Performance enhancement of planar silicon solar cells through utilization of two luminescent down-shifting Eu-doped phosphor species

Abstract

In this study, the substantial performance enhancement of crystalline silicon (C-Si) solar cells through the combined utilization of two luminescent down-shifting europium (Eu)-doped phosphor species in the silicate (SiO2) layer was experimentally demonstrated. The combination of emission wavelengths of 512nm and 550nm, of 512nm and 610nm, and of 550nm and 610nm from the two Eu-doped phosphor species, respectively, was proposed to achieve a broad band luminescent emission as well as a higher conversion efficiency. The surface morphologies and optical properties of the 3-wt.% Eu-doped phosphor species mixed with SiO2 solution coated on C-Si solar cells via a spin-on film technique were characterized by scanning electron microscopy, photoluminescence, optical reflectance, external quantum efficiency, and photovoltaic current density–voltage measurements under one sun AM 1.5G illumination. The short-circuit current density enhancement (ΔJsc) of the Si solar cells with Eu-doped phosphor particles on a SiO2 layer was 4–9% higher than that of cells with only a SiO2 layer. A ΔJsc of 19.85% and a conversion efficiency enhancement of 15.97% for the cells with the combination of two Eu-doped phosphor species with emission wavelengths of 512nm and 610nm were obtained due to broad band luminescent emission and forward light scattering.