Michael Renz

Bio: Michael Renz is an academic researcher from Polytechnic University of Valencia. The author has contributed to research in topics: Catalysis & Lewis acids and bases. The author has an hindex of 33, co-authored 86 publications receiving 5070 citations. Previous affiliations of Michael Renz include European Synchrotron Radiation Facility & Centre national de la recherche scientifique.

Sn-zeolite beta as a heterogeneous chemoselective catalyst for Baeyer – Villiger oxidations

Abstract: The Baeyer-Villiger oxidation, first reported more than 100 years ago, has evolved into a versatile reaction widely used to convert ketones-readily available building blocks in organic chemistry-into more complex and valuable esters and lactones Catalytic versions of the Baeyer-Villiger oxidation are particularly attractive for practical applications, because catalytic transformations simplify processing conditions while minimizing reactant use as well as waste production Further benefits are expected from replacing peracids, the traditionally used oxidant, by cheaper and less polluting hydrogen peroxide Dissolved platinum complexes and solid acids, such as zeolites or sulphonated resins, efficiently activate ketone oxidation by hydrogen peroxide But these catalysts lack sufficient selectivity for the desired product if the starting material contains functional groups other than the ketone group; they perform especially poorly in the presence of carbon-carbon double bonds Here we show that upon incorporation of 16 weight per cent tin into its framework, zeolite beta acts as an efficient and stable heterogeneous catalyst for the Baeyer-Villiger oxidation of saturated as well as unsaturated ketones by hydrogen peroxide, with the desired lactones forming more than 98% of the reaction products We ascribe this high selectivity to direct activation of the ketone group, whereas other catalysts first activate hydrogen peroxide, which can then interact with the ketone group as well as other functional groups

Production of High-Quality Diesel from Biomass Waste Products

Abstract: This work was supported by Consilider Ingenio 2009 CDS 00050. O.d.l.T. is grateful to the Spanish Ministry of Science and Innovation for a doctoral grant (FPU). We also thank E. Ponce and Dr. D. Penno for discussions and technical assistance.

Chemical Routes for the Transformation of Biomass into Chemicals

Abstract: 3.2.3. Hydroformylation 2467 3.2.4. Dimerization 2468 3.2.5. Oxidative Cleavage and Ozonolysis 2469 3.2.6. Metathesis 2470 4. Terpenes 2472 4.1. Pinene 2472 4.1.1. Isomerization: R-Pinene 2472 4.1.2. Epoxidation of R-Pinene 2475 4.1.3. Isomerization of R-Pinene Oxide 2477 4.1.4. Hydration of R-Pinene: R-Terpineol 2478 4.1.5. Dehydroisomerization 2479 4.2. Limonene 2480 4.2.1. Isomerization 2480 4.2.2. Epoxidation: Limonene Oxide 2480 4.2.3. Isomerization of Limonene Oxide 2481 4.2.4. Dehydroisomerization of Limonene and Terpenes To Produce Cymene 2481

Ordered porous materials for emerging applications

Abstract: "Space—the final frontier." This preamble to a well-known television series captures the challenge encountered not only in space travel adventures, but also in the field of porous materials, which aims to control the size, shape and uniformity of the porous space and the atoms and molecules that define it. The past decade has seen significant advances in the ability to fabricate new porous solids with ordered structures from a wide range of different materials. This has resulted in materials with unusual properties and broadened their application range beyond the traditional use as catalysts and adsorbents. In fact, porous materials now seem set to contribute to developments in areas ranging from microelectronics to medical diagnosis.

Engineering Metal Organic Frameworks for Heterogeneous Catalysis

Abstract: 2.2. MOFs with Metal Active Sites 4614 2.2.1. Early Studies 4614 2.2.2. Hydrogenation Reactions 4618 2.2.3. Oxidation of Organic Substrates 4620 2.2.4. CO Oxidation to CO2 4626 2.2.5. Phototocatalysis by MOFs 4627 2.2.6. Carbonyl Cyanosilylation 4630 2.2.7. Hydrodesulfurization 4631 2.2.8. Other Reactions 4632 2.3. MOFs with Reactive Functional Groups 4634 2.4. MOFs as Host Matrices or Nanometric Reaction Cavities 4636

Mechanism of oxidation reactions catalyzed by cytochrome p450 enzymes.

Abstract: ion phase that leads to an alkyl radical coordinated to the iron-hydroxo complex by a weak OH---C hydrogen bond, labeled as CI; (ii) an alkyl (or OH) rotation phase whereby the alkyl group achieves a favorable orientation for rebound; and (iii) a rebound phase that leads to C-O bond making and the ferric-alcohol complexes, 4,2P. The two profiles remain close in energy throughout the first two phases and then bifurcate. Whereas the HS state exhibits a significant barrier and a genuine TS for rebound, in the LS state, once the right orientation of the alkyl group is achieved, the LS rebound proceeds in a virtually barrier-free fashion to the alcohol. As such, alkane hydroxylation proceeds by TSR,70-72,120 in which the HS mechanism is truly stepwise with a finite lifetime for the radical intermediate, whereas the LS mechanism is effectively concerted with an ultrashort lifetime for the radical intermediate. Subsequent studies of ethane and camphor hydroxylation by the Yoshizawa group117,181-183 arrived at basically the same conclusion, that the mechanism is typified by TSR. The differences between the results of Shaik et al.130,173,177-180 and Yoshizawa et al.117,181-183 were rationalized recently71,72 and shown to arise owing to technical problems and the choice of the mercaptide ligand,117,181-183 which is a powerful electron donor and is too far from the representation of cysteine in the protein environment. The most recent study of camphor hydroxylation, which was done at a higher quality,117 converged to the picture reported by Shaik et al.130,173,177-180 and shows a stepwise HS process with a barrier of more than 3 kcal/mol for C-O bond formation by rebound of the camphoryl radical vis-à-vis an effectively concerted LS process for which this barrier is 0.7 kcal mol-1 and is the rotational barrier for reaching the rebound position. By referring to Figure 21, it is possible to rationalize the clock data of Newcomb in a simple manner. The apparent lifetimes are based on the assumption that there is a single state that leads to the reaction, such that the radical lifetime can be quantitated from the rate constant of free radical rearrangement and the ratio of rearranged to unrearranged alcohol product. However, in TSR, the rearranged (R) product is formed only/mainly on the HS surface, while the unrearranged (U) product is formed mainly on Figure 20. Formal descriptions of iron(III)-peroxo, iron(III)-hydroperoxo, and iron(V)-oxo species with indication of the negative charges. The roles “electrophile” or “nucleophile” are assigned according to the charge type. Reprinted with permission from ref 7. Copyright 2000 Springer-Verlag Heidelberg. 3964 Chemical Reviews, 2004, Vol. 104, No. 9 Meunier et al.