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Paper detail

Lithography free method to synthesize the ultra-low reflection inverted-pyramid arrays for ultra-thin silicon solar cell

Silicon inverted pyramids arrays have been suggested as one of the most promising structure for high-efficient ultrathin solar cells due to their ability of superior light absorption and low enhancement of surface area. However, the existing techniques for such fabrication are either expensive or not able to create appropriate structure. Here, we present a lithography free method for the fabrication of inverted pyramid arrays by using a modified metal assisted chemical etching (MACE) method. The size and inter-inverted pyramids spacing can also be controlled through this method. We used an isotropic chemical etching technique for this process to control the angle of etching, which leads to ultra-low reflection, even < 0.5%, of this nanostructure. Using this specification, we have predicted the expected solar cell parameters, which exceeds the Lambertian limit. This report provides a new pathway to improve the efficiency of the ultrathin silicon solar cells at lower cost.

preprint2022arXivOpen access
Anil KumarDivya RaniAnjali SainNeeraj JoshiRavi Kumar VarmaMrinal DuttaArup Samanta
cond-mat.mes-hallcond-mat.mtrl-sciphysics.optics
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Anil KumarDivya RaniAnjali SainNeeraj JoshiRavi Kumar VarmaMrinal DuttaArup Samanta

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