Controllable modulation of precursor reactivity using chemical additives for systematic synthesis of high-quality quantum dots

Park, Joonhyuck; Jayaraman, Arun; Schrader, Alex W.; Hwang, Gyu Weon; Han, Hee-Sun

Controllable modulation of precursor reactivity using chemical additives for systematic synthesis of high-quality quantum dots

Joonhyuck Park, Arun Jayaraman, Alex W. Schrader, Gyu Weon Hwang and Hee-Sun Han ()
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Joonhyuck Park: University of Illinois at Urbana-Champaign
Arun Jayaraman: University of Illinois at Urbana-Champaign
Alex W. Schrader: University of Illinois at Urbana-Champaign
Gyu Weon Hwang: Korea Institute of Science and Technology
Hee-Sun Han: University of Illinois at Urbana-Champaign

Nature Communications, 2020, vol. 11, issue 1, 1-9

Abstract: Abstract The optical and electronic performance of quantum dots (QDs) are affected by their size distribution and structural quality. Although the synthetic strategies for size control are well established and widely applicable to various QD systems, the structural characteristics of QDs, such as morphology and crystallinity, are tuned mostly by trial and error in a material-specific manner. Here, we show that reaction temperature and precursor reactivity, the two parameters governing the surface-reaction kinetics during growth, govern the structural quality of QDs. For conventional precursors, their reactivity is determined by their chemical structure. Therefore, a variation of precursor reactivity requires the synthesis of different precursor molecules. As a result, existing precursor selections often have significant gaps in reactivity or require synthesis of precursor libraries comprising a large number of variants. We designed a sulfur precursor employing a boron-sulfur bond, which enables controllable modulation of their reactivity using commercially available Lewis bases. This precursor chemistry allows systematic optimization of the reaction temperature and precursor reactivity using a single precursor and grows high-quality QDs from cores of various sizes and materials. This work provides critical insights into the nanoparticle growth process and precursor designs, enabling the systematic preparation of high-quality QD of any sizes and materials.

Date: 2020
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DOI: 10.1038/s41467-020-19573-4

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