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Description:

We have investigated the incorporation of sulfur into CuIn(Se,S)₂ thin films from different bonding environments in hydrazine-based precursor solutions. Sulfur is present in the form of (N₂H₅)₂S, [Cu₆S₄]^2-, and [In₂(Se,S)₄]^2- complexes in mixed CuIn(Se,S)₂ precursor solutions. On the basis of compositional information from the precursor solutions and annealed films, we find that the incorporation efficiency of sulfur from (N₂H₅)₂S into the final film is extremely low as a result of the high volatility of this compound and its weak interaction with other species while in solution. Using the same methodology, we additionally report that approximately 80% of the sulfur from [In₂(Se,S)₄]^2- is incorporated into the final material, compared to approximately 40% of the sulfur from [Cu₆S₄]^2- complexes. This difference in sulfur incorporation efficiency may be due to the relatively weak Cu-S bonds present in the [Cu₆S₄]^2- structure, which are somewhat unstable compared to the In-S bonds in the [In₂(Se,S)₄]^2- complex. This method makes it possible to precisely control the sulfur content in CuIn(Se,S)₂ films by adjusting the S/Se ratio of the [In₂(Se,S)₄]^2- ions in the final precursor solution. These results will enable the precise adjustment and optimization of the energy band gap in solution-processed CuIn(Se,S)₂ absorber layers for the future fabrication of improved photovoltaic devices.