Glucose oxidation on different electrocatalysts mechanisms and sensor applications /

Lam, Chung-man.

January 2000

Thesis (M. Phil.)--University of Hong Kong, 2001. / Includes bibliographical references.

Carbon monoxide oxidation on nanoparticle catalysis and gas phase reactions of small molecules and volatile organics with metal cations /

Saoud, Khaled Mohammad,

January 2004

Thesis (Ph. D.)--Virginia Commonwealth University, 2004. / Prepared for: Dept. of Chemistry . Bibliography: leaves 272 - 286 . Also available online via the Internet.

Alkane Oxidation Catalysis by Homogeneous and Heterogeneous Catalyst

Guo, Chris

January 2005

Abstract Cobalt-based complexes are widely used in industry and organic synthesis as catalysts for the oxidation of hydrocarbons. The Co/Mn/Br (known as "CAB system") catalyst system is effective for the oxidation of toluene. The Co/Mn/Br/Zr catalyst system is powerful for the oxidation of p-xylene, but not for the oxidation of toluene. [Co3O(OAc)5(OH)(py)3][PF6] (Co 3+ trimer 5) is more effective than [Co3O(OAc)6(py)3][PF6] (Co 3+ trimer 6) as a catalyst in the CAB catalyst system. Higher temperatures favour the oxidation of toluene. Zr 4+ does not enhance the oxidation of toluene. Zr 4+ could inhibit the oxidation of toluene in the combination of Co/Br/Zr, Co/Mn/Zr or Co/Zr. NHPI enhances the formation of benzyl alcohol, but the formation of other by-products is a problem for industrial processes. Complex(es) between cobalt, manganese and zirconium might be formed during the catalytic reaction. However, attempts at the preparation of complexes consisting of Co/Zr or Mn/Zr or Co3ZrP or Co8Zr4 clusters failed. The oxidation of cyclohexane to cyclohexanone and cyclohexanol is of great industrial significance. For the homogeneous catalysis at 50 o C and 3 bar N2 pressure, the activity order is: Mn(OAc)3 �2H2O > Mn12O12 cluster > Co 3+ trimer 6 > [Co3O(OAc)3(OH)2(py)5][PF6]2 (Co 3+ trimer 3) > Co 3+ trimer 5 > Co(OAc)2 �4H2O > [Co2(OAc)3(OH)2(py)4][PF6]-asym (Co dimerasym) > [Co2(OAc)3(OH)2(py)4][PF6]-sym (Co dimersym); whereas [Mn2CoO(OAc)6(py)3]�HOAc (Mn2Co complex) and zirconium(IV) acetate hydroxide showed almost no activity under these conditions. But at 120 o C and 3 bar N2 pressure, the activity order is changed to: Co dimerasym > Co(OAc)2 �4H2O > Co trimer 3 and Mn(OAc)3 �2H2O > Co 3+ trimer 6 > Mn2Co complex > Co 3+ trimer 5 > Co dimersym > Mn12O12 cluster. The molar ratio of the products was close to cyclohexanol/cyclohexanone=2/1. Mn(II) acetate and zirconium(IV) acetate