Catalysts For Oxidation Of Hydrocarbons Research Articles

98/00293 Process and zirconia-supported catalysts for the catalytic partial oxidation of hydrocarbons to carbon monoxide and hydrogen

98/00293 Process and zirconia-supported catalysts for the catalytic partial oxidation of hydrocarbons to carbon monoxide and hydrogen

ChemInform Abstract: Vanadia Catalysts for Selective Oxidation of Hydrocarbons and Their Derivatives

AbstractChemInform is a weekly Abstracting Service, delivering concise information at a glance that was extracted from about 100 leading journals. To access a ChemInform Abstract of an article which was published elsewhere, please select a “Full Text” option. The original article is trackable via the “References” option.

Active centres on vanadia-based catalysts for selective oxidation of hydrocarbons

On the basis of the papers presented in this issue the structure of active centres for different steps of selective oxidation of hydrocarbons on vanadia-based catalysts has been discussed. The physicochemical properties of the vanadia-based catalysts, which control the selectivity to products of oxidative dehydrogenation vs. that to oxygenated products in the oxidation reactions, have also been considered.

Catalytic Oxidation of Ethylbenzene to Acetophenone Using Alumina-Supported Dichromate: Process Optimisation and Development of a Continuous Process

Potassium dichromate supported on neutral alumina is a heterogeneous catalyst for the liquid phase oxidation of hydrocarbons. The material has been used to catalyse the oxidation of ethylbenzene to acetophenone using air as the consumable oxidant with high selectivity and is truly catalytic in the metal, unlike homogeneous Cr(VI) systems. Optimisation of reaction conditions has been achieved in terms of air flow rate, agitator speed, and catalyst quantity. An induction period prior to achievement of maximum catalytic turnover, which is proportional to both temperature and the concentration of catalyst, may be reduced by doping the substrate with 5−15% acetophenone (w/w) and eliminated by doping with 30% (w/w) acetophenone. A rate of conversion of ca. 3.8% h-1 (0.39 turnover s-1) may be achieved at a reaction temperature of 130 °C for a period of ca. 10 h before catalyst deactivation occurs. However, this rate may be maintained for periods in excess of 24 h by continuous addition of substrate to the reacti...

XPD investigation of [formula omitted] anatase model catalysts

The system V 2 O 5 TiO 2 anatase is an important industrial catalyst for the partial oxidation of hydrocarbons. Model catalysts were prepared by depositing thin V 2O 5 layers upon clean anatase single crystal minerals by means of DC magnetron sputtering. XPD measurements were performed on the fresh structure, recording the Ti 2 p 3 2 , V 2 p 3 2 , O 1s and C 1s photoemission lines at 28° polar angle. The scans displayed a marked degree of symmetry and structure, which was interpreted on the basis of the experimental anatase XPD pattern. After a standard catalytic reaction the used model catalysts were re-examined by a similar XPD characterization.

ChemInform Abstract: 3d Transition‐Metal Oxide‐Stabilized Zirconia as Novel Catalysts for Complete Oxidation of Hydrocarbons.

AbstractChemInform is a weekly Abstracting Service, delivering concise information at a glance that was extracted from about 100 leading journals. To access a ChemInform Abstract of an article which was published elsewhere, please select a “Full Text” option. The original article is trackable via the “References” option.

The design and testing of an autothermal reactor for the conversion of light hydrocarbons to hydrogen I. The kinetics of the catalytic oxidation of light hydrocarbons

The catalytic oxidation of methane, ethane and propane on a Pt/δ-Al 2O 3 catalyst has been studied as part of the design of an autothermal reactor in which exothermic oxidation and endothermic steam reforming are combined. Light-off temperatures and the kinetics of oxidation of the hydrocarbons have been determined. The power rate law kinetics are found to approximate to first order in hydrocarbon and to show a negative order with respect to oxygen. The dependence of rate on oxygen pressure has been shown to be non-monotonic. The kinetics of methane oxidation is best described by a Langmuir-Hinshelwood model in which molecular adsorbed hydrocarbon reacts with adsorbed atomic oxygen. Pt-based catalysts are shown to be more active than Ni-based catalysts for hydrocarbon oxidation.

3d Transition-metal oxide-stabilized zirconia as novel catalysts for complete oxidation of hydrocarbons

A new series of zirconia based fluorite type oxides stabilized by Cr, Mn, Fe, Co or Ni are found to be active for complete oxidation of hydrocarbons.

