Your search keyword '"Ive Hermans"' showing total 6 results

1. Enhancing the Deperoxidation Activity of Cobalt(II)Acetylacetonate by the Addition of Octanoic Acid

Author

Ive Hermans and Eyal Spier

Subjects

inorganic chemicals, Kinetics, chemistry.chemical_element, Homogeneous catalysis, Photochemistry, Atomic and Molecular Physics, and Optics, Catalysis, Homolysis, chemistry, Catalytic cycle, Polymer chemistry, Physical and Theoretical Chemistry, Cobalt, Bond cleavage

Abstract

The homolytic scission of peroxides with catalytic amounts of cobalt(II) complexes is used in several industrial oxidation processes. In this contribution, we report that addition of small amounts of octanoic acid significantly enhances the catalytic deperoxidation activity of the cobalt(II)acetylacetonate complex. We attribute this to the stabilization of the Co--OOR bond upon coordination of octanoic acid, preventing the unimolecular scission. As such, the cobalt peroxo intermediate is forced to enter an alternative catalytic cycle which causes its rapid conversion to the highly reactive cobalt hydroxy. This shift in catalytic cycle results in a higher pre-exponential rate factor, over-compensating the higher barrier of the new rate-determining step.

Published

2013

2. Molecule-Induced Peroxide Homolysis

Author

Natascia Turrà, Ive Hermans, and Ulrich Neuenschwander

Subjects

chemistry.chemical_classification, Free Radicals, Radical, Temperature, chemistry.chemical_element, Photochemistry, Peroxide, Oxygen, Hydrocarbons, Atomic and Molecular Physics, and Optics, Dissociation (chemistry), Peroxides, Homolysis, Kinetics, chemistry.chemical_compound, chemistry, Molecule, Physical and Theoretical Chemistry, Oxidation-Reduction, Algorithms, Alkyl, Bond cleavage

Abstract

The homolytic cleavage of peroxide bonds, leading to the formation of free radicals, plays an important role in the (spontaneous) oxidation of a wide variety of hydrocarbons in the presence of oxygen. Such aerobic oxidations can be desired (e.g. for industrially applied autoxidations) or undesired (e.g. food deterioration). In this contribution we provide experimental and computational evidence for a molecule-induced homolytic dissociation mechanism between alkyl peroxide and compounds featuring weakly bonded H atoms such as (di)unsaturated hydrocarbons.

Published

2013

3. Enhanced Activity and Selectivity in Cyclohexane Autoxidation by Inert H-Bond Acceptor Catalysts

Author

Pierre Jacobs, Ive Hermans, and Jozef Peeters

Subjects

chemistry.chemical_compound, Cycloalkane, Autoxidation, Cyclohexane, chemistry, Radical, Cyclohexanol, Cyclohexanone, Physical and Theoretical Chemistry, Photochemistry, Beta scission, Atomic and Molecular Physics, and Optics, Catalysis

Abstract

Herein, we demonstrate that the chain-initiating dissociation of cyclohexyl hydroperoxide, CyOOH, is substantially accelerated by H-bond acceptors (e.g. Teflon), which assist O-O bond breaking by stabilising the leaving *OH radical. This is a completely new approach to boost the chain-propagating radical concentration. Indeed, up to now, literature has remained focussed on transition metal catalysis. In addition to this initiation effect, we demonstrate how inert perfluorinated compounds are also able to steer the selectivity at the molecular level, by promoting the conversion of the intermediate cyclohexyl hydroperoxide to the most desired end-product, cyclohexanone. This effect is explained by an enhanced, H-bond-assisted, hydroperoxide propagation. This hitherto overlooked hydroperoxide propagation was recently presented by us as the dominant cyclohexanone and cyclohexanol source. We herein thus confirm our previously reported autoxidation scheme, and illustrate its usefulness as a solid basis for designing new catalytic systems.

Published

2006

4. Autoxidation of Cyclohexane: Conventional Views Challenged by Theory and Experiment

Author

Pierre Jacobs, Jozef Peeters, Thanh Lam Nguyen, and Ive Hermans

Subjects

chemistry.chemical_classification, Chain propagation, Ketone, Cyclohexane, Cyclohexanol, Free-radical reaction, Cyclohexanone, Hydrogen atom abstraction, Photochemistry, Atomic and Molecular Physics, and Optics, Reaction rate, chemistry.chemical_compound, chemistry, Physical and Theoretical Chemistry

Abstract

In spite of its industrial importance, the detailed reaction mechanism of cyclohexane autoxidation by O2 is still insufficiently known. Based on quantum chemical potential energy surfaces, rate coefficients of the primary and secondary chain propagation steps involving the cyclohexylperoxyl (CyOO) radical were evaluated using multiconformer transition-state theory. Including tunneling and hindered-internal-rotation effects, the rate coefficient for hydrogen-atom abstraction from cyclohexane (CyH) by CyOO was calculated to be k(T)= 1.46 x 10(-11) x exp(-17.8 kcal mol(-1)/ RT) cm3s(-1) (300-600K), close to the experimental data. A "Franck-Rabinowitch cage" reaction between the nascent cyclohexylhydroperoxide (CyOOH) and cyclohexyl radical, products from CyOO + CyH, is put forward as an initially important cyclohexanol (CyOH) formation channel. alphaH abstraction by CyOO. from cyclohexanone was calculated to be only about five times faster than that from CyH, too slow to explain all the observed side products. The a-hydrogen (alphaH) abstractions from CyOH and CyOOH by CyOO. are predicted to be about 10 and 40 times faster, respectively, than the CyOO. +CyH reaction. The very fast CyOO.+CyOOH reaction proceeds through the unstable Cy-alphaH .OOH radical that decomposes spontaneously into the ketone (Q=O) plus the OH radical; the "hot" .OH is found to produce the bulk of the alcohol via a second, "activated cage" reaction analogous to that above. It is thus shown how the very reactive CyOOH intermediate is the predominant source of ketone and alcohol, while it also leads to some side products. The alpha-hydroxycyclohexylperoxyl radical formed during the moderately fast oxidation of CyOH is shown to decompose fast into HO2 + cyclohexanone in a rapidly equilibrated reaction, which constitutes a smaller, second ketone source. These two fast cyclohexanone forming routes avoid the need for unfavorable molecular routes hitherto invoked as ketone sources. The theoretical predictions are supported and complemented by experimental findings. The newly proposed scheme is also largely applicable to the oxidation of other hydrocarbons, such as toluene, xylene, and ethylbenzene.

Published

2005

5. Enhanced Activity and Selectivity in Cyclohexane Autoxidation by Inert H-Bond Acceptor Catalysts.

Author

Ive Hermans, Jozef Peeters, and Pierre A. Jacobs

Published

2006

6. Autoxidation of Cyclohexane: Conventional Views Challenged by Theory and Experiment.

Author

Ive Hermans, Thanh Lam Nguyen, Pierre A. Jacobs, and Jozef Peeters

Published

2005