UV curing of epoxy functional hybrid silicones

Putzien, Sophie; Louis, E.; Nuyken, Oskar; Crivello, James V.; Kühn, Fritz E.

doi:10.1002/app.36864

Cited by 19 publications

(19 citation statements)

References 15 publications

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“…Crosslinking compounds 2 with telechelich ydrosilicones in the presence of Karstedt's Pt catalyst in the same pot (without workup)l ed to bubble-free elastomers of type 3 (Scheme 3ACF,T able 1). These experiments showedt hat the presence of B(C 6 F 5 ) 3 did not affect the catalytic behavior of the platinum catalyst;w ithoutp latinum, hydrosilylation was not observed.…”

Section: Resultsmentioning

confidence: 90%

“…The platinum catalysti ns tep 2d oes not appear to be affectedb y the presence of B(C 6 F 5 ) 3 and C=Ch ydrosilylation was observed. However, the PR reactioni ns tep 3w as slower than other PR reactions, suggesting boron catalyst degradation or inhibition along the way, but addition of as econd bolus of BCF without any intervening workup led to cleanr eaction in the same pot.…”

Section: Resultsmentioning

confidence: 94%

“…The resulting networks reflect the specific batch of pendant-functional polymers used. It is, therefore, difficult to reproducibly preparep recise networks from commercial materials.It is possible to create networks containing av ariety of silicone precursors in as omewhat controlledm anner by using ac ombinationo fo rthogonal cure technologiess elected from silicone and organic chemistry;d ual cure systemst hat combine any of the cure technologiesn oted above with amine/ epoxy, [2] cationic epoxy polymerization, [3] thiol-ene click, [4] or azide/alkyne click [5] allow complex network materials to be prepared. Most of thesep rocesses, however,s till suffer from random placement of crosslinking groups along as ilicone backbone.…”

mentioning

confidence: 99%

“…In all cases, the complexf ormed between B(C 6 F 5 ) 3 (BCF) and ah ydrosilane reacts with siloxonium ions to form siloxane bondsa nd either H 2 or an alkane (RH) byproduct (shownf or phenolics, Scheme 2B). BCF will also catalyzet he hydrosilylation reaction with alkenes, [9] but only using high concentrations of catalyst ( % 5mol %).…”

mentioning

confidence: 99%

“…Eugenoli sareadily available organic material extracted from cloves and other plants. [10] It has three different functional groups that should react with SiH with very different efficiencies using either platinum catalysts or B(C 6 F 5 ) 3 .P latinums hould preferentially promote SiH reactions with RHC=CH 2 groups, and react much less efficientlyw ith ArOH, [11] while BCF will catalyze reactions between SiHa nd ArOH or ArOMe, respectively. Use of this crosslinker would allow up to three different silicones to be sequentially linked to the central aromatic core, permitting the preparation of precise networks from commercial telechelic silicones;t he products' properties could be tuned by selection of the chain lengths of the three silicones, backbone functionalization, and which silicone chain grafts via hydrosilylation.…”

mentioning

confidence: 99%

See 4 more Smart Citations

Sequential Functionalization of a Natural Crosslinker Leads to Designer Silicone Networks

