Title :
Radiation hard InGaP for high efficiency multi-junction solar cells
Author :
Khan, Aurangzeb ; Yamaguchi, Masafumi ; Bourgoin, Jacques C. ; Takamoto, Tatsuya
Author_Institution :
Toyota Technol. Inst., Nagoya, Japan
Abstract :
The present study demonstrates isothermal and injection annealing recovery of photovoltaic parameters in InGaP solar cells after 1 MeV electron irradiation and correlation with changes in the Deep Level Transient Spectroscopy (DLTS) spectra observed in p-InGaP. In particular, the dominant hole level H2 (0.50-0.55 eV) is found to be significantly decay as a result of 40 days room temperature storage. In addition, a minority-carrier injection-enhanced annealing of the trap H2 has also been observed. Furthermore, an evidence of large minority carrier capture cross section for the hole trap H2 has been obtained by double-carrier pulse DLTS which demonstrates that the role of this trap acts as an apparent recombination center
Keywords :
III-V semiconductors; annealing; deep level transient spectroscopy; electron beam effects; gallium compounds; hole traps; indium compounds; minority carriers; radiation hardening (electronics); solar cells; 1 MeV; 20 C; 40 d; DLTS spectra; InGaP; InGaP solar cells; deep level transient spectroscopy; double-carrier pulse DLTS; electron irradiation; high efficiency multi-junction solar cells; hole level H2; injection annealing recovery; isothermal recovery; large minority carrier capture cross section; minority-carrier injection-enhanced annealing; p-InGaP; photovoltaic parameters; radiation hard InGaP; recombination center; room temperature storage; Annealing; Capacitance measurement; Current measurement; Electron accelerators; Gallium arsenide; Hydrogen; Isothermal processes; Photovoltaic cells; Space technology; Temperature;
Conference_Titel :
Compound Semiconductors, 2000 IEEE International Symposium on
Conference_Location :
Monterey, CA
Print_ISBN :
0-7803-6258-6
DOI :
10.1109/ISCS.2000.947133
