Your search keyword '"Ying, Pengzhan"' showing total 3 results

1. Thermoelectric properties in nanostructured homologous series alloys GamSbnTe1.5(m+n).

Author

Cui, Jiaolin, Liu, Xianglian, Yang, Wei, Chen, Dongyong, Fu, Hong, and Ying, Pengzhan

Subjects

THERMOELECTRICITY, NANOSTRUCTURED materials, SOLID solutions, THERMAL conductivity, GALLIUM, ANTIMONY, TELLURIUM

Abstract

In this paper we reported the thermoelectric (TE) properties in nanostructured homologous series alloys GamSbnTe1.5(m+n) over the temperature range of 318–482 K and observed the maximum TE figure of merit (ZT) value of 0.98 for the alloy with m:n=1:10 at 482 K, which is approximately 0.24 higher than that of undoped Sb2Te3 at the corresponding temperature. This improvement is mainly attributed to the substantial reduction in lattice thermal conductivity due to the phonon scattering caused partly by the nanograins (<30 nm) and amorphous structure conceived in the matrix and partly by the lattice distortion resulted from an occupation of some Ga atoms in the Sb sites and a certain amount of Ga2Te3 precipitation. If in comparison with the TE properties for Ga directly doped Bi–Sb–Te solid solutions, we conclude that these Bi-free nanostructured homologous series alloys GamSbnTe1.5(m+n) with proper compositions are of great potentiality for the improvement of TE performance. [ABSTRACT FROM AUTHOR]

Published

2009

2. Thermoelectric Properties of an Al-Doped In-Sn-Te-Based Alloy.

Author

Fu, Hong, Ying, Pengzhan, Cui, Jiaolin, Yan, Yanming, and Zhang, Xiaojun

Subjects

INDIUM alloys, SEMICONDUCTOR doping, ALUMINUM, THERMAL conductivity of metals, ELECTRIC properties of metals, SINTERING, THERMOELECTRICITY

Abstract

In-Sn-Te-based alloys usually have low electrical and thermal conductivity. In the present work we substituted Al for In in an In-Sn-Te alloy and prepared an (InAlTe)(SnTe) alloy by spark plasma sintering. Substitution of Al for In favors the formation of indium impurity levels in this structure and accounts for the decrease of the band gap ( E) and much of the increase of mobility and electrical conductivity. The thermal conductivity decreases from 1.72 W K m to 1.44 W K m with temperature, while that of the (InTe)(SnTe) alloy increases from 2.29 W K m to 3.50 W K m. The thermoelectric figure of merit ( ZT) of the sample increases with measurement temperature, and the highest ZT value of 0.28 was obtained at 668 K, being a factor of 4.5 greater than the maximum ZT value for the Al-free (InTe)(SnTe) alloy at 510 K. [ABSTRACT FROM AUTHOR]

Published

2011

3. Thermoelectric properties in nanostructured homologous series alloys GamSbnTe1.5(m+n).

Author

Cui, Jiaolin, Liu, Xianglian, Yang, Wei, Chen, Dongyong, Fu, Hong, and Ying, Pengzhan

Subjects

*THERMOELECTRICITY, *NANOSTRUCTURED materials, *SOLID solutions, *THERMAL conductivity, *GALLIUM, *ANTIMONY, *TELLURIUM

Abstract

In this paper we reported the thermoelectric (TE) properties in nanostructured homologous series alloys GamSbnTe1.5(m+n) over the temperature range of 318–482 K and observed the maximum TE figure of merit (ZT) value of 0.98 for the alloy with m:n=1:10 at 482 K, which is approximately 0.24 higher than that of undoped Sb2Te3 at the corresponding temperature. This improvement is mainly attributed to the substantial reduction in lattice thermal conductivity due to the phonon scattering caused partly by the nanograins (<30 nm) and amorphous structure conceived in the matrix and partly by the lattice distortion resulted from an occupation of some Ga atoms in the Sb sites and a certain amount of Ga2Te3 precipitation. If in comparison with the TE properties for Ga directly doped Bi–Sb–Te solid solutions, we conclude that these Bi-free nanostructured homologous series alloys GamSbnTe1.5(m+n) with proper compositions are of great potentiality for the improvement of TE performance. [ABSTRACT FROM AUTHOR]

Published

2009