Laengert

Schneider

Lovinger

et al. 2017

Chemistry An Asian Journal

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Precise silicone networks are difficult to prepare from multiple starting materials because of poor spatial control over crosslinkl ocation, competing side reactions, and incompatible catalysts among other reasons. We demonstrate that cure processes catalyzed by B(C 6 F 5 ) 3 (the Piers-Rubinsztajn reaction) and platinum-catalyzed hydrosilylation are perfectly compatible,a nd can be used in either order.I ti sp ossible to perform three different, selective, sequential reactions in the same potu sing H-terminated silicones as chain extenders in all cases to give explicit networks. Eugenol, ar eadily available aromatic compound, acts as at rifunctional crosslinker (HO,M eO, HC= CH 2 ), each functional group of which can be induced to undergo selectiver eaction. With platinum catalysis, the reaction of SiH groups with alkenes is fastest, while B(C 6 F 5 ) 3 catalyzes reaction at phenolsm uch faster than methoxybenzene. Thus, av ariety of H-terminated telechelic siloxanes can be used to form chain extended polymers or elastomers or foams in whicht he morphology of the material and its constituent parts can be manipulated at will.As with most polymers, the current paradigm for the preparation of silicone polymers, including elastomers, should involve enhanced synthetic control such that desired properties can be attained. Structural control, however,isnot ahallmark of silicone elastomers. The three commercialc ure mechanisms normally utilized are radical, moisture cure (room-temperature vulcanization RTV), and platinum-catalyzed hydrosilylation (PtHSi).[1] Radical cure leads to irreproducible, random networks. In selected cases,m oisture cure allows the controlled incorporation of two different silicone polymers through the use of telechelic crosslinkers;more complex structures are difficult to attain. However, network errors occur when competitive hydrolysisl eads to loss of spatialc ontrolo fc rosslinks at ag iven silicon atom (Scheme 1A).Platinum-catalyzed crosslinking (PtHSi), the most common route to high-quality siliconee lastomers, utilizes the combination of telechelic silicones with pendant functional chains.U nfortunately,t he absolutec oncentration of functional groups on ag iven chain and their relative locations along the chain cannotb er eadily controlled (Scheme 1B). The resulting networks reflect the specific batch of pendant-functional polymers used. It is, therefore, difficult to reproducibly preparep recise networks from commercial materials.It is possible to create networks containing av ariety of silicone precursors in as omewhat controlledm anner by using ac ombinationo fo rthogonal cure technologiess elected from silicone and organic chemistry;d ual cure systemst hat combine any of the cure technologiesn oted above with amine/ epoxy, [2] cationic epoxy polymerization, [3] thiol-ene click, [4] or azide/alkyne click [5] allow complex network materials to be prepared. Most of thesep rocesses, however,s till suffer from random placement of crosslinking groups along as ilicone backbone.T...

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Section: Resultsmentioning

confidence: 90%

Section: Resultsmentioning

confidence: 94%

mentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

See 3 more Smart Citations

Sequential Functionalization of a Natural Crosslinker Leads to Designer Silicone Networks

Laengert

Schneider

Lovinger

et al. 2017

Chemistry An Asian Journal

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Synthesis and ultraviolet‐curing behaviors of vinyl ether functionalized polyurethane oligomers

Feng

Zou

2014

J of Applied Polymer Sci

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The vinyl ether functionalized oligomer is one of the most basic components of vinyl ether functionalized materials for cationic UV-curable coatings. In this study, three types of vinyl ether functionalized polyurethane oligomers (i.e., polyether, polyester, and polydimethylsiloxane) were synthesized with diisocyanate, diol, and hydroxyethyl vinyl ether. These oligomers were characterized by IR, 1 H-NMR, and 13 C-NMR spectroscopy. The effect of the raw material ratio on the oligomer, UV-curing behaviors, and thermal properties of these oligomers were investigated. The UV-curing behavior was analyzed by real-time Fourier transform infrared spectroscopy. The vinyl ether terminated polyester urethane oligomer exhibited better UV curing, with a higher final conversion and maximum UV-curing rates. In addition, the light intensity was enhanced for oligomers with better UV-curing properties. Research on these vinyl ether functionalized oligomers is essential to the development and applications of cationic vinyl ethers systems. V C 2014Wiley Periodicals, Inc. J. Appl. Polym. Sci. 2014, 131, 40501.

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Aliphatic silicone‐epoxy based hybrid photopolymers applied in stereolithography 3D printing

Zhao

Huang

et al. 2020

Polymers for Advanced Techs

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3D Printing has become a powerful technology for future advanced manufacturing, however the choice of materials with good performance is still limited. In this research, a type of hybrid photopolymer resin based on silicone epoxy with high UV curing rate and low viscosity was applied in stereolithography (SLA) technology. First, aliphatic silicone epoxy was synthesized through hydrosilylation reaction, and then compounding with acrylates, cycloaliphatic epoxy and photo‐initiators, finally the hybrid photopolymer system for SLA was obtained. The features of UV curing process were studied through photo‐differential scanning calorimetry and real‐time Fourier transform infrared measurements. Scanning electron microscopy test showed interpenetrating polymer network structure was formed in 3D objects. The performances of 3D printed sample such as mechanical properties, thermal mechanical and stability properties were also investigated in detail. Moreover, the 3D printed objects with complicated structures showed high printing accuracy. This new type of hybrid photopolymer system based on aliphatic silicone epoxy was with fabrication ease, good mechanical properties, good thermal stability and high printing resolution and has great potential of applications in industrial design and models making fields.

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UV curing of epoxy functional hybrid silicones

Cited by 19 publications

References 15 publications

Sequential Functionalization of a Natural Crosslinker Leads to Designer Silicone Networks

Sequential Functionalization of a Natural Crosslinker Leads to Designer Silicone Networks

Synthesis and ultraviolet‐curing behaviors of vinyl ether functionalized polyurethane oligomers

Aliphatic silicone‐epoxy based hybrid photopolymers applied in stereolithography 3D printing

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