甲醇与异戊烯醚化反应的研究

采用国产大孔磺酸树脂(NKC-9),在无梯度反应器对异戊烯与甲醇醚化反应进行了研究,在消除内扩散和外扩散的情况下,考察了甲醇浓度对醚化反应速度的影响,根据LHHW机理和均相反应机理推导出相应的模型方程,经模型筛选和参数估值,得出 LHHW模型为最佳模型.在该模型中反应速率的实验值与模拟值有较好的一致性.     

强酸性阳离子交换树脂催化酯化丙烯酸和甲醇合成丙烯酸甲酯的反应动力学

以丙烯酸和甲醇为原料,强酸性阳离子交换树脂Amberlyst-15为催化剂,对苯二酚为阻聚剂,合成丙烯酸甲酯。 考察了醇酸摩尔比、催化剂用量和温度对反应过程的影响,在实验范围内,随着温度或者催化剂用量的增加,反应速率加快,丙烯酸的转化率也不断提高。 醇酸摩尔比的增加能提高丙烯酸的转化率,反应速率出现先增加后减缓的现象。 与此同时,建立该催化酯化反应的Pseudo-Homogeneous（PH）的理想和非理想以及Langmuir-Hinshelwood（LH）反应动力学模型,辨识得到相应反应动力学方程。 经比较,采用活度替代物质的量浓度的LH模型的平均相对偏差(MRD)最小,计算值为1.466%,最适合实际反应。     

Reaction parameters influence on the catalytic performance of copper-silica aerogel in the methanol steam reforming

Steam reforming of methanol was carried out on the copper-silica aerogel catalyst.The effects of reaction temperature,feed rate,water to methanol molar ratio and carrier gas flowrate on the H_2 production rate and CO selectivity were investigated.M ethanol conversion was increased considerably in the range of about 240-300,after which it increased at a slightly lower rate.The used feed flowrate,steam to methanol molar ratio and carrier gas flowwere 1.2-9.0 m L/h,1.2-5.0 and 20-80 m L/min,respectively.Reducing the feed flowrate increased the H_2 production rate.It was found that an increase in the water to methanol ratio and decreasing the carrier gas flowrate slightly increases the H2production rate.Increasing the water to methanol ratio causes the lowest temperature in which CO formation was observed to rise,so that for the ratio of 5.0 no CO formation was detected in temperatures lower than 375℃.In all conditions,by approaching the complete conversion,increasing the main product concentration,increasing the temperature and contact time,and decreasing the steam to methanol ratio,the CO selectivity was increased.These results suggested that CO was formed as a secondary product through reverse water-gas shift reaction and did not participate in the methanol steam reforming reaction mechanism.     

The intermediacy of metathiophosphonate PhPSO in the reaction of N-tert-butyl-P-phenylphosphonamidothioic acid with alcohols

Kinetic studies of the reaction of N-tert-butyl-P-phenylphosphonamidothioic acid (1) with alcohols were carried out in CH2Cl2 by means of 31P NMR spectrometry. The reaction is of the first order with respect to thio acid 1. The first-order rate constant at 30 degrees C increases with increasing methanol concentration below 0.25 M, but otherwise the rate constants are either independent of alcohol concentration (MeOH above 0.25 M, BuOH) or decrease with increasing alcohol concentration (i-PrOH, t-BuOH). The effect of alcohols on the order of the reaction and parameters of activation, as well as results of competition experiments, lead us to the conclusion that reaction of 1 with alcohols occurs by an elimination-addition mechanism involving the association of the thio acid 1 and the alcohol and then formation in the rate-determining step of an encounter complex 2' ' involving metathiophosphonate 4, amine, and alcohol. Metathiophosphonate 4 reacts preferentially with the alcohol as the encounter complex (primary alcohols) or after diffusion apart as a "free" intermediate (hindered alcohols).     

Kinetic studies of xenon trioxide as an oxidant-I Determination of alcohols

A kinetic study of the oxidation of some alcohols by xenon trioxide has revealed the optimum conditions for analysis of these alcohols. The rate of reaction may be increased by adding a catalyst or by increasing the pH of the solution; it may be decreased by adding an inhibitor. The initiation time of the reaction is used to determine t-butanol in amounts as low as 22 mug or 880 parts per milliard (ppM). Primary and secondary alcohols which catalyse the reaction between t-butanol and xenon trioxide may be determined in amounts as low as 2.3 mug or 92 ppM. Tertiary butanol in amounts less than 40mug is determined with a coefficient of variation of 4% while methanol, ethanol and isopropanol are determined with a coefficient of variation of 10% at the level of 25mug or more. The precision in determination of t-butanol increases with increasing concentration, while for isopropanol, ethanol and methanol it decreases.     

