Toward Mimicking Viral Geometry with Metal-Organic Systems

J.L. Atwood; L.J. Barbour; S.J. Dalgarno; M.J. Hardie; Colin Raston; H.R. Webb

doi:10.1021/ja048058r

Toward Mimicking Viral Geometry with Metal-Organic Systems

J.L. Atwood
, L.J. Barbour
, S.J. Dalgarno
, M.J. Hardie
, Colin Raston
, H.R. Webb

Research output: Contribution to journal › Article › peer-review

145 Citations (Scopus)

Abstract

Icosahedral and cuboctahedral arrangements of calixarenes, a nanometer-scale, spheroidal assembly of 12 calixarene molecules, can be manipulated in a highly controlled fashion. Previously, such assemblies were observed to favor placement of the calixarenes at the vertexes of an icosahedron. A supramolecular constraint is employed in order to enforce molecular alignment and produce a cuboctahedral arrangement. The internal volume of the cuboctahedron is approximately 30% greater than that of the icosahedron. Furthermore, in stark contrast to that of the icosahedral Platonic solid, the shell of the cuboctahedral Archimedean solid is porous.

Original language	English
Pages (from-to)	13170-13171
Journal	Journal of the American Chemical Society
Volume	126
Issue number	41
DOIs	https://doi.org/10.1021/ja048058r
Publication status	Published - 2004

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10.1021/ja048058r

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AU - Hardie, M.J.

AU - Raston, Colin

AU - Webb, H.R.

PY - 2004

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AB - Icosahedral and cuboctahedral arrangements of calixarenes, a nanometer-scale, spheroidal assembly of 12 calixarene molecules, can be manipulated in a highly controlled fashion. Previously, such assemblies were observed to favor placement of the calixarenes at the vertexes of an icosahedron. A supramolecular constraint is employed in order to enforce molecular alignment and produce a cuboctahedral arrangement. The internal volume of the cuboctahedron is approximately 30% greater than that of the icosahedron. Furthermore, in stark contrast to that of the icosahedral Platonic solid, the shell of the cuboctahedral Archimedean solid is porous.

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JO - Journal of the American Chemical Society

JF - Journal of the American Chemical Society

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ER -

Toward Mimicking Viral Geometry with Metal-Organic Systems

Abstract

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