Abstract
The addition of aluminum to silver metallization pastes has been found to lower the contact resistivity of a silver metallization on boron-doped silicon emitters for n-type Si solar cells. However, the addition of Al also induces more surface recombination and increases the Ag pattern′s line resistivity, both of which ultimately limit the cell efficiency. There is a need to develop a fundamental understanding of the role that Al plays in reducing the contact resistivity and to explore alternative additives. A fritless silver paste is used to allow direct analysis of the impact of Al on the Ag-Si interfacial microstructure and isolate the influence of Al on the electrical contact from the complicated Ag-Si interfacial glass layer. Electrical analysis shows that in a simplified system, Al decreases the contact resistivity by about three orders of magnitude. Detailed microstructural studies show that in the presence of Al, microscale metallic spikes of Al-Ag alloy and nanoscale metallic spikes of Ag-Si alloy penetrate the surface of the boron-doped Si emitters. These results demonstrate the role of Al in reducing the contact resistivity through the formation of micro- and nano-scale metallic spikes, allowing the direct contact to the emitters.
Highlights
Photovoltaic (PV) cells based on n-type Si are expected to capture increased market share in the future based on a recent International Technology Roadmap for Photovoltaic (ITRPV).[1]
Due to the differences in the boron-doping profiles of the polished wafers and the textured PV wafers, the contact resistivity data cannot be directly compared. Overall, these results show that even in the fritless paste system the addition of Al decreases the contact resistivity, demonstrating that there is a mechanism by which Al can improve the contact independent of any interaction with the frit
Both boron-doped polished Si wafers and n-type textured Si PV wafers have confirmed that Al improves the contact resistivity significantly and for PV wafers it leads to a significant improvement on the cell performance due to the significant improvement in series resistance, fill factor and short-circuit current density
Summary
Photovoltaic (PV) cells based on n-type Si are expected to capture increased market share in the future based on a recent International Technology Roadmap for Photovoltaic (ITRPV).[1]. Published Online: 19 January 2017 Wei Wu, Katherine E.
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