International Journal of Renewable Energy Research-IJRER

In this paper, the efficiency of a novel GaInP₂/GaAs/GaAs_0.94Bi_0.0583/Ge concentrator multijunction solar cell has been investigated by simulation using indigenously written code for MATLAB software. The materials in this unique cell structure are judiciously selected to ensure the maximum absorption of photons from ultraviolet to deep infrared wavelengths of the solar spectrum. A theoretical model has been developed to channel the same current in all four junctions and to ensure the highest conversion of the sunlight into electricity.  The theoretical efficiencies of this quadruple junction solar cell have been simulated to be 49.6% and 60.2% for AM1.5G solar radiation under 1 sun and 500 sun concentration respectively. Finally, these simulated efficiencies have been compared with the theoretical and experimental efficiencies of the reported champion solar cells.

III-V bismide, multijunction solar cell, concentrator cell, efficiency and simulation

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