Thermal behaviour of cobaltic and cobaltous oxides as influenced by doping with some alkali metal oxides

The role of Na₂O- and Li₂O-doping on the thermal decomposition of Co₃O₄ to CoO and the re-oxidation of cobaltous to cobaltic oxide has been investigated using DTA, with controlled rates of heating and cooling, IR and X-ray diffraction spectrometry techniques.

The DTA investigation revealed that both Li₂O and Na₂O increased the thermal stability of Co₃O₄. However, the effect was much more pronounced in the case of lithium oxide. Doping Co₃O₄ with 1.5 mole% Li₂O was found to prevent any thermal decomposition of cobaltic oxide even by heating at 1100°C. The maximum thermal stabilization effect induced by doping with sodium oxide (4.5 mole%) was 30%. The sodium oxide- and lithium oxide-doping enhanced the reactivity of the produced CoO towards the re-oxidation by O₂ yielding Co₃O₄.

The X-ray diffraction and IR spectrometric investigations showed that part of Li₂O and Na₂O was effectively incorporated in the Co₃O₄ lattice, affecting the thermal stabilization of the solid, and another part of the dopant oxide interacted with the produced CoO and also with Co₃O₄ giving a new sodium cobalt compound, and with Co₃O₄ producing, also, a new lithium cobalt oxide phase. However, the amount of Li₂O dissolved in the Co₃O₄ lattice was greater than that of Na₂O. The sudden cooling of doped solids, from 1000°C to room temperature, favoured the formation of the new sodium cobalt oxide compound, and exerted no effect on the production of the new lithium cobalt oxide phase. The characteristic d spacings and IR absorption bands of these new compounds have been determined.

The possible mechanisms of dissolution of Li₂O and Na₂O in cobaltic oxide lattice are discussed.     

哌啶氧铵盐对醇氧化反应的活性和选择性

系统地研究了12种具有不同4-位取代基(R=H、CH~3O、Cl)及反离子(X=Cl、BF~4、ClO~4、Br或Br~3)的2, 2, 6, 6-四甲基哌啶氧铵盐对醇的氧化反应, 发现这些氧铵盐都能以很高的由率将一级醇氧化为醛, 二级醇氧化为酮。氧化反应的活性与4-位取代基及反离子有关。当反离子相同时, 反应活性的顺序为Cl>CH~3O>H;当4-位取代基相同时, 反应活性的顺序为Cl^-》BF~4^->ClO~4^->Br^-。氧化反应的选择性主要与反离子有关, 当反离子为Cl^-时, 主要氧化一级醇; 当反离子为BF~4^-、ClO~4^-、Br^-或Br~3^-时, 主要氧化二级醇。     

Mixed-valence manganese calcium oxides as efficient catalysts for water oxidation

Incorporation of calcium to mixed-valence manganese oxides improved the water oxidation activity of these manganese oxides.     

Polytetrafluoroethylene surface modification by impregnation with iron and manganese oxides

Polytetrafluoroethylene (PTFE) surfaces can be modified by impregnation with Fe and Mn oxides by procedures based on Fe(CO)₅ sorption in the polymer and followed by oxidation with H₂O₂ or KMnO₄. The effect of some variables (reagent concentrations and temperature) on the amount of oxides deposited was examined. The oxides incorporated in PTFE can be only partly removed by acid cleaning. Water–PTFE contact angles and PTFE surface resistivity are altered. Electron and x-ray diffractograms of the oxides were obtained but unambiguous identification was not achieved. Transmission electron microscopy examination of surface replicas showed that impregnation with oxides which covered most of the PTFE surface was fairly uniform.     

Effect of gamma-irradiation on the catalytic activity and selectivity of gamma-alumina

Methanol conversion reaction was carried out in contact with a poorly crystalline -alumina pre-irradiated with different doses of -rays. The reaction was conducted at 140–440°C using a flow technique under atmospheric pressure. The results obtained revealed that -irradiation of Al₂O₃ resulted in drastic modifications of its activity and selectivity in methanol conversion reaction. The dose of 15 Mrad was sufficient to suppress completely the formation of dimethyl ether (DME) and stimulated the formation of methane, which started at 200°C instead of 300°C in the case of the unirradiated alumina specimen. However, the rate of CH₄ formation was found to decrease as a function of the dose employed. When the dose reached 140 Mrad, DME was reproduced with a rate comparable to that measured for the unirradiated catalyst sample. These results permitted us to conclude that DME is produced on the weak acidic sites (Brönsted acidity of Al₂O₃) and is not necessarily an intermediate compound for methane formation that takes place directly from methanol on strong acidic sites (Lewis acidity). The doses of 15–75 Mrad expelled completely the Brönsted acidic sites from Al₂O₃ surface, and the doses above this limit brought about a transformation of Lewis acidic sites into Brönsted acidity that is responsible for dimethyl ether formation. This transformation occurs by the action of liberated water from the dehydration of methyl alcohol.     

