Improved Thermoelectric Performance of Tellurium by Alloying with a Small Concentration of Selenium to Decrease Lattice Thermal Conductivity

Udara Saparamadu; Chunhua Li; Ran He; Hangtian Zhu; Zhensong Ren; Jun Mao; Shaowei Song; Jingying Sun; Shuo Chen; Qinyong Zhang; Kornelius Nielsch; David Broido; Zhifeng Ren

doi:10.1021/acsami.8b13121

Improved Thermoelectric Performance of Tellurium by Alloying with a Small Concentration of Selenium to Decrease Lattice Thermal Conductivity

Udara Saparamadu
, Chunhua Li
, Ran He
, Hangtian Zhu
, Zhensong Ren
, Jun Mao
, Shaowei Song
, Jingying Sun
, Shuo Chen
, Qinyong Zhang
, Kornelius Nielsch
, David Broido
, Zhifeng Ren^*

^*Corresponding author for this work

University of Houston
Boston College
Leibniz Institute for Solid State and Materials Research Dresden
Xihua University

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

13 Scopus citations

Abstract

Phonon scattering through alloying is a highly effective way to reduce lattice thermal conductivity due to the mass difference between the host and alloyed atoms and strains caused by the different atoms. In this work we investigate the thermoelectric properties of Te between 323 and 623 K. By varying the alloying concentration of Se, a minimum lattice thermal conductivity was achieved with ∼10% (by stoichiometry) alloying of Te by Se. Additionally, Sb has been used as a dopant to increase the carrier concentration of the system. With reduced lattice thermal conductivity by Se alloying and increased carrier concentration by Sb doping, the room-temperature figure of merit (ZT) increased by 60%, leading to an average ZT of ∼0.8 in Te _0.88 Se _0.10 Sb _0.02 , which corresponds to an engineering figure of merit (ZT) _eng ∼ 0.5 between 323 and 623 K and an efficiency of ∼8% in the same temperature range. The results indicate that the combination of Se alloying and Sb doping is successful in improving the thermoelectric properties of Te.

Original language	English
Pages (from-to)	511-516
Number of pages	6
Journal	ACS Applied Materials and Interfaces
Volume	11
Issue number	1
DOIs	https://doi.org/10.1021/acsami.8b13121
State	Published - 9 Jan 2019
Externally published	Yes

Keywords

Te
alloying
average ZT
ball milling
elemental Te
hot pressing
thermoelectric

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10.1021/acsami.8b13121

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Saparamadu, U., Li, C., He, R., Zhu, H., Ren, Z., Mao, J., Song, S., Sun, J., Chen, S., Zhang, Q., Nielsch, K., Broido, D., & Ren, Z. (2019). Improved Thermoelectric Performance of Tellurium by Alloying with a Small Concentration of Selenium to Decrease Lattice Thermal Conductivity. ACS Applied Materials and Interfaces, 11(1), 511-516. https://doi.org/10.1021/acsami.8b13121

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title = "Improved Thermoelectric Performance of Tellurium by Alloying with a Small Concentration of Selenium to Decrease Lattice Thermal Conductivity",

abstract = " Phonon scattering through alloying is a highly effective way to reduce lattice thermal conductivity due to the mass difference between the host and alloyed atoms and strains caused by the different atoms. In this work we investigate the thermoelectric properties of Te between 323 and 623 K. By varying the alloying concentration of Se, a minimum lattice thermal conductivity was achieved with ∼10\% (by stoichiometry) alloying of Te by Se. Additionally, Sb has been used as a dopant to increase the carrier concentration of the system. With reduced lattice thermal conductivity by Se alloying and increased carrier concentration by Sb doping, the room-temperature figure of merit (ZT) increased by 60\%, leading to an average ZT of ∼0.8 in Te 0.88 Se 0.10 Sb 0.02 , which corresponds to an engineering figure of merit (ZT) eng ∼ 0.5 between 323 and 623 K and an efficiency of ∼8\% in the same temperature range. The results indicate that the combination of Se alloying and Sb doping is successful in improving the thermoelectric properties of Te.",

keywords = "Te, alloying, average ZT, ball milling, elemental Te, hot pressing, thermoelectric",

author = "Udara Saparamadu and Chunhua Li and Ran He and Hangtian Zhu and Zhensong Ren and Jun Mao and Shaowei Song and Jingying Sun and Shuo Chen and Qinyong Zhang and Kornelius Nielsch and David Broido and Zhifeng Ren",

