Energy Transfer in Stability-Optimized Perovskite Nanocrystals

Outstanding optoelectronic properties and a facile synthesis render halide perovskite nanocrystals (NCs) a promising material for nanostructure-based devices. However, the commercialization is hindered mainly by the lack of NC stability under ambient conditions and inefficient charge carrier injecti...

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Veröffentlicht in:Nano letters 2022-08, Vol.22 (16), p.6709-6715
Hauptverfasser: Greiner, Michèle G., Singldinger, Andreas, Henke, Nina A., Lampe, Carola, Leo, Ulrich, Gramlich, Moritz, Urban, Alexander S.
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container_end_page 6715
container_issue 16
container_start_page 6709
container_title Nano letters
container_volume 22
creator Greiner, Michèle G.
Singldinger, Andreas
Henke, Nina A.
Lampe, Carola
Leo, Ulrich
Gramlich, Moritz
Urban, Alexander S.
description Outstanding optoelectronic properties and a facile synthesis render halide perovskite nanocrystals (NCs) a promising material for nanostructure-based devices. However, the commercialization is hindered mainly by the lack of NC stability under ambient conditions and inefficient charge carrier injection. Here, we investigate solutions to both problems, employing methylammonium lead bromide (MAPbBr3) NCs encapsulated in diblock copolymer core–shell micelles of tunable size. We confirm that the shell does not prohibit energy transfer, as FRET efficiencies between these NCs and 2D CsPbBr3 nanoplatelets (NPLs) reach 73.6%. This value strongly correlates to the micelle size, with thicker shells displaying significantly reduced FRET efficiencies. Those high efficiencies come with a price, as the thinnest shells protect the encapsulated NCs less from environmentally induced degradation. Finding the sweet spot between efficiency and protection could lead to the realization of tailored energy funnels with enhanced carrier densities for high-power perovskite NC-based optoelectronic applications.
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