hydroxide showed almost no activity under these conditions. Among those cobalt dimers and trimers, only the cobalt dimerasym survived after the stability tests, this means that [Co2(OAc)3(OH)2(py)4][PF6]-asym might be the active form for cobalt(II) acetate in the CAB system. Metal-substituted (silico)aluminophosphate-5 molecular sieves (MeAPO-5 and MeSAPO-5) are important heterogeneous catalysts for the oxidation of cyclohexane. The preparation of MeAPO-5 and MeSAPO-5 and their catalytic activities were studied. Pure MeAPO-5 and MeSAPO-5 are obtained and characterised. Four new pairs of bimetal-substituted MeAPO-5 and MeSAPO-5(CoZr, MnZr, CrZr and MnCo) were prepared successfully. Two novel trimetal-subtituted MeAPO-5 and MeSAPO-5 (MnCoZr) are reported here. Improved methods for the preparation of four monometal-substituted MeAPO-5 (Cr, Co, Mn and Zr) and for CoCe(S)APO-5 and CrCe(S)APO-5 are reported. Novel combinational mixing conditions for the formation of gel mixtures for Me(S)APO-5 syntheses have been developed. For the oxidation of cyclohexane by TBHP catalysed by MeAPO-5 and MeSAPO-5 materials, CrZrSAPO-5 is the only active MeSAPO-5 catalyst among those materials tested under conditions of refluxing in cyclohexane. Of the MeAPO-5 materials tested, whereas CrCeSAPO-5 has very little activity, CrZrAPO-5 and CrCeAPO-5 are very active catalysts under conditions of refluxing in cyclohexane. MnCoAPO-5, MnZrAPO-5 and CrAPO-5 are also active. When Cr is in the catalyst system, the product distribution is always cyclohexanone/cyclohexanol equals 2-3)/1, compared with 1/2 for other catalysts. For MeAPO-5, the activity at 150 o C and 10 bar N2 pressure is: CrZrAPO-5 > CrCeAPO-5 > CoZrAPO-5. For MeAPO-5 and MeSAPO-5, at 150 o C and 13 bar N2 pressure, the selectivity towards cyclohexanone is: CrZrAPO-5 > CrZrSAPO-5 > CrCeAPO-5 > CrAPO-5 > MnCoAPO-5 > MnZrAPO-5; and the selectivity towards cyclohexanol is: MnZrAPO-5 > CrZrAPO-5 > MnCoAPO-5 > CrZrSAPO-5 > CrCeAPO-5 > CrAPO-5. Overall the selectivity towards the oxidation of cyclohexane is: CrZrAPO-5 > CrZrSAPO-5 > CrCeAPO-5 > CrAPO-5 > MnCoAPO-5 > MnZrAPO-5. The amount of water in the system can affect the performance of CrCeAPO-5, but has almost no effect on CrZrAPO-5. Metal leaching is another concern in potential industrial applications of MeAPO-5 and MeSAPO-5 catalysts. The heterogeneous catalysts prepared in the present work showed very little metal leaching. This feature, coupled with the good selectivities and effectivities, makes them potentially very useful.

