n型（PbTe）0.75（PbS）0.15（PbSe）0.1复合材料的热电性能

Thermoelectric performance of n-type (PbTe)0.75(PbS)0.15(PbSe)0.1 composites.

作者信息

Yamini Sima Aminorroaya, Wang Heng, Ginting Dianta, Mitchell David R G, Dou Shi Xue, Snyder G Jeffrey

机构信息

Australian Institute for Innovative Materials, University of Wollongong, Innovation Campus , North Wollongong, New South Wales 2500, Australia.

出版信息

ACS Appl Mater Interfaces. 2014 Jul 23;6(14):11476-83. doi: 10.1021/am502140h. Epub 2014 Jul 3.

DOI:10.1021/am502140h

PMID:24960418

Abstract

Lead chalcogenides (PbQ, Q = Te, Se, S) have proved to possess high thermoelectric efficiency for both n-type and p-type compounds. Recent success in tuning of electronic band structure, including manipulating the band gap, multiple bands, or introducing resonant states, has led to a significant improvement in the thermoelectric performance of p-type lead chalcogenides compared to the n-type ones. Here, the n-type quaternary composites of (PbTe)0.75(PbS)0.15(PbSe)0.1 are studied to evaluate the effects of nanostructuring on lattice thermal conductivity, carrier mobility, and effective mass variation. The results are compared with the similar ternary systems of (PbTe)(1-x)(PbSe)x, (PbSe)(1-x)(PbS)x, and (PbS)(1-x)(PbTe)x. The reduction in the lattice thermal conductivity owing to phonon scattering at the defects and interfaces was found to be compensated by reduced carrier mobility. This results in a maximum figure of merit, zT, of ∼1.1 at 800 K similar to the performance of the single phase alloys of PbTe, PbSe, and (PbTe)(1-x)(PbSe)x.

摘要

硫族化铅（PbQ，Q = 碲、硒、硫）已被证明对于n型和p型化合物都具有较高的热电效率。最近在电子能带结构调控方面取得的成功，包括操纵带隙、多能带或引入共振态，使得p型硫族化铅的热电性能相较于n型有了显著提升。在此，对（PbTe）0.75（PbS）0.15（PbSe）0.1的n型四元复合材料进行研究，以评估纳米结构对晶格热导率、载流子迁移率和有效质量变化的影响。将结果与（PbTe）（1 - x）（PbSe）x、（PbSe）（1 - x）（PbS）x和（PbS）（1 - x）（PbTe）x等类似三元体系进行比较。发现由于缺陷和界面处的声子散射导致的晶格热导率降低被载流子迁移率的降低所补偿。这使得在800 K时的最大品质因数zT约为1.1，与PbTe、PbSe和（PbTe）（1 - x）（PbSe）x单相合金的性能相似。

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n型（PbTe）0.75（PbS）0.15（PbSe）0.1复合材料的热电性能

Thermoelectric performance of n-type (PbTe)0.75(PbS)0.15(PbSe)0.1 composites.

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