Colloidal Assembly Approaches to Micro/Nanostructures of Complex Morphologies

The ability to programmatically assemble colloidal micro/nanostructures into highly ordered superstructures is of great importance in both fundamental studies and practical applications. In addition to the sophisticated manipulation of the short‐range and long‐range interactions imposed on the collo...

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Published inSmall (Weinheim an der Bergstrasse, Germany) Vol. 14; no. 35; pp. e1801083 - n/a
Main Authors Xu, Wenjing, Li, Zhiwei, Yin, Yadong
Format Journal Article
LanguageEnglish
Published Germany Wiley Subscription Services, Inc 01.08.2018
Subjects
anisotropic nanostructures
Assembly
colloidal particles
Colloids
Curvature
Morphology
Nanostructure
Nanotechnology
Superstructures
assembly
colloidal particles
anisotropic nanostructures
morphology
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Abstract The ability to programmatically assemble colloidal micro/nanostructures into highly ordered superstructures is of great importance in both fundamental studies and practical applications. In addition to the sophisticated manipulation of the short‐range and long‐range interactions imposed on the colloidal building blocks, the intrinsic shape elements including face, edge, corner, concave, convex, and curvature also play very important roles in solving the “jigsaw puzzle” of the superstructures. Here, the recent progress in the development of colloidal assembly strategies for the formation of complex superstructures is reviewed, with a primary focus on the unique effects of the morphology of the building blocks to the assembly processes and the final structures. Overall, this Review aims to shed light on the fundamental understanding of the colloidal behaviors of complex micro/nanostructures and promote the continued development of effective strategies for the creation of functional materials with complex compositions and morphologies. Colloidal assembly of micro/nanostructures represents one of the most effective approaches to achieve highly ordered superstructures. Here the recent progress of colloidal assembly strategies is reviewed, especially the unique effects of morphology of the building blocks to the assembly process.
AbstractList The ability to programmatically assemble colloidal micro/nanostructures into highly ordered superstructures is of great importance in both fundamental studies and practical applications. In addition to the sophisticated manipulation of the short-range and long-range interactions imposed on the colloidal building blocks, the intrinsic shape elements including face, edge, corner, concave, convex, and curvature also play very important roles in solving the "jigsaw puzzle" of the superstructures. Here, the recent progress in the development of colloidal assembly strategies for the formation of complex superstructures is reviewed, with a primary focus on the unique effects of the morphology of the building blocks to the assembly processes and the final structures. Overall, this Review aims to shed light on the fundamental understanding of the colloidal behaviors of complex micro/nanostructures and promote the continued development of effective strategies for the creation of functional materials with complex compositions and morphologies.
The ability to programmatically assemble colloidal micro/nanostructures into highly ordered superstructures is of great importance in both fundamental studies and practical applications. In addition to the sophisticated manipulation of the short‐range and long‐range interactions imposed on the colloidal building blocks, the intrinsic shape elements including face, edge, corner, concave, convex, and curvature also play very important roles in solving the “jigsaw puzzle” of the superstructures. Here, the recent progress in the development of colloidal assembly strategies for the formation of complex superstructures is reviewed, with a primary focus on the unique effects of the morphology of the building blocks to the assembly processes and the final structures. Overall, this Review aims to shed light on the fundamental understanding of the colloidal behaviors of complex micro/nanostructures and promote the continued development of effective strategies for the creation of functional materials with complex compositions and morphologies. Colloidal assembly of micro/nanostructures represents one of the most effective approaches to achieve highly ordered superstructures. Here the recent progress of colloidal assembly strategies is reviewed, especially the unique effects of morphology of the building blocks to the assembly process.
The ability to programmatically assemble colloidal micro/nanostructures into highly ordered superstructures is of great importance in both fundamental studies and practical applications. In addition to the sophisticated manipulation of the short-range and long-range interactions imposed on the colloidal building blocks, the intrinsic shape elements including face, edge, corner, concave, convex, and curvature also play very important roles in solving the "jigsaw puzzle" of the superstructures. Here, the recent progress in the development of colloidal assembly strategies for the formation of complex superstructures is reviewed, with a primary focus on the unique effects of the morphology of the building blocks to the assembly processes and the final structures. Overall, this Review aims to shed light on the fundamental understanding of the colloidal behaviors of complex micro/nanostructures and promote the continued development of effective strategies for the creation of functional materials with complex compositions and morphologies.The ability to programmatically assemble colloidal micro/nanostructures into highly ordered superstructures is of great importance in both fundamental studies and practical applications. In addition to the sophisticated manipulation of the short-range and long-range interactions imposed on the colloidal building blocks, the intrinsic shape elements including face, edge, corner, concave, convex, and curvature also play very important roles in solving the "jigsaw puzzle" of the superstructures. Here, the recent progress in the development of colloidal assembly strategies for the formation of complex superstructures is reviewed, with a primary focus on the unique effects of the morphology of the building blocks to the assembly processes and the final structures. Overall, this Review aims to shed light on the fundamental understanding of the colloidal behaviors of complex micro/nanostructures and promote the continued development of effective strategies for the creation of functional materials with complex compositions and morphologies.
Author Li, Zhiwei
Xu, Wenjing
Yin, Yadong
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  surname: Yin
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  organization: University of California
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2015; 115
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2011 2008 2011; 11 112 107
1997 2001 2002; 385 11 12
2009 2012; 5 134
2013; 34
2015; 112
2007 2006; 104 128
2016 2005; 10 109
2008 2009 2009 2010 2011 2013 2009; 20 21 131 114 7 1 3
2011 2012 2014; 21 6 14
2009; 9
2011 2012; 108 3
2013; 135
2007 2008 2007; 46 181 7
2008; 455
2002 2005 2008 2003 2008; 298 5 41 3 130
2007 2004; 111 303
2012; 7
2016; 28
2014; 345
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Snippet The ability to programmatically assemble colloidal micro/nanostructures into highly ordered superstructures is of great importance in both fundamental studies...
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SubjectTerms anisotropic nanostructures
Assembly
colloidal particles
Colloids
Curvature
Morphology
Nanostructure
Nanotechnology
Superstructures
Title Colloidal Assembly Approaches to Micro/Nanostructures of Complex Morphologies
URI https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fsmll.201801083
https://www.ncbi.nlm.nih.gov/pubmed/30039921
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Volume 14
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