Abstract

Graphene/Si Schottky junction is highly attractive for its application in solar cells due to the excellence of graphene as a transparent conducting electrode. However, the high sheet resistance of the chemical vapor deposition-grown graphene films, mostly used for the solar cells, is still one of the principal factors limiting the power conversion efficiency of graphene/Si solar cells. Here, we report an approach of co-doping with gold (III) chloride (AuCl3) and silver nanowires (Ag NWs) to reduce the sheet resistance (Rs) of graphene as well as to control its work function (WG) for well-matched graphene/Si wafer junction. The molar concentration (nD) of AuCl3 is varied from 1 to 10 mM while the fraction (nA) of Ag NWs is fixed at 0.1 wt% for the fabrication of the solar cells, based on nA-dependent behaviors of Rs and WG. The co-doped graphene/n-Si Schottky solar cells show a maximum power-conversion efficiency of 7.01% at nD = 7.5 mM, resulting from the increased barrier height at the graphene/Si junction and the reduced sheet resistance/transmittance of graphene by the co-doping, as proved from the nD-dependent behaviors of open-circuit voltage, DC conductivity/optical conductivity ratio, series resistance, and external quantum efficiency.

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