Hierarchical organic microspheres from diverse molecular building blocks

Li, Yintao; Fan, Longlong; Xu, Xinyan; Sun, Yang; Wang, Wei; Li, Bin; Veroneau, Samuel S.; Ji, Pengfei

Hierarchical organic microspheres from diverse molecular building blocks

Yintao Li, Longlong Fan, Xinyan Xu, Yang Sun, Wei Wang, Bin Li, Samuel S. Veroneau and Pengfei Ji ()
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Yintao Li: Zhejiang University
Longlong Fan: the Chinese Academy of Sciences
Xinyan Xu: Zhejiang University
Yang Sun: Zhejiang University
Wei Wang: Zhejiang University
Bin Li: Zhejiang University
Samuel S. Veroneau: Harvard University
Pengfei Ji: Zhejiang University

Nature Communications, 2024, vol. 15, issue 1, 1-13

Abstract: Abstract Microspherical structures find broad application in chemistry and materials science, including in separations and purifications, energy storage and conversion, organic and biocatalysis, and as artificial and bioactive scaffolds. Despite this utility, the systematic diversification of their morphology and function remains hindered by the limited range of their molecular building blocks. Drawing upon the design principles of reticular synthesis, where diverse organic molecules generate varied porous frameworks, we show herein how analogous microspherical structures can be generated under mild conditions. The assembly of simple organic molecules into microspherical structures with advanced morphologies represents a grand challenge. Beginning with a partially condensed Schiff base which self-assembles into a hierarchical organic microsphere, we systematically synthesized sixteen microspheres from diverse molecular building blocks. We subsequently explicate the mechanism of hierarchical assembly through which these hierarchical organic microspheres are produced, isolating the initial monomer, intermediate substructures, and eventual microspheres. Furthermore, the open cavities present on the surfaces of these constructs provided distinctive adsorptive properties, which we harnessed for the immobilization of enzymes and bacteriophages. Holistically, these hierarchical organic microspheres provide an approach for designing multi-functional superstructures with advanced morphologies derived from simple organic molecules, revealing an extended length scale for reticular synthesis.

Date: 2024
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DOI: 10.1038/s41467-024-49379-7

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