氧化锰晶体作为催化材料调控氨氧化反应产物选择性

有机腈类化合物作为一类重要的化工原料,被广泛应用于医药/农药制造、精细化学品合成和高性能纤维/橡胶生产中.传统合成有机腈类化合物一般使用剧毒的氰化物作为腈化试剂,这类氰化物在危害人体健康的同时,也会严重污染生态环境.针对无氰化物的腈化过程,发展了很多新的反应路线,其中,采用氨气作为氮源的直接氨氧化引起了广泛关注.在该反应中,高温气固相氨氧化反应容易发生过氧化等副反应.与之相比,液相体系中的氨氧化过程反应条件则相对温和,可以有效抑制过氧化.但是,在液相反应中,腈类产物很容易被水合成酰胺类化合物,从而导致该反应的产物选择性大幅降低.本文研究发现,通过改变氧化锰晶体结构可以有效地调控醇类分子氨氧化反应中腈和酰胺产物的选择性.MnO2(包括α,β,γ和δ相)催化的氨氧化过程中,主要得到了酰胺(选择性>99.0％),而在相同反应条件下,α-Mn2O3却可以高选择性地催化醇氨氧化到腈类产物(选择性>99.0％),在该体系中,即使额外增加反应体系中水和催化剂的用量,腈类产物依然不会转化为酰胺产物.动力学研究结果表明,α-Mn2O3催化腈水合到酰胺的反应速率几乎为零,这说明该类催化剂可以有效抑制腈水合反应.原位红外光谱结果表明,α-Mn2O3表面无法有效活化水分子,并且对腈类分子的吸附较弱,这些因素都导致了腈水合反应难以进行,从而可以高选择性地形成腈类化合物.与之相反,MnO2催化材料则可以高效地活化水分子,并且对腈类分子吸附较强,从而有效促进了水合反应并获得了酰胺产物.综上,通过调控氧化锰的晶体类型就可以简单、有效地改变氨氧化反应中的产物选择性.即使在苛刻的反应条件下,例如较大量的水存在下,α-Mn2O3催化的反应体系中依然可以高选择性地获得腈类化合物.本文为高效调控氨氧化反应的产物选择性提供了一个可靠方案.     

Reductive dissolution of microparticulate manganese oxides

Electrochemical dissolution of immobilised microparticulate Mn(III,IV) oxides in slightly acidic solution (pH 4.4) was found to be a very general reaction, which is responsible for well-defined voltammetric peaks. Dissolution of six Mn(III,IV) oxides is initiated by the reduction of Mn(IV) to Mn(III) in the solid phase, which is followed by a massive dissolution via further reduction of Mn(III) to Mn(II), which finally yields soluble Mn²⁺. The reactivity of manganese oxides depends on their structure: the most reactive are amorphous (δ-MnO₂) and layered structures (birnessite); more resistant toward reductive dissolution are α- and λ-MnO₂ and electrochemical manganese dioxide; and least reactive is β-MnO₂. Reductive dissolution of LiMn₂O₄ resembles that of λ-MnO₂, whereas CaMnO₃ dissolves via a different reaction mechanism.     

Facile fabrication of mesoporous manganese oxides as advanced electrode materials for supercapacitors

