Title :
Thermoelectric properties of layer-structured (ZnO)mIn 2O3 (m=integer) improved by elemental substitution
Author :
Ohta, M. ; Kazeoka, M. ; Seo, W.S. ; Koumoto, K.
Author_Institution :
Dept. of Appl. Chem., Nagoya Univ., Japan
Abstract :
We have already proposed that homologous compounds of (ZnO)m In2O3 with layer structures can become candidate materials for high-temperature thermoelectric conversion due to their low thermal conductivity and fairly high electron mobility. Crystal structures can be modified by the substitution of either divalent or trivalent metal ions for Zn or In ions, respectively: Substitution of those smaller than Zn or larger than In in ionic size gave rise to the shrinkage of c-axis and the elongation of a-axis of a hexagonal unit cell. An optimum amount of substitution increased electron mobility and hence Z values coupled with lowered thermal conductivity which was possibly caused by suitable modification of the electronic structure associated with distortion of the crystal structure. For instance, substitution of 3% Y for In realized about one order of magnitude increase in Z up to ~1.3×10-1 K-1 at 1200 K. However, substitution of small trivalent ions all deteriorated the properties
Keywords :
electron mobility; indium compounds; semiconductor materials; thermal conductivity; thermoelectric power; zinc compounds; 1200 K; ZnO-In2O3; crystal structures; elemental substitution; elongation; fairly high electron mobility; high-temperature thermoelectric conversion; layer-structured (ZnO)mIn2O3; low thermal conductivity; shrinkage; thermoelectric properties; Conducting materials; Electron mobility; Oxidation; Powders; Semiconductor materials; Temperature; Thermal conductivity; Thermal resistance; Thermoelectricity; Zinc oxide;
Conference_Titel :
Thermoelectrics, 1998. Proceedings ICT 98. XVII International Conference on
Conference_Location :
Nagoya
Print_ISBN :
0-7803-4907-5
DOI :
10.1109/ICT.1998.740452