Alkane Oxidation Catalysis by Homogeneous and Heterogeneous Catalyst

Guo, Chris

January 2005

Abstract Cobalt-based complexes are widely used in industry and organic synthesis as catalysts for the oxidation of hydrocarbons. The Co/Mn/Br (known as "CAB system") catalyst system is effective for the oxidation of toluene. The Co/Mn/Br/Zr catalyst system is powerful for the oxidation of p-xylene, but not for the oxidation of toluene. [Co3O(OAc)5(OH)(py)3][PF6] (Co 3+ trimer 5) is more effective than [Co3O(OAc)6(py)3][PF6] (Co 3+ trimer 6) as a catalyst in the CAB catalyst system. Higher temperatures favour the oxidation of toluene. Zr 4+ does not enhance the oxidation of toluene. Zr 4+ could inhibit the oxidation of toluene in the combination of Co/Br/Zr, Co/Mn/Zr or Co/Zr. NHPI enhances the formation of benzyl alcohol, but the formation of other by-products is a problem for industrial processes. Complex(es) between cobalt, manganese and zirconium might be formed during the catalytic reaction. However, attempts at the preparation of complexes consisting of Co/Zr or Mn/Zr or Co3ZrP or Co8Zr4 clusters failed. The oxidation of cyclohexane to cyclohexanone and cyclohexanol is of great industrial significance. For the homogeneous catalysis at 50 o C and 3 bar N2 pressure, the activity order is: Mn(OAc)3 �2H2O > Mn12O12 cluster > Co 3+ trimer 6 > [Co3O(OAc)3(OH)2(py)5][PF6]2 (Co 3+ trimer 3) > Co 3+ trimer 5 > Co(OAc)2 �4H2O > [Co2(OAc)3(OH)2(py)4][PF6]-asym (Co dimerasym) > [Co2(OAc)3(OH)2(py)4][PF6]-sym (Co dimersym); whereas [Mn2CoO(OAc)6(py)3]�HOAc (Mn2Co complex) and zirconium(IV) acetate hydroxide showed almost no activity under these conditions. But at 120 o C and 3 bar N2 pressure, the activity order is changed to: Co dimerasym > Co(OAc)2 �4H2O > Co trimer 3 and Mn(OAc)3 �2H2O > Co 3+ trimer 6 > Mn2Co complex > Co 3+ trimer 5 > Co dimersym > Mn12O12 cluster. The molar ratio of the products was close to cyclohexanol/cyclohexanone=2/1. Mn(II) acetate and zirconium(IV) acetate hydroxide showed almost no activity under these conditions. Among those cobalt dimers and trimers, only the cobalt dimerasym survived after the stability tests, this means that [Co2(OAc)3(OH)2(py)4][PF6]-asym might be the active form for cobalt(II) acetate in the CAB system. Metal-substituted (silico)aluminophosphate-5 molecular sieves (MeAPO-5 and MeSAPO-5) are important heterogeneous catalysts for the oxidation of cyclohexane. The preparation of MeAPO-5 and MeSAPO-5 and their catalytic activities were studied. Pure MeAPO-5 and MeSAPO-5 are obtained and characterised. Four new pairs of bimetal-substituted MeAPO-5 and MeSAPO-5(CoZr, MnZr, CrZr and MnCo) were prepared successfully. Two novel trimetal-subtituted MeAPO-5 and MeSAPO-5 (MnCoZr) are reported here. Improved methods for the preparation of four monometal-substituted MeAPO-5 (Cr, Co, Mn and Zr) and for CoCe(S)APO-5 and CrCe(S)APO-5 are reported. Novel combinational mixing conditions for the formation of gel mixtures for Me(S)APO-5 syntheses have been developed. For the oxidation of cyclohexane by TBHP catalysed by MeAPO-5 and MeSAPO-5 materials, CrZrSAPO-5 is the only active MeSAPO-5 catalyst among those materials tested under conditions of refluxing in cyclohexane. Of the MeAPO-5 materials tested, whereas CrCeSAPO-5 has very little activity, CrZrAPO-5 and CrCeAPO-5 are very active catalysts under conditions of refluxing in cyclohexane. MnCoAPO-5, MnZrAPO-5 and CrAPO-5 are also active. When Cr is in the catalyst system, the product distribution is always cyclohexanone/cyclohexanol equals 2-3)/1, compared with 1/2 for other catalysts. For MeAPO-5, the activity at 150 o C and 10 bar N2 pressure is: CrZrAPO-5 > CrCeAPO-5 > CoZrAPO-5. For MeAPO-5 and MeSAPO-5, at 150 o C and 13 bar N2 pressure, the selectivity towards cyclohexanone is: CrZrAPO-5 > CrZrSAPO-5 > CrCeAPO-5 > CrAPO-5 > MnCoAPO-5 > MnZrAPO-5; and the selectivity towards cyclohexanol is: MnZrAPO-5 > CrZrAPO-5 > MnCoAPO-5 > CrZrSAPO-5 > CrCeAPO-5 > CrAPO-5. Overall the selectivity towards the oxidation of cyclohexane is: CrZrAPO-5 > CrZrSAPO-5 > CrCeAPO-5 > CrAPO-5 > MnCoAPO-5 > MnZrAPO-5. The amount of water in the system can affect the performance of CrCeAPO-5, but has almost no effect on CrZrAPO-5. Metal leaching is another concern in potential industrial applications of MeAPO-5 and MeSAPO-5 catalysts. The heterogeneous catalysts prepared in the present work showed very little metal leaching. This feature, coupled with the good selectivities and effectivities, makes them potentially very useful.

The oxidation of carbon monoxide catalyzed by nitrogen dioxide ...

Roehling, Otto Carl,

January 1935

Thesis (Ph. D.)--Columbia University, 1935. / Vita. Bibliography: p. [29].

Bioinspired dinuclear copper complexes for catalytic oxidation of phenolic substrates

Seeba, Marten

06 November 2017

No description available.

