Tunable self-assembled elastomers using triply hydrogen-bonded arrays

Adam Gooch; Chinemelum Nedolisa; Kelly A. Houton; Christopher I. Lindsay; Alberto Saiani; Andrew J. Wilson

doi:10.1021/ma3001109

Tunable self-assembled elastomers using triply hydrogen-bonded arrays

Adam Gooch, Chinemelum Nedolisa, Kelly A. Houton, Christopher I. Lindsay, Alberto Saiani, Andrew J. Wilson

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

Abstract

This article describes the synthesis and surpamolecular assembly of polyurethane-based elastomers. Triple hydrogen bonding between novel amidoisocytosine (AIC) and ureidoimidazole (UIM) motifs is used to promote assembly of the material. The material comprises an amorphous phase derived from a telechelic diol and a hard crystalline phase that comprises the supramolecular end groups. The use of a heterocomplementary hydrogen bonding interaction results in two unique features: (1) assembly of the elastomer occurs only in the presence of both components, and (2) different feed ratios used during synthesis allow the materials properties to be tuned as the stoichiometries of the components found in the amorphous and crystalline phases of the material are varied. The approach hence offers supramolecular control over materials properties and results in materials that can be melted and therefore processed at lower temperature compared to standard covalent elastomers. © 2012 American Chemical Society.

Original language	English
Pages (from-to)	4723-4729
Number of pages	6
Journal	Macromolecules
Volume	45
Issue number	11
DOIs	https://doi.org/10.1021/ma3001109
Publication status	Published - 12 Jun 2012

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title = "Tunable self-assembled elastomers using triply hydrogen-bonded arrays",

abstract = "This article describes the synthesis and surpamolecular assembly of polyurethane-based elastomers. Triple hydrogen bonding between novel amidoisocytosine (AIC) and ureidoimidazole (UIM) motifs is used to promote assembly of the material. The material comprises an amorphous phase derived from a telechelic diol and a hard crystalline phase that comprises the supramolecular end groups. The use of a heterocomplementary hydrogen bonding interaction results in two unique features: (1) assembly of the elastomer occurs only in the presence of both components, and (2) different feed ratios used during synthesis allow the materials properties to be tuned as the stoichiometries of the components found in the amorphous and crystalline phases of the material are varied. The approach hence offers supramolecular control over materials properties and results in materials that can be melted and therefore processed at lower temperature compared to standard covalent elastomers. {\textcopyright} 2012 American Chemical Society.",

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T1 - Tunable self-assembled elastomers using triply hydrogen-bonded arrays

AU - Gooch, Adam

AU - Nedolisa, Chinemelum

AU - Houton, Kelly A.

AU - Lindsay, Christopher I.

AU - Saiani, Alberto

AU - Wilson, Andrew J.

N1 - Gooch, Adam Nedolisa, Chinemelum Houton, Kelly A. Lindsay, Christopher I. Saiani, Alberto Wilson, Andrew J.

PY - 2012/6/12

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N2 - This article describes the synthesis and surpamolecular assembly of polyurethane-based elastomers. Triple hydrogen bonding between novel amidoisocytosine (AIC) and ureidoimidazole (UIM) motifs is used to promote assembly of the material. The material comprises an amorphous phase derived from a telechelic diol and a hard crystalline phase that comprises the supramolecular end groups. The use of a heterocomplementary hydrogen bonding interaction results in two unique features: (1) assembly of the elastomer occurs only in the presence of both components, and (2) different feed ratios used during synthesis allow the materials properties to be tuned as the stoichiometries of the components found in the amorphous and crystalline phases of the material are varied. The approach hence offers supramolecular control over materials properties and results in materials that can be melted and therefore processed at lower temperature compared to standard covalent elastomers. © 2012 American Chemical Society.

AB - This article describes the synthesis and surpamolecular assembly of polyurethane-based elastomers. Triple hydrogen bonding between novel amidoisocytosine (AIC) and ureidoimidazole (UIM) motifs is used to promote assembly of the material. The material comprises an amorphous phase derived from a telechelic diol and a hard crystalline phase that comprises the supramolecular end groups. The use of a heterocomplementary hydrogen bonding interaction results in two unique features: (1) assembly of the elastomer occurs only in the presence of both components, and (2) different feed ratios used during synthesis allow the materials properties to be tuned as the stoichiometries of the components found in the amorphous and crystalline phases of the material are varied. The approach hence offers supramolecular control over materials properties and results in materials that can be melted and therefore processed at lower temperature compared to standard covalent elastomers. © 2012 American Chemical Society.

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ER -

Tunable self-assembled elastomers using triply hydrogen-bonded arrays

Abstract

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