Impact of Well Number on High-Efficiency Strain-Balanced Quantum-Well Solar Cells

Abstract: The addition of lower energy-gap InGaAs quantum wells to the depletion region of GaAs solar cells is an established approach to enhance photovoltaic performance by extending infrared collection. However, maintaining a high open-circuit voltage (V oc ) when including quantum wells has proven more challenging. In this article, we report on high-efficiency (η > 23.5% AM0) strainbalanced quantum well (SBQW) solar cells with increased current output and efficiency while maintaining the same high open-circuit voltag… Show more

“…The purpose of this design is to extend the absorption spectrum of GaAs cells and optimize the current matching of TJ cells. [5][6][7][8][9][10][11][12] Therefore, compared with the IMM 6-junction cell that requires multiple compositionally graded buffer layers 1) and wafer-bonded MJSC that requires a complex bonding process, 2) the high-efficiency SBQW TJ cell is more suitable for mass production. The research findings of France et al also confirm this point.…”

Improvement of radiation resistance of GaInP/GaInAs/Ge triple-junction solar cell with GaInAs/GaAsP quantum wells

“…The purpose of this design is to extend the absorption spectrum of GaAs cells and optimize the current matching of TJ cells. [5][6][7][8][9][10][11][12] Therefore, compared with the IMM 6-junction cell that requires multiple compositionally graded buffer layers 1) and wafer-bonded MJSC that requires a complex bonding process, 2) the high-efficiency SBQW TJ cell is more suitable for mass production. The research findings of France et al also confirm this point.…”

Improvement of radiation resistance of GaInP/GaInAs/Ge triple-junction solar cell with GaInAs/GaAsP quantum wells

Demonstration of Dual-Junction ELO Solar Cells with Strain-Balanced and Lattice-Matched Quantum Well Absorbers

AM0 Optimized Dual Junction Quantum Well Solar Cells-Investigation of Radiation Tolerance Designs and V_oc Retention at EOL