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Article Abstract
Thinning CIGSe absorber layer to less than 500 nm is desirable for reducing the cost per unit watt of photovoltaic-generated electricity, and also, the semitransparent solar cell based on such a thin absorber can be used in bifacial and superstrate configurations if the back electrode is transparent. In this study, a WO layer is inserted between Cu(In,Ga)Se (CIGSe) absorber and tin-doped indium oxide back-contact to enhance the hole collection at the back electrode. A WO interlayer with a thickness of 6 nm is found to be optimum because it causes a ∼38% relative increase in the fill factor of a ∼450 nm thick CIGSe-based device compared to the reference device without a WO interlayer. While fixing the thickness of CIGSe, increasing the WO interlayer thickness to ≥6 nm results in decreases of solar cell parameters primarily because of the emergence of a GaO interfacial layer at the CIGSe/WO junction.
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