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Saparamadu, U, Li, C, He, R, Zhu, H, Ren, Z, Mao, J, Song, S, Sun, J, Chen, S, Zhang, Q, Nielsch, K, Broido, D & Ren, Z 2019, 'Improved Thermoelectric Performance of Tellurium by Alloying with a Small Concentration of Selenium to Decrease Lattice Thermal Conductivity', ACS Applied Materials and Interfaces, vol. 11, no. 1, pp. 511-516. https://doi.org/10.1021/acsami.8b13121

TY - JOUR

T1 - Improved Thermoelectric Performance of Tellurium by Alloying with a Small Concentration of Selenium to Decrease Lattice Thermal Conductivity

AU - Saparamadu, Udara

AU - Li, Chunhua

AU - He, Ran

AU - Zhu, Hangtian

AU - Ren, Zhensong

AU - Mao, Jun

AU - Song, Shaowei

AU - Sun, Jingying

AU - Chen, Shuo

AU - Zhang, Qinyong

AU - Nielsch, Kornelius

AU - Broido, David

AU - Ren, Zhifeng

PY - 2019/1/9

Y1 - 2019/1/9

N2 - Phonon scattering through alloying is a highly effective way to reduce lattice thermal conductivity due to the mass difference between the host and alloyed atoms and strains caused by the different atoms. In this work we investigate the thermoelectric properties of Te between 323 and 623 K. By varying the alloying concentration of Se, a minimum lattice thermal conductivity was achieved with ∼10% (by stoichiometry) alloying of Te by Se. Additionally, Sb has been used as a dopant to increase the carrier concentration of the system. With reduced lattice thermal conductivity by Se alloying and increased carrier concentration by Sb doping, the room-temperature figure of merit (ZT) increased by 60%, leading to an average ZT of ∼0.8 in Te 0.88 Se 0.10 Sb 0.02 , which corresponds to an engineering figure of merit (ZT) eng ∼ 0.5 between 323 and 623 K and an efficiency of ∼8% in the same temperature range. The results indicate that the combination of Se alloying and Sb doping is successful in improving the thermoelectric properties of Te.

AB - Phonon scattering through alloying is a highly effective way to reduce lattice thermal conductivity due to the mass difference between the host and alloyed atoms and strains caused by the different atoms. In this work we investigate the thermoelectric properties of Te between 323 and 623 K. By varying the alloying concentration of Se, a minimum lattice thermal conductivity was achieved with ∼10% (by stoichiometry) alloying of Te by Se. Additionally, Sb has been used as a dopant to increase the carrier concentration of the system. With reduced lattice thermal conductivity by Se alloying and increased carrier concentration by Sb doping, the room-temperature figure of merit (ZT) increased by 60%, leading to an average ZT of ∼0.8 in Te 0.88 Se 0.10 Sb 0.02 , which corresponds to an engineering figure of merit (ZT) eng ∼ 0.5 between 323 and 623 K and an efficiency of ∼8% in the same temperature range. The results indicate that the combination of Se alloying and Sb doping is successful in improving the thermoelectric properties of Te.

KW - Te

KW - alloying

KW - average ZT

KW - ball milling

KW - elemental Te

KW - hot pressing

KW - thermoelectric

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DO - 10.1021/acsami.8b13121

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AN - SCOPUS:85059859936

SN - 1944-8244

VL - 11

SP - 511

EP - 516

JO - ACS Applied Materials and Interfaces

JF - ACS Applied Materials and Interfaces

IS - 1

ER -

Improved Thermoelectric Performance of Tellurium by Alloying with a Small Concentration of Selenium to Decrease Lattice Thermal Conductivity

Abstract

Keywords

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