Dynamic doping and Cottrell atmosphere optimize the thermoelectric performance of n-type PbTe

High thermoelectric energy conversion efficiency requires a large figure-of-merit, zT, over a broad temperature range. To achieve this, we optimize the carrier concentrations of n-type PbTe from room up to hot-end temperatures by co-doping Bi and Ag. Bi is an efficient n-type dopant in PbTe, often l...

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Veröffentlicht in:	arXiv.org 2022-03
Hauptverfasser:	Yu, Yuan, Zhou, Chongjian, Zhang, Xiangzhao, Abdellaoui, Lamya, Doberstein, Christian, Berkels, Benjamin, Ge, Bangzhi, Qiao, Guanjun, Scheu, Christina, Wuttig, Matthias, Cojocaru-Mirédin, Oana, Zhang, Siyuan
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Schlagworte:	Bismuth Carrier density Density functional theory Dopants Doping Energy conversion efficiency Heat conductivity Heat transfer High temperature Intermetallic compounds Interstitials Optimization Phonons Physics - Materials Science Power factor Precipitates Room temperature Scattering Strong interactions (field theory) Temperature Temperature dependence Thermal conductivity Thermoelectricity
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creator	Yu, Yuan Zhou, Chongjian Zhang, Xiangzhao Abdellaoui, Lamya Doberstein, Christian Berkels, Benjamin Ge, Bangzhi Qiao, Guanjun Scheu, Christina Wuttig, Matthias Cojocaru-Mirédin, Oana Zhang, Siyuan
description	High thermoelectric energy conversion efficiency requires a large figure-of-merit, zT, over a broad temperature range. To achieve this, we optimize the carrier concentrations of n-type PbTe from room up to hot-end temperatures by co-doping Bi and Ag. Bi is an efficient n-type dopant in PbTe, often leading to excessive carrier concentration at room temperature. As revealed by density functional theory calculations, the formation of Bi and Ag defect complexes is exploited to optimize the room temperature carrier concentration. At elevated temperatures, we demonstrate the dynamic dissolution of Ag2Te precipitates in PbTe in situ by heating in a scanning transmission electron microscope. The release of n-type Ag interstitials with increasing temperature fulfills the requirement of higher carrier concentrations at the hot end. Moreover, as characterized by atom probe tomography, Ag atoms aggregate along parallel dislocation arrays to form Cottrell atmospheres. This results in enhanced phonon scattering and leads to a low lattice thermal conductivity. As a result of the synergy of dynamic doping and phonon scattering at decorated dislocations, an average zT of 1.0 is achieved in n-type Bi/Ag-codoped PbTe between 400 and 825 K. Introducing dopants with temperature-dependent solubility and strong interaction with dislocation cores enables simultaneous optimization of the average power factor and thermal conductivity, providing a new concept to exploit in the field of thermoelectrics.
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To achieve this, we optimize the carrier concentrations of n-type PbTe from room up to hot-end temperatures by co-doping Bi and Ag. Bi is an efficient n-type dopant in PbTe, often leading to excessive carrier concentration at room temperature. As revealed by density functional theory calculations, the formation of Bi and Ag defect complexes is exploited to optimize the room temperature carrier concentration. At elevated temperatures, we demonstrate the dynamic dissolution of Ag2Te precipitates in PbTe in situ by heating in a scanning transmission electron microscope. The release of n-type Ag interstitials with increasing temperature fulfills the requirement of higher carrier concentrations at the hot end. Moreover, as characterized by atom probe tomography, Ag atoms aggregate along parallel dislocation arrays to form Cottrell atmospheres. This results in enhanced phonon scattering and leads to a low lattice thermal conductivity. As a result of the synergy of dynamic doping and phonon scattering at decorated dislocations, an average zT of 1.0 is achieved in n-type Bi/Ag-codoped PbTe between 400 and 825 K. Introducing dopants with temperature-dependent solubility and strong interaction with dislocation cores enables simultaneous optimization of the average power factor and thermal conductivity, providing a new concept to exploit in the field of thermoelectrics.</description><identifier>EISSN: 2331-8422</identifier><identifier>DOI: 10.48550/arxiv.2203.10514</identifier><language>eng</language><publisher>Ithaca: Cornell University Library, arXiv.org</publisher><subject>Bismuth ; Carrier density ; Density functional theory ; Dopants ; Doping ; Energy conversion efficiency ; Heat conductivity ; Heat transfer ; High temperature ; Intermetallic compounds ; Interstitials ; Optimization ; Phonons ; Physics - Materials Science ; Power factor ; Precipitates ; Room temperature ; Scattering ; Strong interactions (field theory) ; Temperature ; Temperature dependence ; Thermal conductivity ; Thermoelectricity</subject><ispartof>arXiv.org, 2022-03</ispartof><rights>2022. 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As a result of the synergy of dynamic doping and phonon scattering at decorated dislocations, an average zT of 1.0 is achieved in n-type Bi/Ag-codoped PbTe between 400 and 825 K. 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To achieve this, we optimize the carrier concentrations of n-type PbTe from room up to hot-end temperatures by co-doping Bi and Ag. Bi is an efficient n-type dopant in PbTe, often leading to excessive carrier concentration at room temperature. As revealed by density functional theory calculations, the formation of Bi and Ag defect complexes is exploited to optimize the room temperature carrier concentration. At elevated temperatures, we demonstrate the dynamic dissolution of Ag2Te precipitates in PbTe in situ by heating in a scanning transmission electron microscope. The release of n-type Ag interstitials with increasing temperature fulfills the requirement of higher carrier concentrations at the hot end. Moreover, as characterized by atom probe tomography, Ag atoms aggregate along parallel dislocation arrays to form Cottrell atmospheres. This results in enhanced phonon scattering and leads to a low lattice thermal conductivity. 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subjects	Bismuth Carrier density Density functional theory Dopants Doping Energy conversion efficiency Heat conductivity Heat transfer High temperature Intermetallic compounds Interstitials Optimization Phonons Physics - Materials Science Power factor Precipitates Room temperature Scattering Strong interactions (field theory) Temperature Temperature dependence Thermal conductivity Thermoelectricity
title	Dynamic doping and Cottrell atmosphere optimize the thermoelectric performance of n-type PbTe
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