Litcius/Paper detail

Effect of Anisotropic Confinement on Electronic Structure and Dynamics of Band Edge Excitons in Inorganic Perovskite Nanowires

Brendan Folie, Jenna A. Tan, Jianmei Huang, Peter C. Sercel, Milan Delor, Minliang Lai, John L. Lyons, Noam Bernstein, Alexander L. Efros, Peidong Yang, Naomi S. Ginsberg

2020The Journal of Physical Chemistry A45 citationsDOIOpen Access PDF

Abstract

Inorganic lead halide perovskite nanostructures show promise as the active layers in photovoltaics, light emitting diodes, and other optoelectronic devices. They are robust in the presence of oxygen and water, and the electronic structure and dynamics of these nanostructures can be tuned through quantum confinement. Here we create aligned bundles of CsPbBr3 nanowires with widths resulting in quantum confinement of the electronic wave functions and subject them to ultrafast microscopy. We directly image rapid one-dimensional exciton diffusion along the nanowires, and we measure an exciton trap density of roughly one per nanowire. Using transient absorption microscopy, we observe a polarization-dependent splitting of the band edge exciton line, and from the polarized fluorescence of nanowires in solution, we determine that the exciton transition dipole moments are anisotropic in strength. Our observations are consistent with a model in which splitting is driven by shape anisotropy in conjunction with long-range exchange.

Topics & Concepts

NanowireExcitonQuantum dotMaterials scienceCondensed matter physicsAnisotropyBiexcitonPerovskite (structure)Ultrafast laser spectroscopyOptoelectronicsMolecular physicsPhysicsOpticsChemistryLaserCrystallographyPerovskite Materials and ApplicationsQuantum Dots Synthesis And Properties2D Materials and Applications