Catalytic and physico-chemical properties of new schiff base complexes in zeolites

Abstract Adsorption of tetradentate Schiff base ligands on MnIINaY zeolites yields catalysts for selective oxidation of hydrocarbons with PhIO or tert-butylhydroperoxide (tBHP). The interaction between Mn and the ligands is proved by IR, diffuse reflectance and EPR spectroscopy. Olefin epoxidation with these catalysts suffers from formation of undesirable products when tBHP is used, but reasonable epoxide selectivities are obtained with PhIO. Very active catalysts for alkane oxidation with tBHP are produced by adsorption of the pyridine derived pyren and pyrpn ligands on MnIINaY (pyren = bis(2-pyridinecarboxaldehyde)ethylenediimine; pyrpn = bis(2-pyridinecarboxaldehyde)propylenediimine). With these catalysts, very high selectivities are obtained for formation of monoketones from alkanes. A relation is proposed between the appearance of low-field features in the Mn(II) EPR spectra and a high activity in hydrocarbon oxidation.

Molecular design of oxide catalysts for oxidation of hydrocarbons

Molecular design of oxide catalysts for oxidation of hydrocarbons

A binuclear manganese complex of a pyridoxal derivative and its use as an oxidation catalyst

A new binuclear complex of manganese, [Mn2L(OAc)2], where H3L = N,N′-[4(3-hydroxy-5-hydroxymethyl-2-methyl)pyridylmethylene]-1,3-diamionopropane-2-ol, was prepared and characterized by analysis and various spectral methods. The studies reveal that it is a mixed valence manganese(II)/manganese(III) complex with endogenous μ-oxo and exogenous μ-carboxylato bridges. The complex can be used as a catalyst for the selective oxidation of hydrocarbons (cyclohexene, cis-cyclooctene, styrene, norbornene and trans-4-octene) using terminal oxidant at ambient temperatures. The yields calculated on the basis of the oxidant concentrations indicate that the complex works as an efficient catalyst for the oxidation of hydrocarbons. A probable mechanism for the reaction is proposed.

Synthesis of an ultralarge pore titanium silicate isomorphous to MCM-41 and its application as a catalyst for selective oxidation of hydrocarbons

An ultralarge pore titanium silicate with MCM-41 structure has been prepared by direct hydrothermal synthesis; this material gives rise to useful catalysts for the selective oxidation of small and large organic compounds.

Characterization and activity of cobalt oxide catalysts for total oxidation of hydrocarbons

Characterization and activity of cobalt oxide catalysts for total oxidation of hydrocarbons

Characterization and activity of cobalt oxide catalysts for total oxidation of hydrocarbons

In view of the importance of catalytic combustion in the field of air pollution control, a study on the total oxidation of lean mixtures of hexane (approximately 0.5 mol%) in air was undertaken. Silica-supported cobalt oxide catalysts prepared by the impregnation of silica hydrogel by ammoniacal cobalt oxalate precursor effectively catalysed the total oxidation at 553 K. The dependence of the catalyst activity on the temperature and environment during decomposition was investigated. A low decomposition temperature and an inert environment yielded better activity of the catalysts. This has been explained with the help of the decomposition mechanism of cobalt oxalate and has been supported by estimating the particle size distribution by X-ray diffraction analysis.

Electrochemical characterization of manganese porphyrins fixed onto silica and layered dihydroxide matrices

Immobilization of metalloporphyrin catalysts on polymer and inorganic supports has been researched intensively in recent years. Methods being actively pursued at present are the electrochemical polymerization of a suitably designed pyrrole-substituted porphyrin [l-7], the chemical polymerization of readily available halogenated metalloporphyrins [8,9], and the fixation of the complexes by adsorption on silica or alumina [lo-121 and by ion-exchange reaction on clay minerals (i.e. montmorillonite) [12-161, zeolites [171, layered dihydroxides [10,18,191 and ion-exchange resins [20-221. In the case of manganese porphyrins, these new supported catalysts have been used in oxidation catalysis and involved in efficient biomimetic systems. In fact, recent publications have shown that polypyrrole + manganese porphyrin films are good catalysts for electroassisted oxidation of hydrocarbons by molecular oxygen [23,241 and that multicharged porphyrins supported on silica and mineral clays are particularly efficient for alkene epoxidation and alkane hydroxydation by iodosylbenzene [lo-12,20-221 or molecular oxygen [El. A new easy access to polyhalogenated metalloporphyrins covalently bound to silica and polystyrene supports as efficient catalysts for hydrocarbon oxidation by iodosylbenzene has recently been reported by Battioni et al. [9].

