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锶-钼取代的钙锰矿的晶体结构和热电性能:实验与计算相结合的研究

Crystal structure and thermoelectric properties of Sr-Mo substituted CaMnO: a combined experimental and computational study.

作者信息

Srivastava D, Azough F, Freer R, Combe E, Funahashi R, Kepaptsoglou D M, Ramasse Q M, Molinari M, Yeandel S R, Baran J D, Parker S C

机构信息

School of Materials , University of Manchester , Manchester , M13 9PL , UK . Email:

National Institute of Advanced Industrial Science and Technology , Midorigaoka , Ikeda , Osaka 563-8577 , Japan.

出版信息

J Mater Chem C Mater. 2015 Dec 21;3(47):12245-12259. doi: 10.1039/c5tc02318a. Epub 2015 Nov 13.

DOI:10.1039/c5tc02318a
PMID:28496979
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC5361175/
Abstract

A combination of experimental and computational techniques has been employed to study doping effects in perovskite CaMnO. High quality Sr-Mo co-substituted CaMnO ceramics were prepared by the conventional mixed oxide route. Crystallographic data from X-ray and electron diffraction showed an orthorhombic to tetragonal symmetry change on increasing the Sr content, suggesting that Sr widens the transition temperature in CaMnO preventing phase transformation-cracking on cooling after sintering, enabling the fabrication of high density ceramics. Atomically resolved imaging and analysis showed a random distribution of Sr in the A-site of the perovskite structure and revealed a boundary structure of 90° rotational twin boundaries across {101}; the latter are predominant phonon scattering sources to lower the thermal conductivity as suggested by molecular dynamics calculations. The effect of doping on the thermoelectric properties was evaluated. Increasing Sr substitution reduces the Seebeck coefficient but the power factor remains high due to improved densification by Sr substitution. Mo doping generates additional charge carriers due to the presence of Mn in the Mn matrix, reducing electrical resistivity. The major impact of Sr on thermoelectric behaviour is the reduction of the thermal conductivity as shown experimentally and by modelling. Strontium containing ceramics showed thermoelectric figure of merit () values higher than 0.1 at temperatures above 850 K. CaSrMnMoO ceramics exhibit enhanced properties with = -180 μV K, = 5 × 10 Ωm, = 1.8 W m K and ≈ 0.11 at 1000 K.

摘要

采用实验和计算相结合的技术来研究钙钛矿CaMnO中的掺杂效应。通过传统的混合氧化物路线制备了高质量的Sr-Mo共取代CaMnO陶瓷。X射线和电子衍射的晶体学数据表明,随着Sr含量的增加,晶体结构从正交对称转变为四方对称,这表明Sr拓宽了CaMnO的转变温度,防止烧结后冷却时发生相变开裂,从而能够制备高密度陶瓷。原子分辨成像和分析表明,Sr在钙钛矿结构的A位随机分布,并揭示了跨越{101}的90°旋转孪晶界的边界结构;分子动力学计算表明,后者是降低热导率的主要声子散射源。评估了掺杂对热电性能的影响。增加Sr取代会降低塞贝克系数,但由于Sr取代改善了致密化,功率因子仍然很高。由于Mn基体中存在Mn,Mo掺杂产生了额外的载流子,降低了电阻率。实验和模型均表明Sr对热电行为的主要影响是降低热导率。含锶陶瓷在850 K以上的温度下表现出高于0.1的热电优值()。CaSrMnMoO陶瓷在1000 K时表现出增强的性能,= -180 μV K,= 5×10 Ωm,= 1.8 W m K,≈ 0.11。

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