Oxydation photocatalytique de composés organiques volatils et suivi de leurs intermédiaires réactionnels : étude en réacteurs statique et dynamique à des concentrations typiques de l'air intérieur / Photocatalytic oxidation of volatile organic compounds and monitor of their reaction intermediates : investigation of static and dynamic reactors at typical concentrations of indoor air

Debono, Olivier

15 December 2011

La photocatalyse hétérogène est une technique d’oxydation utilisée pour l’élimination des Composés Organiques Volatils (COV). L’objectif est d’étudier la dégradation des COV initiaux et la production d’intermédiaires réactionnels lors de la mise en oeuvre de ce procédé dans des conditions proches de l’air intérieur (concentration des COV en mélange). TroisCOV modèles (toluène, décane, trichloréthylène) sont étudiés séparément puis en mélange dans un réacteurstatique puis dans un réacteur dynamique multi-pass. Les résultats obtenus montrent que (i) l’efficacité dedégradation dépend de la nature et du nombre de COV à traiter, des caractéristiques du média photocatalytiqueet des conditions opératoires, (ii) les intermédiaires majoritaires et les plus persistants sont les aldéhydeslégers, (iii) l’élimination des aldéhydes est inhibée lorsque les COV initiaux sont en mélange, (iv) l’augmentation du temps de résidence sur le matériau photocatalytique permet une élimination plus rapide des COV initiaux et des sous-produits. / Heterogeneous photocatalysis is a technique of oxidation used for the removal of Volatile Organic Compounds (VOCs). Aim is to study the degradation of initial VOCs and the production of reaction intermediates during this process in conditions close to the indoor air (VOC concentration in mixture). Three model VOCs (toluene, decane, trichloroethylene) are studied separately and then in mixture in a static reactor and in a dynamic multi-pass reactor. The obtained results show that (i) the degradation efficiency depends on the nature and the number of VOCs, on the photocatalyst characteristics and on process conditions, (ii) the major and the most persistent intermediates are light aldehydes, (iii) the elimination of aldehydes is inhibited when the initial VOCs are in mixture, (iv) increasing the residence time on the photocatalyst provides a higher removal rate of initial VOCs and of byproducts.

Photocatalyse

Traitement de l’air intérieur

Composés organiques volatils

Ppb

Intermédiaires réactionnels

Photocatalysis

Indoor air treatment

Volatile organic compounds

Ppb

Reaction intermediates

Efekt stříbra v homogenní zlaté katalýze / Effect of silver in homogeneous gold catalysis

Motloch, Petr

January 2014

Gold catalysis has recently experienced a sustained upswing in interest from scientific community. The amount of new reactions catalysed by gold is so significant that little is known about mechanisms of most of these reactions. Research into mechanisms of (not only) gold catalysed reactions is therefore very significant area of interest and important to the continued improvement of gold catalysed reactions. Formation of cationic π-complexes is considered a first mechanistic step in reactions catalysed by gold(I). The bond dissociation energies of gas phase cationic π-complexes were investigated by mass spectrometry and theory calculations in this thesis. These complexes consisted of differently substituted unsaturated hydrocarbons (alkenes, alkynes, alkadienes and allenes) and complex cations of silver and gold containing second ligand (triphenylphosphine, acetonitrile). On the basis of the results obtained from this study, a possible origin of the "silver effect" in gold(I) catalysis is discussed. Key words catalysis, gold, silver, mass spectrometry, DFT calculations, reaction intermediates

Catalyzed hydrogenation of nitrogen and ethylene on metal (Fe, Pt) single crystal surfaces and effects of coadsorption A sum frequency generation vibrational spectroscopy study.

Westerberg, Staffan Per Gustav

January 2004

Thesis (Ph.D.); Submitted to the University of California, Berkeley, Berkeley, California (US); 15 Dec 2004. / Published through the Information Bridge: DOE Scientific and Technical Information. "LBNL--56814" Westerberg, Staffan Per Gustav. USDOE Director. Office of Science. Office of Basic Energy Sciences (US) 12/15/2004. Report is also available in paper and microfiche from NTIS.

Metal catalysed alkylation of carbonyl compounds with formaldehyde

Lorusso, Patrizia

January 2015

Formaldehyde is a chemical used widely in the manufacture of building materials. A remarkable example is represented by the Lucite two-step Alpha technology for the large scale production of methyl methacrylate (MMA), the essential building block of all acrylic-based products. Esters and ketones are important intermediates in the manufacture of acrylate esters therefore α-hydroxymethylenation of carbonyl compounds using formaldehyde as a one carbon alkylating agent and subsequent dehydration to the corresponding methylenated derivatives has been explored in the current work. We report a novel catalytic approach for the synthesis of methyl methacrylate (MMA) via one-pot α-methylenation of methyl propanoate (a chemical intermediate of the ALPHA process) with formaldehyde, generated in situ by Ru-catalysed dehydrogenation of methanol. Elucidation of the mechanism involved in the catalytic dehydrogenation of methanol along with the collateral alcohol decarbonylation reaction was gained through a combined experimental and DFT study. The development of an alternative process where anhydrous formaldehyde is produced in situ would provide a simplification over the current second step of the ALPHA technology where the formaldehyde is initially produced as formalin, subsequently dehydrated to afford anhydrous formaldehyde in order to ensure high selectivity to MMA. As an alternative approach, ketones, in particular 3-pentanone and 2-butanone, were targeted as potential substrates in order to overcome some of the problems related to competing reactions that occur at the ester group. Hydroxymethylenation, followed by dehydration and Baeyer-Villager oxidation, possibly catalysed by enzymes to reverse the normal selectivity, leads to the formation of acrylate esters. The catalytic reaction is enabled by a gold carbene hydroxide complex in such a way that the substrate undergoes C-H activation and the nascent metal alkyl acts as a nucleophile towards the electrophilic formaldehyde, supplied in the form of alcoform* (solution of paraformaldehyde in methanol).

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