Carrier density and compensation in semiconductors with multiple dopants and multiple transition energy levels: Case of Cu impurities in CdTe
Document Type
Article
Publication Date
6-27-2011
Abstract
Doping is one of the most important issues in semiconductor physics. In many cases, when people describe carrier concentration as a function of dopant density and Fermi energy, they usually assume only one type of dopant with single transition energy level in the system. However, in reality, the situation is often more complicated, that is, in a semiconductor device, it usually contains multidopants and each can have multitransition energy levels. In this paper, using detailed balance theory and first-principles calculated defect formation energies and transition energy levels, we derive formulas to calculate carrier density for semiconductor with multidopants and multitransition energy levels. As an example, we studied CdTe doped with Cu, in which VCd, CuCd, and Cui are the dominant defects/impurities. We show that in this system, when Cu concentration increases, the doping properties of the system can change from a poor p-type, to a poorer p-type, to a better p-type, and then to poor p-type again, in good agreement with experimental observations. © 2011 American Physical Society.
Identifier
79961234511 (Scopus)
Publication Title
Physical Review B Condensed Matter and Materials Physics
External Full Text Location
https://doi.org/10.1103/PhysRevB.83.245207
e-ISSN
1550235X
ISSN
10980121
Issue
24
Volume
83
Recommended Citation
Ma, Jie; Wei, Su Huai; Gessert, T. A.; and Chin, Ken K., "Carrier density and compensation in semiconductors with multiple dopants and multiple transition energy levels: Case of Cu impurities in CdTe" (2011). Faculty Publications. 11294.
https://digitalcommons.njit.edu/fac_pubs/11294
