Giant surfactants provide a versatile platform for sub-10-nm nanostructure engineering

The engineering of structures across different length scales is central to the design of novel materials with controlled macroscopic properties. Herein, we introduce a unique class of self-assembling materials, which are built upon shape- and volume-persistent molecular nanoparticles and other struc...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 2013-06, Vol.110 (25), p.10078-10083
Main Authors: Yu, Xinfei, Yue, Kan, Hsieh, I-Fan, Li, Yiwen, Dong, Xue-Hui, Liu, Chang, Xin, Yu, Wang, Hsiao-Fang, Shi, An-Chang, Newkome, George R., Ho, Rong-Ming, Chen, Er-Qiang, Zhang, Wen-Bin, Cheng, Stephen Z. D.
Format: Article
Language:English
Subjects:
Block copolymers
Colloids - chemistry
Design engineering
Electronics - methods
Libraries
Materials
Microelectronics
Nanoparticles
Nanoparticles - chemistry
Nanostructured materials
Nanostructures
Nanotechnology - methods
Physical Sciences
Polymers
Self assembly
Surface Properties
Surface-Active Agents - chemistry
Surfactants
Thermodynamics
Thin films
Topology
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Summary:The engineering of structures across different length scales is central to the design of novel materials with controlled macroscopic properties. Herein, we introduce a unique class of self-assembling materials, which are built upon shape- and volume-persistent molecular nanoparticles and other structural motifs, such as polymers, and can be viewed as a size-amplified version of the corresponding small-molecule counterparts. Among them, “giant surfactants” with precise molecular structures have been synthesized by “clicking” compact and polar molecular nanoparticles to flexible polymer tails of various composition and architecture at specific sites. Capturing the structural features of small-molecule surfactants but possessing much larger sizes, giant surfactants bridge the gap between small-molecule surfactants and block copolymers and demonstrate a duality of both materials in terms of their self-assembly behaviors. The controlled structural variations of these giant surfactants through precision synthesis further reveal that their self-assemblies are remarkably sensitive to primary chemical structures, leading to highly diverse, thermodynamically stable nanostructures with feature sizes around 10 nm or smaller in the bulk, thin-film, and solution states, as dictated by the collective physical interactions and geometric constraints. The results suggest that this class of materials provides a versatile platform for engineering nanostructures with sub-10-nm feature sizes. These findings are not only scientifically intriguing in understanding the chemical and physical principles of the self-assembly, but also technologically relevant, such as in nanopatterning technology and microelectronics.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1302606110