Highly Tunable Thiol–Ene Networks via Dual Thiol Addition

Throughout the past decade, investigations of thick thermoset thiol–ene networks (TENs) have become increasingly prominent in the literature due to facile, quantitative synthesis giving rise to unique network characteristics, specifically high mechanical energy damping. This article reports the synt...

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Bibliographic Details
Published in:Macromolecules 2013-07, Vol.46 (14), p.5614-5621
Main Authors: McNair, Olivia. D, Sparks, Bradley J, Janisse, Andrew P, Brent, Davis P, Patton, Derek L, Savin, Daniel A
Format: Article
Language:English
Subjects:
Applied sciences
Exact sciences and technology
Physicochemistry of polymers
Polymerization
Polymers and radiations
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Summary:Throughout the past decade, investigations of thick thermoset thiol–ene networks (TENs) have become increasingly prominent in the literature due to facile, quantitative synthesis giving rise to unique network characteristics, specifically high mechanical energy damping. This article reports the synthesis and thermomechanical properties of ternary thiol–thiol–ene systems that exhibit tunable glass transitions that maintain high, narrow tan δ values in the glass transition region. We begin with a base network of a trifunctional thiol and a trifunctional ene and then systematically substitute the trifunctional thiol with a series of difunctional thiols while maintaining stoichiometric balance between total thiol and ene content. The resultant ternary networks exhibit glass transition temperatures that follow the Fox equation. In contrast to other ternary thiol–ene networks, we observe minimal broadening of the glass transition region, which implies that we can retain the energy-absorbing capabilities of the thiol–ene system. This approach has high potential as a simple tool for scientists and researchers to tune T gs for select networks without detrimentally affecting other physical properties.
ISSN:0024-9297
1520-5835
DOI:10.1021/ma400748h