DOI

  • Pascal Büttner
  • Florian Scheler
  • Craig Pointer
  • Dirk Döhler
  • Tadahiro Yokosawa
  • Erdmann Spiecker
  • Pablo P. Boix
  • Elizabeth R. Young
  • Ignacio Mínguez-Bacho
  • Julien Bachmann

Antimony chalcogenides represent a family of materials of low toxicity and relative abundance, with a high potential for future sustainable solar energy conversion technology. However, solar cells based on antimony chalcogenides present open-circuit voltage losses that limit their efficiencies. These losses are attributed to several recombination mechanisms, with interfacial recombination being considered as one of the dominant processes. In this work, we exploit atomic layer deposition (ALD) to grow a series of ultrathin ZnS interfacial layers at the TiO2/Sb2S3 interface to mitigate interfacial recombination and to increase the carrier lifetime. ALD allows for very accurate control over the ZnS interlayer thickness on the ångström scale (0-1.5 nm) and to deposit highly pure Sb2S3. Our systematic study of the photovoltaic and optoelectronic properties of these devices by impedance spectroscopy and transient absorption concludes that the optimum ZnS interlayer thickness of 1.0 nm achieves the best balance between the beneficial effect of an increased recombination resistance at the interface and the deleterious barrier behavior of the wide-bandgap semiconductor ZnS. This optimization allows us to reach an overall power conversion efficiency of 5.09% in planar configuration.

Original languageEnglish
Pages (from-to)11861-11868
Number of pages8
JournalACS Applied Materials and Interfaces
Volume13
Issue number10
DOIs
StatePublished - 5 Mar 2021

    Scopus subject areas

  • Materials Science(all)

    Research areas

  • anti-recombination layer, atomic layer deposition, chalcogenides, extremely thin absorber, interfacial layer, passivation layer, thin film solar cells, tunnel barrier

ID: 77893701