Antimony sulfide-selenide thin film solar cells produced from stibnite mineral

• Published in: Thin solid films Vol. 645; pp. 305 - 311
• Main Authors: Nair, P.K., Vázquez García, Geovanni, Zamudio Medina, Eira Anais, Guerrero Martínez, Laura, Leyva Castrejón, Oscar, Moctezuma Ortiz, Jacqueline, Nair, M.T.S.
• Format: Journal Article
• Language: English
• Published: Elsevier B.V 01.01.2018
• Subjects: Antimony chalcogenide; Antimony chalcogenide solar cells; Antimony sulfide selenide; Renewable energy; Sb-S-Se; Sb2SxSe3 − x; Semiconductor thin films; Solar energy; Thin film solar cells; Antimony chalcogenide; Antimony chalcogenide solar cells; Sb2SxSe3−x; Semiconductor thin films; Renewable energy; Antimony sulfide selenide; Solar energy; Sb-S-Se; Thin film solar cells
• ISSN: 0040-6090; 1879-2731
• DOI: 10.1016/j.tsf.2017.11.004

Stibnite (Sb2S3) is a major mineral of antimony, which occurs as large crystals often with minor encrustations of other minerals. Locally sourced powdered stibnite containing some quartzite (SiO2) and ferrosilite (FeSiO3) has been used in this work as evaporation source for vacuum deposition of thin film solar cells. The added minerals were left as residue in the crucible and did not incorporate into the Sb2S3 thin film. To stibnite powder was added Sb2Se3 powder prepared in our laboratory as chemical precipitate. Source mixtures of different weight – by – weight (w/w) ratios gave thin films of chemical composition Sb2SxSe3−x and optical band gap (Eg) within 1.38eV (Sb2Se3) – 1.88eV (Sb2S3). Solar cells of SnO2:F/CdS (100nm)/Sb2S3(250nm)/C-Ag prepared by using stibnite as evaporation source gave under standard conditions, open circuit voltage (Voc), 0.668V; short circuit current density (Jsc), 6.95mA/cm2; and conversion efficiency (η), 1.62%. For a 2:1 (w/w) mixture of stibnite:Sb2Se3, solar cell of Sb2S2.14Se0.86 (Eg 1.61eV) was obtained with Voc, 0.562V; Jsc, 13.53mA/cm2 and η, 4.03%. For 1:5 (w/w) mixture, solar cell of Sb2S0.5Se2.5 (Eg 1.44eV) gave Voc, 0.443V; Jsc, 22.31mA/cm2 and η, 4.24%. Electrical conductivity of the Sb2SxSe3−x absorber films in the dark increased from 10−8 to 10−6Ω−1cm−1 and their photoconductivity, from 10−6 to 10−5Ω−1cm−1 as the composition changed from Sb2S3 to Sb2SxSe3−x and Sb2Se3. Direct use of an abundant mineral as the evaporation source in thin film solar cell technology is a novelty. •Direct use of stibnite ore-mineral of Sb2S3 to produce solar cells of 1.6% efficiency•Stibnite mineral and Sb2Se3 precipitate source-mix used for solar cells of 4.2% efficiency•Variable electrical conductivity and Eg 1.38–1.61eV in Sb2SxSe3−x from stibnite – Sb2Se3