Abstract
This paper reports on efforts to enhance the photovoltaic performance of textured silicon solar cells through the application of a layer of Eu-doped silicate phosphor with particles of various dimensions using the spin-on film technique. We examined the surface profile and dimensions of the Eu-doped phosphors in the silicate layer using optical microscopy with J-image software. Optical reflectance, photoluminescence, and external quantum efficiency were used to characterize the luminescent downshifting (LDS) and light scattering of the Eu-doped silicate phosphor layer. Current density-voltage curves under AM 1.5G simulation were used to confirm the contribution of LDS and light scattering produced by phosphor particles of various dimensions. Experiment results reveal that smaller phosphor particles have a more pronounced effect on LDS and a slight shading of incident light. The application of small Eu-doped phosphor particles increased the conversion efficiency by 9.2% (from 12.56% to 13.86%), far exceeding the 5.6% improvement (from 12.54% to 13.32%) achieved by applying a 250 nm layer of SiO2 and the 4.5% improvement (from 12.37% to 12.98%) observed in cells with large Eu-doped phosphor particles.
Highlights
The conversion efficiency of solar cells is limited by optical absorption, carrier transport, and carrier collection
This paper reports on the fabrication and characterization of textured C-Si solar cells coated with
This paper reports on the fabrication and characterization of textured C-Si solar cells coated a layer of luminescent downshifting (LDS) Eu-doped silicate phosphor particles of various dimensions
Summary
The conversion efficiency of solar cells is limited by optical absorption, carrier transport, and carrier collection. The maximum theoretical efficiency of a single-junction crystalline-silicon (C-Si) solar cell is 31% under AM 1.5G illumination [1]. This limitation can be attributed to losses associated with the excess energy of above-bandgap photons, photon transparency below the band gap, and radiative and Auger recombination. Nanomaterials are currently being employed in photovoltaics to reduce the fundamental spectral losses in single-junction silicon solar cells, which can reach 50% [3]. Many researchers have sought to enhance the overall conversion efficiency by applying a down-conversion (DC) layer or a down-shifting (DS) layer over the top surface of the C-Si in order to improve its spectral response in the UV-blue region [16–18]. EQE response and photovoltaic current density-voltage (J-V) characteristics under AM 1.5G simulation measurements were used to quantify improvements in photovoltaic performance as a function of LDS and particle dimensions
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