Suppressed phase transition and enhanced thermoelectric performance in iodine-doped AgCuTe

Yi Niu; Shan Li; Jun Mao; Chengcheng Yang; Qinyong Zhang; Qian Zhang; Jing Jiang; Chao Wang; Zhifeng Ren

doi:10.1016/j.nanoen.2020.105297

Suppressed phase transition and enhanced thermoelectric performance in iodine-doped AgCuTe

Yi Niu, Shan Li, Jun Mao, Chengcheng Yang, Qinyong Zhang, Qian Zhang, Jing Jiang, Chao Wang, Zhifeng Ren

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

28 Scopus citations

Abstract

AgCuTe has been recognized as a promising thermoelectric material due to its reported ultralow lattice thermal conductivity, but its phase transition and unsatisfactory thermoelectric performance at close to room temperature restrict its application for the harvesting of low-grade heat. In this work, the near-room-temperature phase transition is successfully avoided by iodine doping at the Te site. In addition, iodine doping effectively reduces the hole concentration, thus greatly increasing the Seebeck coefficient and improving the average power factor, as well as reducing the electronic thermal conductivity. Consequently, a room-temperature ZT of ~0.35 and a maximum ZT of ~0.9 at 463 K were obtained in AgCuTe_0.9I_0.1, leading to a high average ZT of ~0.6 between 303 and 463 K. Our work paves a new way for realizing stable high performance in AgCuTe-based materials for thermoelectric applications.

Original language	English
Article number	105297
Journal	Nano Energy
Volume	77
DOIs	https://doi.org/10.1016/j.nanoen.2020.105297
State	Published - Nov 2020
Externally published	Yes

Keywords

AgCuTe
Average ZT
Hole concentration
Phase transition
Thermoelectric material

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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10.1016/j.nanoen.2020.105297

Cite this

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title = "Suppressed phase transition and enhanced thermoelectric performance in iodine-doped AgCuTe",

abstract = "AgCuTe has been recognized as a promising thermoelectric material due to its reported ultralow lattice thermal conductivity, but its phase transition and unsatisfactory thermoelectric performance at close to room temperature restrict its application for the harvesting of low-grade heat. In this work, the near-room-temperature phase transition is successfully avoided by iodine doping at the Te site. In addition, iodine doping effectively reduces the hole concentration, thus greatly increasing the Seebeck coefficient and improving the average power factor, as well as reducing the electronic thermal conductivity. Consequently, a room-temperature ZT of ~0.35 and a maximum ZT of ~0.9 at 463 K were obtained in AgCuTe0.9I0.1, leading to a high average ZT of ~0.6 between 303 and 463 K. Our work paves a new way for realizing stable high performance in AgCuTe-based materials for thermoelectric applications.",

keywords = "AgCuTe, Average ZT, Hole concentration, Phase transition, Thermoelectric material",

author = "Yi Niu and Shan Li and Jun Mao and Chengcheng Yang and Qinyong Zhang and Qian Zhang and Jing Jiang and Chao Wang and Zhifeng Ren",

note = "Publisher Copyright: {\textcopyright} 2020 Elsevier Ltd",

year = "2020",

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doi = "10.1016/j.nanoen.2020.105297",

language = "英语",

volume = "77",

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T1 - Suppressed phase transition and enhanced thermoelectric performance in iodine-doped AgCuTe

AU - Niu, Yi

AU - Li, Shan

AU - Mao, Jun

AU - Yang, Chengcheng

AU - Zhang, Qinyong

AU - Zhang, Qian

AU - Jiang, Jing

AU - Wang, Chao

AU - Ren, Zhifeng

PY - 2020/11

Y1 - 2020/11

N2 - AgCuTe has been recognized as a promising thermoelectric material due to its reported ultralow lattice thermal conductivity, but its phase transition and unsatisfactory thermoelectric performance at close to room temperature restrict its application for the harvesting of low-grade heat. In this work, the near-room-temperature phase transition is successfully avoided by iodine doping at the Te site. In addition, iodine doping effectively reduces the hole concentration, thus greatly increasing the Seebeck coefficient and improving the average power factor, as well as reducing the electronic thermal conductivity. Consequently, a room-temperature ZT of ~0.35 and a maximum ZT of ~0.9 at 463 K were obtained in AgCuTe0.9I0.1, leading to a high average ZT of ~0.6 between 303 and 463 K. Our work paves a new way for realizing stable high performance in AgCuTe-based materials for thermoelectric applications.

AB - AgCuTe has been recognized as a promising thermoelectric material due to its reported ultralow lattice thermal conductivity, but its phase transition and unsatisfactory thermoelectric performance at close to room temperature restrict its application for the harvesting of low-grade heat. In this work, the near-room-temperature phase transition is successfully avoided by iodine doping at the Te site. In addition, iodine doping effectively reduces the hole concentration, thus greatly increasing the Seebeck coefficient and improving the average power factor, as well as reducing the electronic thermal conductivity. Consequently, a room-temperature ZT of ~0.35 and a maximum ZT of ~0.9 at 463 K were obtained in AgCuTe0.9I0.1, leading to a high average ZT of ~0.6 between 303 and 463 K. Our work paves a new way for realizing stable high performance in AgCuTe-based materials for thermoelectric applications.

KW - AgCuTe

KW - Average ZT

KW - Hole concentration

KW - Phase transition

KW - Thermoelectric material

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U2 - 10.1016/j.nanoen.2020.105297

DO - 10.1016/j.nanoen.2020.105297

M3 - 文章

AN - SCOPUS:85089954528

SN - 2211-2855

VL - 77

JO - Nano Energy

JF - Nano Energy

M1 - 105297

ER -

Suppressed phase transition and enhanced thermoelectric performance in iodine-doped AgCuTe

Abstract

Keywords

UN SDGs

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