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Efficient solar energy conversion with CuInS2

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Abstract

The high absorptivity associated with a direct energy gap in the optimum range for solar-energy conversion makes CuInS2 a particularly promising material for efficient solar-energy conversion1. Achieved solar-to-electrical conversion efficiencies have been limited to ∼6% (refs 2–8). We report here a new heterogeneous poly crystalline n-CuInS2 based semiconductor which has yielded conversion efficiencies of 9.7% in an electrochemical cell. The high photoactivity is also evident in a Schottky barrier solar cell configuration. The origin of the improved efficiency is attributed to impurity scavenging by In spheres resulting from a modified vapour/liquid/solid (VLS) growth process9–11 and the influence of the acidic iodine iodide electrolyte on the cell performances.

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Authors and Affiliations

  1. Hahn-Meitner-Institut für Kernforschung Berlin, Bereich Strahlenchemie, 1000 Berlin 39, FRG

    H. J. Lewerenz, H. Goslowsky, K.-D. Husemann & S. Fiechter

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  1. H. J. Lewerenz
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  2. H. Goslowsky
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  3. K.-D. Husemann
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  4. S. Fiechter
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Lewerenz, H., Goslowsky, H., Husemann, KD. et al. Efficient solar energy conversion with CuInS2. Nature 321, 687–688 (1986). https://doi.org/10.1038/321687a0

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  • DOI: https://doi.org/10.1038/321687a0

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