Ruthenium complex catalyst system for selective oxidation of cyclohexane to cyclohexanone by molecular oxygen

Summary TS-1 zeolite was successfully synthesized <Emphasis Type=Italic>in-situ</Emphasis> on a honeycomb cordierite substrate. Cu-TS-1/cordierite and LaCu-TS-1/cordierite were used as catalysts for selective catalytic reduction (SCR) of nitrogen oxides (NOx) in the exhaust of lean burn engine. High catalytic activities were obtained and the main pollutants nitrogen oxides, carbon monoxide and hydrocarbons in the exhaust could be purified together.     

分子氧选择性氧化醇类的研究进展

综述了分子氧化剂的醇类液相催化氧化的新进展。分别介绍了均相催化、水/有机两相催化、氟两相催化和液固多相催化体系。重点讨论了精细有机合成中有广泛应用前景的绿色氧化方法。预测了均相催化剂的多相化是今后工业化发展的趋势。     

Palladium oxidase catalysis: selective oxidation of organic chemicals by direct dioxygen-coupled turnover

Selective aerobic oxidation of organic molecules is a fundamental and practical challenge in modern chemistry. Effective solutions to this problem must overcome the intrinsic reactivity and selectivity challenges posed by the chemistry of molecular oxygen, and they must find application in diverse classes of oxidation reactions. Palladium oxidase catalysis combines the versatility of Pd(II)-mediated oxidation of organic substrates with dioxygen-coupled oxidation of the reduced palladium catalyst to enable a broad range of selective aerobic oxidation reactions. Recent developments revealed that cocatalysts (e.g. Cu(II), polyoxometalates, and benzoquinone) are not essential for efficient oxidation of Pd(0) by molecular oxygen. Oxidatively stable ligands play an important role in these reactions by minimizing catalyst decomposition, promoting the direct reaction between palladium and dioxygen, modulating organic substrate reactivity and permitting asymmetric catalysis.     

Green oxidation of alcohols by a reusable nickel catalyst in the presence of molecular oxygen

An easily prepared and reusable Ni(OH)₂ catalyst for the oxidation of benzylic and allylic alcohols by molecular oxygen has been developed.     

Catalytic oxidation of organic substrates by molecular oxygen and hydrogen peroxide by multistep electron transfer--a biomimetic approach

Oxidation reactions are of fundamental importance in nature, and are key transformations in organic synthesis. The development of new processes that employ transition metals as substrate-selective catalysts and stoichiometric environmentally friendly oxidants, such as molecular oxygen or hydrogen peroxide, is one of the most important goals in oxidation chemistry. Direct oxidation of the catalyst by molecular oxygen or hydrogen peroxide is often kinetically unfavored. The use of coupled catalytic systems with electron-transfer mediators (ETMs) usually facilitates the procedures by transporting the electrons from the catalyst to the oxidant along a low-energy pathway, thereby increasing the efficiency of the oxidation and thus complementing the direct oxidation reactions. As a result of the similarities with biological systems, this can be dubbed a biomimetic approach.     

Non-heme iron catalysts for the benzylic oxidation: a parallel ligand screening approach

Ethylbenzene and 4-ethylanisole were used as model substrates for benzylic oxidation with H₂O₂ or O₂ using a range of non-heme iron catalysts following a parallel ligand screening approach. Effective oxidation was found for Fe complexes based on tetra- and pentadentate nitrogen ligands affording the corresponding benzylic alcohol and ketone.     

Reaction mechanism of aerobic oxidation of alcohols conducted on activated-carbon-supported cobalt oxide catalysts

Catalytic performances and the reaction mechanism of Co(3)O(4)/AC (AC=activated carbon) for aerobic oxidation of alcohols carried out in the liquid phase were investigated. Co(3)O(4)/AC shows a high activity for aerobic oxidation of benzyl alcohol, comparable to noble metal catalysts (e.g., Au/AC) even in the absence of additives or promoters (e.g., NaOH). Changing preparation conditions, such as treatment temperature and/or time, can affect the catalytic performances of Co(3)O(4)/AC, due to decomposition of surface groups of the carbon support. Careful studies show that low alcohol conversions are obtained with either Co(3)O(4) or AC alone, which indicates that the high conversion observed over the Co(3)O(4)/AC is due to a synergistic effect between Co(3)O(4) and AC. Parallel experiments using a high-surface-area covalent triazine framework or oxygen-inert carbon nitride as support for the Co(3)O(4) catalyst also show lower conversions, which suggest that the ability of AC (in Co(3)O(4)/AC) to activate molecular oxygen is essential for the reaction. FTIR and XPS spectra taken from catalysts before and after the reaction confirm that oxygen activation proceeds mainly on the carbon support. As a result, it can be assumed that the alcohol dehydrogenation step proceeds on the metal oxide, whereas the oxygen activation step occurs mainly on the carbon support.     

Methyltrioxorhenium catalyzed aerobic oxidation of organonitrogen compounds

A variety of tertiary, secondary and primary organonitrogen compounds have been efficiently and selectivity oxidized to their corresponding N-oxides, nitrones, and nitro compounds with molecular oxygen using methyltrioxorhenium as catalyst.     

Catalytic behavior of a magnesium oxide supported polysilazane-ruthenium complex for the oxidation of indene with molecular oxygen to indanones

A new magnesium oxide supported polysilazane ruthenium complex has been prepared and found to be capable of catalyzing the oxygenation of indene in 62.9% conversion to indanones without by-products under mild conditions, i.e. 1 atm oxygen and 80°C. The supported ruthenium complex was effective without need for a cocatalyst. Also, it can be reused several times without apparent loss of activity.     

Visible light photoredox catalysis: aerobic oxidation of perimidines to perimidinones

Aerobic oxidation of a series of 2,3-dihydro-1H-perimidines to the corresponding 4- and 6-perimidinones via visible light photoredox catalysis using Ru(bpy)₃²⁺ as a catalyst was reported. The scope and limitation of this oxidation were investigated and a possible photochemical mechanism was proposed.     

Measurement and characterization of singlet oxygen production in copper ion-catalyzed aerobic oxidation of ascorbic acid

Production of singlet molecular oxygen (¹O₂) in the aerobic oxidation of ascorbic acid catalyzed by copper ion was measured and characterized using [4′-(9-anthryl)-2,2′:6′,2″-terpyridine-6,6″-diyl]bis(methylenenitrilo)tetrakis(acetate)-Eu³⁺ (ATTA-Eu³⁺) as a highly sensitive and selective time-resolved luminescence probe for ¹O₂. The ¹O₂ produced in the reaction was further characterized and confirmed by (i) chemical trapping of ¹O₂ with 9,10-diphenylanthracene (DPA), the corresponding endoperoxide was detected by HPLC and (ii) spin trapping of ¹O₂ with 2,2,6,6-tetramethyl-4-piperidinol (TMP-OH), the corresponding free radical of TMP-OH oxide (TMPO) was detected by electron spin resonance (ESR) spectroscopy. The effects of deuterium oxide, sodium azide and histidine on the ¹O₂ signal were investigated. The mechanism investigation of ¹O₂ production implied that the ascorbic acid-Cu(I) complex formed in the reaction could be an important intermediate for the ¹O₂ production. The reaction of ascorbic acid with copper ion monitored by ¹H NMR and absorption spectroscopy demonstrated the formation of a copper ion-ascorbic acid complex. Except for Cu²⁺ and Cu⁺-ascorbic acid systems, no detectable ¹O₂ was produced in other transition metal cation-ascorbic acid systems in the studied range.