One key action to mitigate the adverse impacts of climate change is transitioning to sustainable energy production, notably through photovoltaic (PV) power generation. PV technologies based on crystalline silicon (c-Si) currently represent ∼95% of the global market and will thus be the main driving force toward the expected growth of worldwide PV installations to the multi-terawatt scale. Lately, further increase of the conversion efficiency of industrial mainstream c-Si solar cells has relied on the integration of passivating contacts based on a highly-doped polycrystalline silicon (poly-Si) layer on top of a thin silicon oxide (SiOx) buffer layer (so-called “poly-Si contacts”).
The overall objective of SLICE was to elucidate the interrelation between the functional properties of poly-Si contacts (especially surface passivation) and their fabrication process in order to guide the developments of better surface passivation and ultimately c-Si solar cells with higher efficiency. Throughout the project, we developed novel methodologies that enabled the identification of the first order limitation to reaching poly-Si contacts featuring both high surface passivation and good electrical properties. Based on this key finding, we optimized the fabrication process to eventually demonstrate poly-Si contacts providing higher and better thermally stable surface passivation.