Residual conductivity and Seebeck coefficient calculations in TiCo1-xCuxSb alloys

2006 25th International Conference on Thermoelectrics Pub Date : 2006-08-01 DOI:10.1109/ICT.2006.331298

T. Stopa, J. Toboła, S. Kaprzyk

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引用次数: 1

Abstract

We report results of conductivity and Seebeck coefficient calculations for TiCo1-xCuxSb alloys, as well as their comparison with experimental data. TiCoSb crystallizes in a half-Heusler crystal structure. As revealed from experimental measurements by Horyn et al., this type of structure does not change with Cu doping until x = 0.5. Moreover, lattice constant changes also very slightly and not-monotonically for 0 < x < 0.5, varying less then 0.001 nm. Therefore, we decided to use fixed lattice constant a = 0.58819 nm for all Cu concentrations. In TiCo1-xCuxSb a semiconductor-metal phase transition is observed upon even very small Cu doping. This is connected with the fact, that Fermi level in TiCoSb is located at the top of valence band. When the number of electrons in the system grows, Fermi energy crosses energy gap (which is about 1 eV) and enters conduction band. Also Seebeck coefficient increases rapidly with x from about -350 muV/K in TiCoSb to almost zero for x = 0.5, but it doesn't change the sign. All calculations were performed within Korringa-Kohn-Rostoker (KKR) method [Bansil et al., 1990 and 1999] with coherent potential approximation (CPA) [Soven, 1967] and [Kaprzyk and Bansil, 1990]

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TiCo1-xCuxSb合金的残余电导率和塞贝克系数计算

本文报道了TiCo1-xCuxSb合金的电导率和塞贝克系数的计算结果，并与实验数据进行了比较。TiCoSb结晶为半赫斯勒晶体结构。Horyn等人的实验测量表明，在x = 0.5之前，铜掺杂不会改变这种结构。此外，在0 < x < 0.5时，晶格常数的变化也非常微小且非单调，变化小于0.001 nm。因此，我们决定对所有Cu浓度使用固定的晶格常数a = 0.58819 nm。在TiCo1-xCuxSb中，即使非常小的Cu掺杂也能观察到半导体-金属相变。这与TiCoSb中的费米能级位于价带顶端有关。当系统中电子数增加时，费米能穿过能隙(约1 eV)进入导带。塞贝克系数也随着x的增加而迅速增加，从TiCoSb中的-350 muV/K到x = 0.5时几乎为零，但它没有改变符号。所有计算均采用Korringa-Kohn-Rostoker (KKR)方法[Bansil等人，1990和1999]和相干势近似(CPA) [Soven, 1967]和[Kaprzyk和Bansil, 1990]进行。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2006 25th International Conference on Thermoelectrics

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