Title :
Wide-Bandgap InAs/InGaP Quantum-Dot Intermediate Band Solar Cells
Author :
Ramiro, Inigo ; Villa, Juan ; Phu Lam ; Hatch, Sabina ; Jiang Wu ; Lopez, Esther ; Antolin, Elisa ; Huiyun Liu ; Marti, Antonio ; Luque, Antonio
Author_Institution :
Inst. de Energia Solar, Univ. Politec. de Madrid, Madrid, Spain
Abstract :
Current prototypes of quantum-dot intermediate band solar cells suffer from voltage reduction due to the existence of thermal carrier escape. An enlarged subbandgap EL would not only minimize this problem but would lead to a bandgap distribution that exploits more efficiently the solar spectrum. In this study, we demonstrate InAs/InGaP QD-IBSC prototypes with the following bandgap distribution: EG = 1.88 eV, EH = 1.26 eV, and EL > 0.4 eV. We have measured, for the first time in this material, both the interband and intraband transitions by means of photocurrent experiments. The activation energy of the carrier thermal escape in our devices has also been measured. It is found that its value, compared with InAs/GaAs-based prototypes, does not follow the increase in EL. The benefits of using thin-AlGaAs barriers before and after the quantum-dot layers are analyzed.
Keywords :
III-V semiconductors; aluminium compounds; energy gap; gallium arsenide; indium compounds; photoconductivity; photoemission; semiconductor quantum dots; solar cells; wide band gap semiconductors; InAs-InGaP-AlGaAs; activation energy; band gap distribution; carrier thermal escape; enlarged subbandgap; indium arsenide-indium gallium phosphide quantum dot intermediate band solar cells; interband transitions; intraband transitions; photocurrent; quantum dot layers; voltage reduction; wide band gap; Energy measurement; Gallium arsenide; Photoconductivity; Photonic band gap; Photovoltaic cells; Quantum dots; Temperature measurement; Intermediate band (IB); intraband absorption; quantum dots; solar cell characterization;
Journal_Title :
Photovoltaics, IEEE Journal of
DOI :
10.1109/JPHOTOV.2015.2402439
