Efficient Synthesis of α,ω-Divinyl-Functionalized Polyolefins

Efficient Synthesis of α,ω-Divinyl-Functionalized Polyolefins

A facile one‐step olefin metathesis‐mediated ethenolysis reaction on polyolefins containing 1,4‐inserted butadiene units yields α,ω‐divinyl telechelic polymers. These reactions can be successfully performed with well‐defined thermally stable ruthenium catalysts to yield essentially complete metathes...

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Veröffentlicht in:Macromolecular chemistry and physics 2014-06, Vol.215 (11), p.1140-1145
Hauptverfasser: Patil, Vishal B., Saliu, Kuburat O., Jenkins, Roxanne M., Carnahan, Edmund M., Kramer, Edward J., Fredrickson, Glenn H., Bazan, Guillermo C.
Format: Artikel
Sprache:eng
Schlagworte:
Applied sciences
Catalysis
Catalysts
Chemical modifications
Chemical reactions and properties
Decomposition reactions
depolymerization
ethenolysis
Ethylene
Exact sciences and technology
Isomerization
Metathesis
olefin metathesis
Olefins
Organic polymers
Physicochemistry of polymers
Polyolefins
Ruthenium
telechelic polymers
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container_end_page 1145
container_issue 11
container_start_page 1140
container_title Macromolecular chemistry and physics
container_volume 215
creator Patil, Vishal B.
Saliu, Kuburat O.
Jenkins, Roxanne M.
Carnahan, Edmund M.
Kramer, Edward J.
Fredrickson, Glenn H.
Bazan, Guillermo C.
description A facile one‐step olefin metathesis‐mediated ethenolysis reaction on polyolefins containing 1,4‐inserted butadiene units yields α,ω‐divinyl telechelic polymers. These reactions can be successfully performed with well‐defined thermally stable ruthenium catalysts to yield essentially complete metathesis of internal double bonds. The reaction progress is monitored by 1H NMR spectroscopy over time, by tracking the disappearance of the signal due to internal unsaturation of 1,4‐butadiene at ca. 5.5 ppm in toluene‐d8 solvent. The reaction conditions are optimized for ethylene pressure, temperature, catalyst loading, and reaction time. Catalyst loading of 45:1 1,4‐butadiene unsaturation to catalyst at 90 °C with 25 psi ethylene pressure is successful in removing internal unsaturation with no detectable isomerization side reactions. High‐temperature gel‐permeation chromatography (GPC) analysis of the depolymerized product correlates to the calculated molecular weight based on the number of internal double bonds observed in the 1H NMR analysis of the starting polyolefin. This method offers a single step, rapid, and clean route toward divinyl‐terminated telechelic polymers based on commodity materials in high yields. The olefin metathesis reaction of a polyolefin containing inserted 1,4‐butadiene using an indenylidene‐based ruthenium catalyst in the presence of ethylene gas yields the formation of an α,ω‐divinyl poly­olefin with undetectable isomerization side reactions and complete elimination of internal unsaturation.
doi_str_mv 10.1002/macp.201400139
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These reactions can be successfully performed with well‐defined thermally stable ruthenium catalysts to yield essentially complete metathesis of internal double bonds. The reaction progress is monitored by 1H NMR spectroscopy over time, by tracking the disappearance of the signal due to internal unsaturation of 1,4‐butadiene at ca. 5.5 ppm in toluene‐d8 solvent. The reaction conditions are optimized for ethylene pressure, temperature, catalyst loading, and reaction time. Catalyst loading of 45:1 1,4‐butadiene unsaturation to catalyst at 90 °C with 25 psi ethylene pressure is successful in removing internal unsaturation with no detectable isomerization side reactions. High‐temperature gel‐permeation chromatography (GPC) analysis of the depolymerized product correlates to the calculated molecular weight based on the number of internal double bonds observed in the 1H NMR analysis of the starting polyolefin. This method offers a single step, rapid, and clean route toward divinyl‐terminated telechelic polymers based on commodity materials in high yields. 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subjects Applied sciences
Catalysis
Catalysts
Chemical modifications
Chemical reactions and properties
Decomposition reactions
depolymerization
ethenolysis
Ethylene
Exact sciences and technology
Isomerization
Metathesis
olefin metathesis
Olefins
Organic polymers
Physicochemistry of polymers
Polyolefins
Ruthenium
telechelic polymers
title Efficient Synthesis of α,ω-Divinyl-Functionalized Polyolefins
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