Thermoelectric SnTe with Band Convergence, Dense Dislocations, and Interstitials through Sn Self-Compensation and Mn Alloying

Fengkai Guo; Bo Cui; Yuan Liu; Xianfu Meng; Jian Cao; Yang Zhang; Ran He; Weishu Liu; Haijun Wu; Stephen J. Pennycook; Wei Cai; Jiehe Sui

doi:10.1002/smll.201802615

Thermoelectric SnTe with Band Convergence, Dense Dislocations, and Interstitials through Sn Self-Compensation and Mn Alloying

Fengkai Guo
, Bo Cui
, Yuan Liu
, Xianfu Meng
, Jian Cao
, Yang Zhang
, Ran He
, Weishu Liu
, Haijun Wu
, Stephen J. Pennycook
, Wei Cai
, Jiehe Sui

Harbin Institute of Technology
University of Houston
National University of Singapore
Leibniz Institute for Solid State and Materials Research Dresden
Southern University of Science and Technology

科研成果: 期刊稿件 › 文章 › 同行评审

169 引用（Scopus）

摘要

SnTe is known as an eco-friendly analogue of PbTe without toxic elements. However, the application potentials of pure SnTe are limited because of its high hole carrier concentration derived from intrinsic Sn vacancies, which lead to a high electrical thermal conductivity and low Seebeck coefficient. In this study, Sn self-compensation and Mn alloying could significantly improve the Seebeck coefficients in the whole temperature range through simultaneous carrier concentration optimization and band engineering, thereby leading to a large improvement of the power factors. Combining precipitates and atomic-scale interstitials due to Mn alloying with dense dislocations induced by long time annealing, the lattice thermal conductivity is drastically reduced. As a result, an enhanced figure of merit (ZT) of 1.35 is achieved for the composition of Sn_0.94Mn_0.09Te at 873 K and the ZT_ave from 300 to 873 K is boosted to 0.78, which is of great significance for practical application. Hitherto, the ZT_max and ZT_ave of this work are the highest values among all single-element-doped SnTe systems.

源语言	英语
文章编号	1802615
期刊	Small
卷	14
期	37
DOI	https://doi.org/10.1002/smll.201802615
出版状态	已出版 - 13 9月 2018
已对外发布	是

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@article{b5538d50e86443ec897f4cf273147e86,

title = "Thermoelectric SnTe with Band Convergence, Dense Dislocations, and Interstitials through Sn Self-Compensation and Mn Alloying",

abstract = "SnTe is known as an eco-friendly analogue of PbTe without toxic elements. However, the application potentials of pure SnTe are limited because of its high hole carrier concentration derived from intrinsic Sn vacancies, which lead to a high electrical thermal conductivity and low Seebeck coefficient. In this study, Sn self-compensation and Mn alloying could significantly improve the Seebeck coefficients in the whole temperature range through simultaneous carrier concentration optimization and band engineering, thereby leading to a large improvement of the power factors. Combining precipitates and atomic-scale interstitials due to Mn alloying with dense dislocations induced by long time annealing, the lattice thermal conductivity is drastically reduced. As a result, an enhanced figure of merit (ZT) of 1.35 is achieved for the composition of Sn0.94Mn0.09Te at 873 K and the ZTave from 300 to 873 K is boosted to 0.78, which is of great significance for practical application. Hitherto, the ZTmax and ZTave of this work are the highest values among all single-element-doped SnTe systems.",

keywords = "SnTe, band convergence, dislocations, interstitials, self-compensation",

author = "Fengkai Guo and Bo Cui and Yuan Liu and Xianfu Meng and Jian Cao and Yang Zhang and Ran He and Weishu Liu and Haijun Wu and Pennycook, \{Stephen J.\} and Wei Cai and Jiehe Sui",

note = "Publisher Copyright: {\textcopyright} 2018 WILEY-VCH Verlag GmbH \& Co. KGaA, Weinheim",

year = "2018",

month = sep,

day = "13",

doi = "10.1002/smll.201802615",

language = "英语",

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T1 - Thermoelectric SnTe with Band Convergence, Dense Dislocations, and Interstitials through Sn Self-Compensation and Mn Alloying

AU - Guo, Fengkai

AU - Cui, Bo

AU - Liu, Yuan

AU - Meng, Xianfu

AU - Cao, Jian

AU - Zhang, Yang

AU - He, Ran

AU - Liu, Weishu

AU - Wu, Haijun

AU - Pennycook, Stephen J.

AU - Cai, Wei

AU - Sui, Jiehe

PY - 2018/9/13

Y1 - 2018/9/13

N2 - SnTe is known as an eco-friendly analogue of PbTe without toxic elements. However, the application potentials of pure SnTe are limited because of its high hole carrier concentration derived from intrinsic Sn vacancies, which lead to a high electrical thermal conductivity and low Seebeck coefficient. In this study, Sn self-compensation and Mn alloying could significantly improve the Seebeck coefficients in the whole temperature range through simultaneous carrier concentration optimization and band engineering, thereby leading to a large improvement of the power factors. Combining precipitates and atomic-scale interstitials due to Mn alloying with dense dislocations induced by long time annealing, the lattice thermal conductivity is drastically reduced. As a result, an enhanced figure of merit (ZT) of 1.35 is achieved for the composition of Sn0.94Mn0.09Te at 873 K and the ZTave from 300 to 873 K is boosted to 0.78, which is of great significance for practical application. Hitherto, the ZTmax and ZTave of this work are the highest values among all single-element-doped SnTe systems.

AB - SnTe is known as an eco-friendly analogue of PbTe without toxic elements. However, the application potentials of pure SnTe are limited because of its high hole carrier concentration derived from intrinsic Sn vacancies, which lead to a high electrical thermal conductivity and low Seebeck coefficient. In this study, Sn self-compensation and Mn alloying could significantly improve the Seebeck coefficients in the whole temperature range through simultaneous carrier concentration optimization and band engineering, thereby leading to a large improvement of the power factors. Combining precipitates and atomic-scale interstitials due to Mn alloying with dense dislocations induced by long time annealing, the lattice thermal conductivity is drastically reduced. As a result, an enhanced figure of merit (ZT) of 1.35 is achieved for the composition of Sn0.94Mn0.09Te at 873 K and the ZTave from 300 to 873 K is boosted to 0.78, which is of great significance for practical application. Hitherto, the ZTmax and ZTave of this work are the highest values among all single-element-doped SnTe systems.

KW - SnTe

KW - band convergence

KW - dislocations

KW - interstitials

KW - self-compensation

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DO - 10.1002/smll.201802615

M3 - 文章

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AN - SCOPUS:85052759688

SN - 1613-6810

VL - 14

JO - Small

JF - Small

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M1 - 1802615

ER -

Thermoelectric SnTe with Band Convergence, Dense Dislocations, and Interstitials through Sn Self-Compensation and Mn Alloying

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