Dissections: self-assembled aggregates that spontaneously reconfigure their structures when their environment changes.

Dissections: self-assembled aggregates that spontaneously reconfigure their structures when their environment changes. Research Abstract Details 

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Dissections: self-assembled aggregates that spontaneously reconfigure their structures when their environment changes. Abstract Text:

Chengde Mao,Venkat R Thalladi,Daniel B Wolfe,Sue Whitesides,George M Whitesides,

This Communication describes a new strategy for the design of adaptive structures based on reconfigurable mesoscale self-assembly. Several sets of millimeter-scale objects have been designed that can self-assemble into two different, regular aggregates at the interface between an aqueous solution and perfluorodecalin; the choice between the two aggregates is determined by the density of the aqueous phase.

Dissections: self-assembled aggregates that spontaneously reconfigure their structures when their environment changes. Publishing Authors By Initials

C Mao,VR Thalladi,DB Wolfe,S Whitesides,GM Whitesides,

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Dissections: self-assembled aggregates that spontaneously reconfigure their structures when their environment changes. Journal Published:

PUBLICATION TYPE: Journal Article

Journal: Journal of the American Chemical Society

VOLUME: 124

Page Numbers: 14508-9

Journal Abbreviation: J. Am. Chem. Soc.

ISSN: 0002-7863

DAY: 11

MONTH: Dec

YEAR: 2002

Dissections: self-assembled aggregates that spontaneously reconfigure their structures when their environment changes. Information

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LANGUAGE: eng

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AFFILIATION: Department of Chemistry and Chemical Biology, Harvard University, 12 Oxford Street, Cambridge, Massachusetts 02138, USA.

Country: United States

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MEDLINETA: J Am Chem Soc

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