Ligand engineering of lead chalcogenide nanoparticle solar cells

ORAL

Abstract

Semiconductor nanoparticles (NP) are promising materials to build cheap and efficient solar cells. One of the key challenges in their utilization for solar energy conversion is the control of ligand-NP interfaces. Recent experiments have shown that by carefully choosing the ligands terminating the NPs, one can tailor electronic and optical absorption properties of NP assemblies, along with their transport properties.[1] By using density functional theory based methods, we investigated how the opto-electronic properties of lead chalcogenide NPs may be tuned by using diverse organic and inorganic ligands. We interpreted experiments, and we showed that an essential prerequisite to avoid detrimental trap states is to ensure charge balance at the ligand-NP interface, possibly with the help of hydrogen treatment. [1] Ryan Crisp et al., Scientific Reports 5, 9945 (2015); Carlo Giansante et al., J. Am. Chem. Soc. 137, 1875 (2015).

*Work supported by the Center for Advanced Solar Photophysics, an Energy Frontier Research Center funded by the US Department of Energy, Office of Science, Office of Basic Energy Sciences.

Authors

  • Marton Voros

    • Argonne Natl Lab
    • Materials Science Division, Argonne National Laboratory

  • Nicholas Brawand

    • Institute for Molecular Engineering, University of Chicago

  • Giulia Galli

    • Institute for Molecular Engineering, University of Chicago
    • University of Chicago
    • Institute for Molecular Engineering, the University of Chicago
    • Univ of Chicago
    • Institute for Molecular Engineering University of Chicago
    • Institute for Molecular Engineering-The University of Chicago, and Argonne National Laboratory
    • Institute for Molecular Engineering, The University of Chicago
    • Institute for Molecular Engineering, University of Chicago & Argonne National Laboratory