Investigation of thermoelectric material based on Lu1-xZrxNiSb solid solution. II. Modeling of characteristics

• Published in: Fìzika ì hìmìâ tverdogo tìla (Online) Vol. 23; no. 3; pp. 497 - 504
• Main Authors: Romaka, V.A., Stadnyk, Yu, Romaka, L., Romaka, V.V., Demchenko, P., Pashkevich, V., Horyn, А.
• Format: Journal Article
• Language: English
• Published: Vasyl Stefanyk Precarpathian National University 10.09.2022
• Subjects: electrical conductivity; fermi level; semiconductor; thermopower coefficient
• ISSN: 1729-4428; 2309-8589
• DOI: 10.15330/pcss.23.3.497-504

The KKR (AkaiKKR software package) and FLAPW (Elk software package) methods were used to model the structural, thermodynamic, energetic, and electrokinetic characteristics of the Lu1-xZrxNiSb semiconductor solid solution. It is shown that defects of acceptor nature are present in the structure of LuNiSb as a result of vacancies in positions 4a and 4c of Lu and Ni atoms, respectively, which generates two acceptor levels eAVac 4a and eAVac 4c in the band gap εg. When Zr atoms are introduced into the LuNiSb structure by replacing Lu atoms in position 4a, Zr atoms also occupy vacancies in this position, which increases the lattice parameter a(x) and eliminates defects of acceptor nature and corresponding acceptor levels eAVac 4a. When the vacancies are filled, Lu atoms are displaced, which reduces the value of the unit cell parameter and generates defects of donor nature and donor levels eD4a. The Ni atoms return to position 4c, which increases the a(x) value and eliminates defects of acceptor nature and the corresponding acceptor levels eAVac 4c. At the lowest concentration of Zr atoms, the conduction type of Lu1-xZrxNiSb changes from p- to n-type. The simulation results are consistent with experimental studies of Lu1-xZrxNiSb.