Publication Type : Journal Article
Publisher : Solar Energy
Source : Solar Energy, Vol. 177, pp. 679-689, January 2019
Url : https://www.sciencedirect.com/science/article/abs/pii/S0038092X1831171X
Campus : Chennai
School : School of Engineering
Department : Electronics and Communication
Year : 2019
Abstract : We used density functional theory based calculations to investigate the structural and optoelectronic properties of copper-based ternary chalcogenide Cu-M-X2 (M: Sb, Bi & X: S, Se). These form orthorhombic crystallographic structure with Pnma space group. The relative thermodynamic stability of these structures is supported by their phonon band dispersions. The calculated electronic band structure is indirect for all these compounds in conjunction with a close direct band gap transition. The calculated effective mass of electrons and holes are (0.074, 0.732), (0.053, 0.297), (0.039, 0.655) and (0.031, 0.514) for CuSbS2, CuSbSe2, CuBiS2 and CuBiSe2, respectively. Interestingly, a very high optical absorption coefficient above 105 cm−1 above band gap values is noticed for these materials, making them suitable for ultrathin solar cell absorbers.
Cite this Research Publication : G. K. Gupta, R. Chaurasiya, A. Dixit, Thermodynamic stability and optoelectronic properties of Cu(Sb/Bi)(S/Se)2 ternary chalcogenides: Promising ultrathin photoabsorber semiconductors, Solar Energy, Vol. 177, pp. 679-689, January 2019