Tailoring Luminescent Solar Concentrators for High‐Performance Flexible Double‐Junction III‐V Photovoltaics

Despite the remarkable advantages of luminescent solar concentrators (LSCs), their application has not been of interest in ultrahigh efficient photovoltaic modules such as multi‐junctions and related two‐terminal tandems due to challenging issues limiting the cell capability and impeding the output current. Here type of multi‐junction LSC photovoltaics is presented that consists of transfer‐printed arrays of InGaP/GaAs solar cells and strategically tailored luminescent waveguides. A coplanar waveguide with the non‐self‐aligned quantum dot luminophores enables simultaneous absorptions of the directly illuminated solar flux and the indirectly waveguided LSC flux, where cell deployment and luminophore spectrum are systematically tuned for balanced enhancement of the subcell photocurrents. Through systematic comparisons across various LSC configurations supported by both experimental and theoretical quantifications, the power conversion efficiency of flexible modules with InGaP/GaAs cell arrays is improved from 1.67% to 2.22% by the optimal LSC, where the module area is 14.4 times larger than the total cell area. The details of optical and mechanical studies provide a further comprehensive understanding of the suggested approach toward multi‐junction LSC photovoltaics. Strategically designed luminescent solar concentrators (LSCs) are presented to boost the module power generation of flexible double‐junction III‐V solar cells. The optimal LSC and cell deployments are identified by systematically examining various LSC device configurations based on experimental and theoretical quantifications; thus, up to 50% improvement in the output power is achieved.