Mesoporous manganese oxides (MnO₂) were synthesized via a facile chemical deposition strategy. Three kinds of basic precipitants including sodium carbonate (Na₂CO₃), sodium bicarbonate (NaHCO₃), and sodium hydroxide (NaOH) were employed to adjust the microstructures and surface morphologies of MnO₂ materials. The obtained MnO₂ materials display different microstructures. Great differences are observed in their specific surface area and porosity properties. The microstructures and surface morphologies characteristics of MnO₂ materials largely determine their pseudocapacitive behavior for supercapacitors. The MnO₂ prepared with Na₂CO₃ precipitant exhibits the optimal microstructures and surface morphologies compared with the other two samples, contributing to their best electrochemical performances for supercapacitors when conducted either in the single electrode tests or in the capacitor measurements. The optimal MnO₂ electrode exhibits a high specific capacitance (173 F g^–1 at 0.25 A g^?1), high-rate capability (123 F g^?1 at 4 A g^?1), and excellent cyclic stability (no capacitance loss after 5,000 cycles at 1 A g^?1). The optimal activated carbon//MnO₂ hybrid capacitor exhibits a wide working voltage (1.8 V), high-power and high-energy densities (1,734 W kg^?1 and 20.9 Wh kg^?1), and excellent cycling behavior (93.8 % capacitance retention after 10,000 cycles at 1 A g^?1), indicating the promising applications of the easily fabricated mesoporous MnO₂ for supercapacitors.     

Selective oxidation of alcohols by porphyrin-based porous polymer-supported manganese heterogeneous catalysts

A series of porphyrin-based porous polymers to support Mn heterogeneous catalysts (Mn/TFP-DPM, Mn/TFP-DPM-2, Mn/TFP-DPM-3, and Mn/TFP-DPM-4) in the selective oxidation of alcohols were designed. TFP-DPM and TFP-DPM-2 demonstrated micro/nanoscale spherical morphology, whereas TFP-DPM-3 and TFP-DPM-4 exhibited nanosheets structure. According to surface area and porosity analysis results, the specific surface areas of these catalysts were less than 300 m² g^–1. Thermogravimetric analysis indicated that the synthesized catalysts maintain their stability even at 300 °C. Catalysts Mn/TFP-DPM and Mn/TFP-DPM-3, which had the smallest and largest specific surface area among the four catalysts, respectively, were used to perform selective oxidation reaction of alcohols, with experimental results indicating that both have excellent catalytic performance. As these catalysts possess good catalytic performance despite their low specific surface area, we suggest that porphyrin-based porous polymer-supported Mn heterogeneous catalysts are promising materials for selective oxidation of alcohols.     

Synthesis of monodisperse nanocrystals of manganese oxides

We report a simple and effective method for the generation of high-quality nanocrystals of manganese oxide, MnO, with an alkyl capping group. MnO is a model system for the theoretical study of electronic and magnetic properties of rock salt oxides. Synthesis of relatively monodisperse nanocrystals of MnO was achieved over a range of sizes between 7 and 20 nm. The nanocrystals are readily dispersed in nonpolar solvents, and their uniformity allows for the formation of superlattices, as observed by TEM. Fitting size evolution/time data with the Lifshitz-Slyozov-Wagner model indicates that the increase in particle size from 7 nm is dominated by diffusion-limited growth. Controlled chemical oxidation can allow for the preparation of nanocrystals of Mn3O4 from MnO. We demonstrate the use of acetate precursors in the preparation of ligand-capped, transition metal oxide nanocrystals (of MnO and FeO), which are safer and more environmentally benign than their metal carbonyl counterparts.     

Catalytic graphitization of PAN-based carbon fibers by spontaneously deposited manganese oxides

A simple method for the spontaneous deposition of manganese oxides on the surface of polyacrylonitrile (PAN)-based carbon fibers by a direct redox reaction between carbon fibers and permanganate ions is described. Catalytic graphitization of the PAN-based carbon fibers coated with manganese oxides was investigated by X-ray diffraction, Raman spectroscopy, and scanning electron microscopy. The results indicate that the graphitization of the PAN-based carbon fibers was accelerated in the presence of the manganese oxides even at the relatively low temperature of 1,600 °C.     

Phase diagrams for systems formed by manganese and rare earth metal oxides

We analyze the advantages and disadvantages of various methods for representing P-T-x diagrams of three-component systems and their fragments in various coordinates.     

Fluidized-bed granulation of ammonium sulfate from solution formed as by-product in production of manganese oxides

Fluidized-bed granulation of ammonium sulfate from the solution formed as by-product in production of manganese oxides was subjected to theoretical and experimental study. The evolution of the particle-size distribution in relation to the process conditions was examined, and the adequacy of the suggested mathematical model was checked.     

Conversion of rare-earth metal oxides in tributyl phosphate

Dissolution of gadolinium, europium, neodymium, dysprosium, and samarium oxides to give nitrates of these metals was studied in a system constituted by tributyl phosphate (30 vol %), tetrachloroethylene (70 vol %), and NO₂. The activation energy of anhydrous dissolution of gadolinium oxide was calculated. The effect of water on the conversion efficiency of gadolinium oxide into nitrate was examined.     