Total Oxidation of Hydrocarbons on Perovskite Oxides

Abstract Perovskite-type oxides containing transition metals are attracting great attention as catalysts for complete oxidation of hydrocarbons as well as electrochemical reduction of oxygen (1). A s far as I know, the use of perovskite-type oxides as catalysts was first reported by Meadowcroft in 1970 (2) for the electrochemical reduction of oxygen. Soon after that, Voorhoeve et al. (3) reported the high catalytic activity of perovskite oxides for heterogeneous oxidation. These studies triggered many studies thereafter which are related to exhaust control catalysts and electrode catalysts.

Structural analysis of some alkaline-earth-metal–copper oxide catalysts for hydrocarbon oxidation or NO decomposition

Some Ca–Cu–O, Sr–Cu–O and Ca–Sr–Cu–O defective perovskite-like mixtures have been prepared by the sol–gel technique and tested by means of a pulse reactor as possible catalysts for the title reactions. The characterisation of these preparations by several techniques, such as X-ray diffraction (XRD), scanning electron microscopy–electron probe microanalysis (SEM–EPMA), temperature-programmed desorption–temperature-programmed reaction–mass spectrometry (TPD–TPR–MS), electron paramagnetic resonance spectroscopy (EPR) and sorption–desorption of nitrogen, showed that the catalytic activity for both the reactions appears to be connected with the presence of a layer-like crystal structure approximating a two-dimensional antiferromagnet, stable within a sufficiently wide range of temperature. When oxygen, either added during the oxidation reaction or forming after the decomposition of NO, bridges together neighbouring Cu2+ ions not previously linked to oxygen, strongly interacting dipole systems form.

An easy access to polyhalogenated metalloporphyrins covalently bound to polymeric supports as efficient catalysts for hydrocarbon oxidation

Reaction of silica, montmorillonite and polystyrene bearing amino functions with several polyhalogenated metalloporphyrins gave an easy one-step access to new supported catalysts, owing to a selective nucleophilic substitution of the para-halogen atoms of the porphyrin meso-aryl groups by the polymer amine function; these catalysts were very active for cyclooctene epoxidation and alkane hydroxylation by PhlO.

ChemInform Abstract: Selective Oxidation of Hydrocarbons Employing Tellurium Containing Heterogeneous Catalysts

Abstract Premier catalysts for the selective oxidation of hydrocarbons are multifunctional in nature and are based on complex mixed metal oxides containing at least one of the key elements Mo, Sb and/or V. Te is often added as a promoter to enhance selectivities of desired products. In the 4 + oxidation state its role is that of hydrogen abstraction, in the 6+ oxidation state that of selective oxygen or nitrogen insertion. It also suppresses by-product formation of unwanted cracked intermediates as well as CO 4x . The major drawback of using tellurium containing catalysts is tellurium's volatility when in its lower oxidation state (Te 4+ ) generated under the redox conditions of the catalytic operation. Unless immediately reoxidized to the 6 + oxidation state, it volatilizes and is lost from the catalyst with a concomitant loss of its beneficial properties originally imparted to the base catalyst. Many ingenious solutions have been found to minimize the losses from catalysts in commercial operation. A most elegant approach is intercatalyst redox stabilization of Te 6+ through strategic placing of powerful reoxidation couples (Cu, Fe, Ce, V, U) in the immediate proximetry of the tellurium in the lattice of a given catalytically active phase. This elegant but difficult approach alleviates the volatility problem only partially. A more pragmatic, practical approach in commercial scale operation is the addition of volatile tellurium compounds on a continuous or intermittent basis directly to the reactor. An optimum concentration of tellurium is thus maintained on the surface of the catalyst resulting in constant and optimized process operation. Similarly, other key covalent catalytic elements (e.g., Sb, Mo) also lost through volatilization from the catalysts can be replenished. Since (amm)oxidation catalyst surfaces are very dynamic in nature under operating conditions, the addition of controlled amounts of key catalytic elements and/or promoters by means of volatile compounds directly to the reactor not only effectively maintains catalyst life and product quality but also suggests the opportunity to create new surface states so chosen as to potentially alter the reaction channels at will.

Chromium(III) compounds as catalysts for Hydrocarbon Oxidation and hydroperoxide decomposition

AbstractChromium stearate and chromium acetylacetonate are very active catalysts both for the oxidation of hydrocarbons by molecular oxygen and for the decomposition of organic hydroperoxides. During these reactions they also catalyze the oxidation of secondary alcohols to the corresponding ketones by organic hydroperoxides. From organic hydroperoxides and chromium(III)compounds chromium (VI) compounds are formed which are probably the effective agents oxidizing secondary alcohols to ketones.