540

bioinorganic chemistry

copper catalysis

aerobic oxidation

oxidation catalysis

copper oxygen chemistry

Chemie  (PPN62138352X)

Synthèse de nouveaux catalyseurs nanostructurés par dépôts physiques à base de pérovskite de lanthane / New nanostructured catalysts with pérovskites of lanthanum obtained by processes of physical deposit

Vilasi, Pauline

20 December 2018

Ce travail de thèse est issu d’une collaboration entre les laboratoires de recherche FEMTO-ST de l’université technologique de Belfort-Montbéliard et IRCELYON de l’université Claude Bernard à Villeurbanne. Les objectifs de cette étude portent sur la faisabilité d’élaborer par pulvérisation cathodique magnétron des films minces de cobaltite de lanthane nanostructurés. En effet, ces films présentent des propriétés catalytiques intéressantes pour l’oxydation des composés organiques volatiles comme le propène (C3H6) ou le monoxyde de carbone (CO) qui constituent la principale source de pollution de l’air. Il sera montré dans un premier temps que les cobaltites de lanthane de formule LaCoO3 ne sont pas efficaces pour ce type d’application. La composition chimique de ce matériau sera donc modifiée en y incorporant de l’argent de manière à faire varier les propriétés physico-chimiques des films et d’augmenter leurs performances catalytiques. La morphologie des films est directement impactée par l’introduction de Ag puisqu’elle évolue d’un système dense à un système « nanofilaire ». Une autre série de dépôts sera également élaborée et testée en catalyse constituée de cobaltites de lanthane dopées avec de l’argent mais aussi du cérium. On retiendra alors que les films de LaCoO3 + Ag sont plutôt efficaces et prometteurs puisqu’ils présentent des performances catalytiques se rapprochant de celles du platine (catalyseur de référence). Néanmoins, bien que les films aient toujours cette morphologie nanofilaire, les compositions chimiques des films élaborés à base de LaCoO3 + Ag + Ce doivent être optimisées afin d’augmenter leurs activités catalytiques. / This work was made in the frame of a scientific research relationships between the laboratory FEMTO-ST of the Technological University of Belfort-Montbéliard and the laboratory IRCELYON of the Claude Bernard University of Villeurbanne. This study aims at characterizing the feasibility of nanostructured lanthanum cobaltite thin films via magnetron sputtering. Indeed, it is well known these materials have interesting catalytic properties regarding the oxidation of volatile organic compounds such as propene (C3H6) or carbon monoxide (CO), the latter being the main source of air pollution. First, it has been shown that lanthanum cobaltites of formula LaCoO3 are not efficient for this type of application. The chemical composition of this material was then modified by incorporating silver so as to vary the physicochemical properties of the films and increase their catalytic performance. In consequence, the morphology of the films was directly impacted by the introduction of Ag since it evolved from a dense system to a "nanowire" system. Another series of deposits based on cobaltite modified by both silver and cerium additions have been also developed and tested during catalytic tests. It should be noted that the Ag containing thin films of LaCoO3 are rather efficient and then promising since they have catalytic performances close to those of platinum (the reference catalyst). Concerning the Ag and Ce containing perovskite films, although they still have this peculiar nanowired morphology, their chemical compositions have to be optimized in order to increase their catalytic activities.

Catalyse d'oxydation

Nanofils

Cobaltites de lanthane dopées

Cov

Doped lanthanum cobaltites

Nanowires

Voc

Oxidation catalysis

530

620

Theoretical Studies of Ru- and Re-based Catalysts for Artificial Photosynthesis

Stolper, Thorsten

08 December 2017

No description available.

540

Artificial Photosynthesis

Computational Chemistry

Water Oxidation Catalysis

Carbon Dioxide Reduction

Geometry Optimization Algorithms

Chemie  (PPN62138352X)

Iminium Based Electrocaralysts for Water Oxidation and Organic Photohydrides for Proton Reduction

Walpita, Janitha Kumara

23 July 2015

No description available.

