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Design and Application of a Hybrid Material Featuring Well‐Defined, Tuneable Grafting Sites for Supported Catalysis.
Author(s) -
Popoff Nicolas,
Espinas Jeff,
Pelletier Jérémie,
Szeto Kai C.,
ThivolleCazat Jean,
Delevoye Laurent,
Gauvin Régis M.,
Taoufik Mostafa
Publication year - 2013
Publication title -
chemcatchem
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 1.497
H-Index - 106
eISSN - 1867-3899
pISSN - 1867-3880
DOI - 10.1002/cctc.201200850
Subject(s) - yield (engineering) , catalysis , hydroquinone , metathesis , ethylene , reagent , grafting , amorphous silica , chemistry , heterogeneous catalysis , amorphous solid , propene , organometallic chemistry , materials science , nuclear chemistry , polymer chemistry , medicinal chemistry , chemical engineering , organic chemistry , polymerization , engineering , metallurgy , polymer
A new material based on amorphous silica, and featuring a well‐defined phenolic functionality was prepared in two simple steps by using commercially available, cheap reagents. Silica was first reacted with aluminum isobutyl etherate to yield an aluminum isobutyl site [(≡SiO) 2 Al( i Bu)(Et 2 O)], which then selectively reacted with a hydroquinone spacer to yield [(≡SiO) 2 (AlOC 6 X 4 OH)(Et 2 O)] (X=H or F). This support material was then used to tether the organometallic tungstenocarbyne complex [W(≡C t Bu)(CH 2 t Bu) 3 ] to yield the surface species [(≡SiO) 2 (AlOC 6 X 4 O‐W(≡C t Bu)(CH 2 t Bu) 2 (Et 2 O)] (X=H or F). Both H‐ and F‐containing species were fully characterized, and their activities in the self‐metathesis reaction of propene to ethylene and 2‐butenes were found to be two and three times higher, respectively, than the activity of the corresponding tungstenocarbyne complex directly grafted onto silica.