZrNiBi. The phonon kinetic process is mediated in both propagating velocity and relaxation time: vacancy-induced local soft bonds lower the phonon velocity while acoustic-optical phonon coupling, anisotropic vibrations, and point-defect scattering induced by vacancy shorten the relaxation time. Consequently, defective ZrNiBi exhibits the lowest lattice thermal conductivity among the half-Heusler family. In addition, a vacancy-induced flat band features prominently in its electronic band structure, which is not only desirable for electron-sufficient thermoelectric materials but also interesting for driving other novel physical phenomena. Finally, better thermoelectric performance is established in a ZrNiBi-based compound. Our findings not only demonstrate a promising thermoelectric material but also promote the fascinating vacancy-mediated anomalous transport properties for multidisciplinary explorations.
%0 Journal Article
%1 ren2023vacancymediated
%A Ren, Wuyang
%A Xue, Wenhua
%A Guo, Shuping
%A He, Ran
%A Deng, Liangzi
%A Song, Shaowei
%A Sotnikov, Andrei
%A Nielsch, Kornelius
%A van den Brink, Jeroen
%A Gao, Guanhui
%A Chen, Shuo
%A Han, Yimo
%A Wu, Jiang
%A Chu, Ching-Wu
%A Wang, Zhiming
%A Wang, Yumei
%A Ren, Zhifeng
%D 2023
%J Nat. Commun
%K a b
%N 1
%P 4722--
%R 10.1038/s41467-023-40492-7
%T Vacancy-mediated anomalous phononic and electronic transport in defective half-Heusler ZrNiBi
%U https://doi.org/10.1038/s41467-023-40492-7
%V 14
%X Studies of vacancy-mediated anomalous transport properties have flourished in diverse fields since these properties endow solid materials with fascinating photoelectric, ferroelectric, and spin-electric behaviors. Although phononic and electronic transport underpin the physical origin of thermoelectrics, vacancy has only played a stereotyped role as a scattering center. Here we reveal the multifunctionality of vacancy in tailoring the transport properties of an emerging thermoelectric material, defective n-type ZrNiBi. The phonon kinetic process is mediated in both propagating velocity and relaxation time: vacancy-induced local soft bonds lower the phonon velocity while acoustic-optical phonon coupling, anisotropic vibrations, and point-defect scattering induced by vacancy shorten the relaxation time. Consequently, defective ZrNiBi exhibits the lowest lattice thermal conductivity among the half-Heusler family. In addition, a vacancy-induced flat band features prominently in its electronic band structure, which is not only desirable for electron-sufficient thermoelectric materials but also interesting for driving other novel physical phenomena. Finally, better thermoelectric performance is established in a ZrNiBi-based compound. Our findings not only demonstrate a promising thermoelectric material but also promote the fascinating vacancy-mediated anomalous transport properties for multidisciplinary explorations.
@article{ren2023vacancymediated,
abstract = {Studies of vacancy-mediated anomalous transport properties have flourished in diverse fields since these properties endow solid materials with fascinating photoelectric, ferroelectric, and spin-electric behaviors. Although phononic and electronic transport underpin the physical origin of thermoelectrics, vacancy has only played a stereotyped role as a scattering center. Here we reveal the multifunctionality of vacancy in tailoring the transport properties of an emerging thermoelectric material, defective n-type ZrNiBi. The phonon kinetic process is mediated in both propagating velocity and relaxation time: vacancy-induced local soft bonds lower the phonon velocity while acoustic-optical phonon coupling, anisotropic vibrations, and point-defect scattering induced by vacancy shorten the relaxation time. Consequently, defective ZrNiBi exhibits the lowest lattice thermal conductivity among the half-Heusler family. In addition, a vacancy-induced flat band features prominently in its electronic band structure, which is not only desirable for electron-sufficient thermoelectric materials but also interesting for driving other novel physical phenomena. Finally, better thermoelectric performance is established in a ZrNiBi-based compound. Our findings not only demonstrate a promising thermoelectric material but also promote the fascinating vacancy-mediated anomalous transport properties for multidisciplinary explorations.},
added-at = {2023-11-22T18:32:48.000+0100},
author = {Ren, Wuyang and Xue, Wenhua and Guo, Shuping and He, Ran and Deng, Liangzi and Song, Shaowei and Sotnikov, Andrei and Nielsch, Kornelius and van den Brink, Jeroen and Gao, Guanhui and Chen, Shuo and Han, Yimo and Wu, Jiang and Chu, Ching-Wu and Wang, Zhiming and Wang, Yumei and Ren, Zhifeng},
biburl = {https://www.bibsonomy.org/bibtex/28e664f7f8d7f8994b73870983a430d39/ctqmat},
day = 05,
doi = {10.1038/s41467-023-40492-7},
interhash = {248605ed8b3d1bd5a78df6a74b9eb298},
intrahash = {8e664f7f8d7f8994b73870983a430d39},
issn = {20411723},
journal = {Nat. Commun},
keywords = {a b},
month = {08},
number = 1,
pages = {4722--},
refid = {Ren2023},
timestamp = {2023-11-22T18:32:48.000+0100},
title = {Vacancy-mediated anomalous phononic and electronic transport in defective half-Heusler ZrNiBi},
url = {https://doi.org/10.1038/s41467-023-40492-7},
volume = 14,
year = 2023
}