Chemistry

Organic Chemistry

Physical Chemistry

water oxidation catalysis

proton-coupled electron transfer

organic photohydrides

Iridacycles à chiralité planaire : concepts, synthèses et applications / Planar chiral iridacycles : concepts, synthesis and applications

Iali, Wissam Nabil

16 October 2012

L’un des axes de recherche du laboratoire Synthèse Métallo-Induites consiste en le développement de nouveaux complexes métallacycliques à chiralité planaire. Le défi majeur de cette thèse, a été l’élaboration de nouvelles approches sélectives de synthèse de complexes cationiques et neutres métallacyliques à chiralité planaire dont le métal chélaté est un centrestéréogène pseudo-tétraédrique.Le projet de thèse fut initié lors de l’étude d’une réaction inhabituelle de cycloruthénation d’un ligand dérivé de la 2-phénylpyridine qui était capable de produire un complexe ruthénacyclique OC-6 triscationique, homobinucléaire et à chiralité planaire comme produit secondaire en une seule étape à partir de substrats simples. Ce type de produit homobinucléaire ne peut se former uniquement que lorsqu’un groupement fortement donneur comme le N,N-diméthylamino (-NMe2) est présent sur le ligand départ. C’est donc à la lumière de ce résultat que nous avons engagé une étude systématique de la synthèse de nouveaux composés iridacycliques à chiralité planaire. Les fragments métalliques positivement chargés (Cp*Ir2+, Cp*Ru+) et neutre (Cr(CO)3) pourraient p-coordiner un fragment aryle riche en électrons d’un composé cyclométallé suivant un cours stéréochimiqueconditionné par la nature des entités ainsi introduites. Une des conséquences inattendues de ces recherches est l’émergence du concept de chiralité constitutionnelle déportée qui a surgi lors de l’étude du comportement conformationnel du complexe endo dicationique IrIr(NMe2) dont les groupes méthyles portés par le substituant N,N-diméthylamino dénotent une diastéréotopicité remarquable en spectroscopie de RMN 1H.A cette quête fondamentale de sélectivité s’est aussi greffée une exploration des propriétés catalytiques de nos complexes qui se sont révélés comme d’excellents précatalyseurs pour la promotion de réactions comme l’oxydation de l’eau et l’hydroamination/hydrosilylation d’alcynes vrais. / One of the main research domain in the laboratory of «Synthèse Metallo-Induites» consists in the development of new planar chiral metallacycles complexes. The challenge of this thesis was the development of new selective approaches for the synthesis of new cationic and neutral planar chiral metallacycles complexes in which the chelated metal is a pseudotetrahedral stereogenic center.The thesis project was initiated by the study of the unusual cycloruthenation of a 2-phenylpyridine ligand which was able to produce a tris-cationic homobimetallic planar chiral ruthenacycle as secondary product in a one step reaction starting from simple substrates. This type of homobimetallic product is only formed when a strong electrodonationg group as NMe2 is present on the starting ligand. In view of this result, we engaged a systematic study by synthesizing new planar chiral iridacycles compounds. The positively charged metal fragments (Cp*Ir2+, Cp*Ru+) and neutral (Cr(CO)3) may p-coordinate the electronic rich aryl fragment of the iridacyclic compound by virtue of the coulombic imbalance in the coordination sphere of the chelated metal center. One of the unexpected consequence of this research is the emergence of the concept ″deported constitutional chirality″, which appeared during the study of the conformational behaviour of an endodicationiciridacyclic complex where the methyl groups carried by the N,N-dimethylamino substituent diastereotopicity.To this fundamental quest for selectivity an explanation of the catalytic proprieties of our complexes was added. They were found to be good precatalysts for the promotion of the water oxidation catalysis and to be promising catalysts for tandem hydroamination/hydrosilation of terminal alkynes.

Chiralité planaire

Cyclométallation

P-coordination

Iridium

Hydroamination

Hydrosilylation/protodésilylation

Oxydation de l’eau

Planar chirality

Cyclometallation

P-coordination

Iridium

Hydroamination

Hydrosilation/protodesilation

Water oxidation catalysis

541.39

547.2