氧化镁上乙酸乙酯和乙酸丁酯氧化反应（英文）

采用新型无溶剂反应和回流的方法制得锰钾矿型氧化镁(K-OMS-2),同时采用常规方法制得氧化镁,并测试不同催化剂对工业排放气中有机挥发性物质(VOCs)中的模型化合物––乙酸乙酯和乙酸丁酯的催化氧性能.采用N2吸附-脱附、X射线衍射、扫描电镜、程序升温还原和X射线光电子能谱等技术对催化剂进行了表征.所有氧化镁样品均表现出很高的催化乙酸乙酯和乙酸丁酯氧化生成CO2的活性,且制备方法对催化剂性能起着重要作用.新型无溶剂法制得的K-OMS-2纳米棒样品比常规的回流法制得样品表现出更好的催化性能,含锰钾矿型氧化镁的样品比常规方法制得样品表现出更高的活性.性能最好的催化剂也表现出较高的稳定性,在213和202 oC条件下,可分别使90%的乙酸乙酯和乙酸丁酯转化为CO2.催化剂性能的显著差异清楚地表明,对于所选VOCs氧化反应,采用新型无溶剂法制得的K-OMS-2纳米棒样品比常规法制备的氧化镁混合物更好,这可能与样品结构中含有更高的Mn平均氧化态有关.本文表明了催化剂性能与其表面化学性质间存在显著的关联,显示了K-OMS-2内在性质决定了其高的催化性能.     

Kinetic and selectivity control of TEMPO electro-mediated oxidation of alcohols

TEMPO electro-mediated oxidation of alcohols has been investigated in aqueous and hydro-organic media. Mono- and poly-saccharides, aryl alcohols and heterocyclic alcohols were converted into the corresponding carbonyls in good chemical and Faradaic yields. In both solvents, the electrochemically generated TEMPO⁺ was used in catalytic amount and the kinetics was found to be controlled by the diffusion step.     

Calcium manganese oxides as oxygen evolution catalysts: O2 formation pathways indicated by 18O-labelling studies

Oxygen evolution catalysed by calcium manganese and manganese-only oxides was studied in (18)O-enriched water. Using membrane-inlet mass spectrometry, we monitored the formation of the different O(2) isotopologues (16)O(2), (16)O(18)O and (18)O(2) in such reactions simultaneously with good time resolution. From the analysis of the data, we conclude that entirely different pathways of dioxygen formation catalysis exist for reactions involving hydrogen peroxide (H(2)O(2)), hydrogen persulfate (HSO(5)(-)) or single-electron oxidants such as Ce(IV) and [Ru(III) (bipy)(3)](3+) . Like the studied oxide catalysts, the active sites of manganese catalase and the oxygen-evolving complex (OEC) of photosystem II (PSII) consist of μ-oxido manganese or μ-oxido calcium manganese sites. The studied processes show very similar (18)O-labelling behaviour to the natural enzymes and are therefore interesting model systems for in vivo oxygen formation by manganese metalloenzymes such as PSII.     

Combustion-synthesized sodium manganese (cobalt) oxides as cathodes for sodium ion batteries

We report on the electrochemical properties of layered manganese oxides, with and without cobalt substituents, as cathodes in sodium ion batteries. We fabricated sub-micrometre-sized particles of Na_0.7MnO_2?+?z and Na_0.7Co_0.11Mn_0.89O_2?+?z via combustion synthesis. X-ray diffraction revealed the same layered hexagonal P2-type bronze structure with high crystallinity for both materials. Potentiostatic and galvanostatic charge/discharge cycles in the range 1.5–3.8 V vs. Na | Na⁺ were performed to identify potential-dependent phase transitions, capacity, and capacity retention. After charging to 3.8 V, both materials had an initial discharge capacity of 138 mA?h?g^?1 at a rate of 0.3 C. For the 20th cycle, those values reduced to 75 and 92 mA?h?g^?1 for Co-free and Co-doped samples, respectively. Our findings indicate that earlier works probably underestimated the potential of (doped) P2-type Na_0.7MnO_2?+?z as cathode material for sodium ion batteries in terms of capacity and cycle stability. Apart from doping, a simple optimization parameter seems to be the particle size of the active material.     

Effects of pH on the morphology of iron oxides synthesized under gamma-irradiation

Summary 190, Kinshasa XI, Kinshasa, République Démocratique du C