How a Thermally Unstable Metal Hydrido Complex Can Yield High Catalytic Activity Even at Elevated Temperatures

Despite their instability in ethereal solvents, organotitanium hydride catalysts are successfully employed in catalysis at moderate to high temperatures (110 °C), even in the presence of alcohols. It is shown computationally (bond dissociation energy (BDE) analysis and energetic profile for regenera...

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Published in:Chemistry : a European journal 2016-06, Vol.22 (27), p.9305-9310
Main Authors: Ehm, Christian, Krüger, Juliane, Lentz, Dieter
Format: Article
Language:English
Subjects:
Bonding
Catalysis
catalyst regeneration
Catalysts
Chemistry
density functional calculations
homogeneous catalysis
Hydrides
hydrodefluorination
Instability
metal hydride
Regeneration
Stability
Titanium
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creator Ehm, Christian
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Lentz, Dieter
description Despite their instability in ethereal solvents, organotitanium hydride catalysts are successfully employed in catalysis at moderate to high temperatures (110 °C), even in the presence of alcohols. It is shown computationally (bond dissociation energy (BDE) analysis and energetic profile for regeneration) and experimentally (EPR studies and kinetic studies), with the specific example of hydrodefluorination (HDF), that despite the long standing belief, regeneration of Ti−H bonds from Ti−F bonds using silanes is endergonic. The resulting low concentration of Ti−H species is crucial for the catalytic stability of those systems. The resting state in the catalysis is a Ti−F species. The most promising silanes for regeneration are not the ones that have the strongest Si−F bond, but the ones that show the largest difference in Si−F and Si−H BDEs. Organotitanium hydride catalysts: It has been shown that, despite their instability in ethereal solvents, organotitanium hydride compounds are successfully employed in catalysis at moderate to high temperatures.
doi_str_mv 10.1002/chem.201601641
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subjects Bonding
Catalysis
catalyst regeneration
Catalysts
Chemistry
density functional calculations
homogeneous catalysis
Hydrides
hydrodefluorination
Instability
metal hydride
Regeneration
Stability
Titanium
title How a Thermally Unstable Metal Hydrido Complex Can Yield High Catalytic Activity Even at Elevated Temperatures
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