Kinetics of liquid-phase noncatalytic methanol hydrochlorination in hydrochloric acid

The kinetics of the liquid-phase noncatalytic hydrochlorination of methanol in hydrochloric acid is reported. The methyl chloride formation rate depends on the methanol concentration in hydrochloric acid and on the partial pressure of hydrogen chloride over hydrochloric acid. The activation energy of the reaction is 113 kJ/mol. The rate of the side process of dimethyl ether evolution is directly proportional to the methanol concentration and is inversely proportional to the partial pressure of hydrogen chloride over hydrochloric acid. The activation energy of the side reaction is about 33 kJ/mol. The results of the industrial implementation of methyl chloride synthesis from methanol and hydrochloric acid are in satisfactory agreement with the laboratory data.     

The electrooxidation of methanol and related compounds at ruthenium dioxide-coated electrodes

The underlying metal was observed to corrode when a ruthenium dioxide-coated titanium electrode was anodized in an aqueous methanol solution. With a similarly coated platinum electrode peaks were observed on the voltammogram below 1.0 V which were attributed to methanol oxidation on the underlying metal. This effect was more pronounced when the electrode was subjected during cycling to potentials close to 0 V. Rapid oxidation of methanol on RuO₂ was observed at potentials above 1.0 V, the rate at a given potential increasing in an approximately linear manner with increasing alcohol concentration. The rate of reaction also increased with increasing temperature and increasing surface roughness. Tafel slope values were rather high (>100 mV decade^?1) and a mechanism involving anodically generated species such as OH_ads was proposed to account for these results. The variation of activity with pH was similar to that reported earlier for oxygen evolution at these anodes and this was again explained in terms of partial deactivation of the surface due to a combination of proton loss and phosphate ion adsorption at intermediate pH values. The release of carbon dioxide from aqueous solutions of higher alcohols at 25°C confirmed the high oxidizing power of RuO₂ anodes.     

Kinetics of the reaction of solvated electrons with fluorobenzene in liquid ammonia

The rate of disappearance of solvated electrons by reaction with fluorobenzene in ammonia is accelerated by small concentrations of methanol; it also has a “negative activation energy” depending on the methanol concentration. The kinetic data suggest an exothermic electron attachment-detachment equilibrium with the fluorobenzene followed by a slower reaction of the electron adduct with the proton donating methanol.     

Studies on the polymerization of methyl methacrylate activated by azobisisobutyramidine

Kinetic studies on methyl methacrylate polymerization were carried out with watersoluble 2,2′-azobisisobutyramidine (ABA). The rate of polymerization was proportional to the square root of the initiator concentration in the solvents chloroform, methanol, and dimethyl sulfoxide (DMSO), which confirms the bimolecular nature of the termination reaction. The monomer exponent was unity in chloroform but in methanol and DMSO the rate of polymerization passed through a maximum when plotted against the monmer concentration. This behavior in methanol has been attributed to be due to the enhanced rate of production of radical with increasing proportion of methanol. The rate of decomposition of the ABA has been observed to be faster in methanol than in chloroform. The situation becomes more complicated with DMSO, which was found to reduce the value of δ = (2k_t)^1/2/k_p in methyl methacrylate polymerization. The rate of polymerization was observed to be highly dependent on the nature of the solvent, the rate increasing with increased electrophilicity of the solvent. The dependence of R_p on the solvent has been explained in the light of the stabilization of the transition state due to increased solvation of the basic amidine group of the initiator with the increased electrophilicity of the solvent.     

操作条件对DMFC阴极电化学阻抗谱参数的影响

通过降低阴极催化剂载量强化了阴极氧还原反应的电化学极化, 测量了不同操作条件下直接甲醇燃料电池(DMFC)的极化曲线和交流阻抗谱,并提出了改进的等效电路模型LR(CR)(QR(LR))用以分析温度、空气流量和甲醇流量对DMFC阴极电化学反应和传质极化过程的影响. 研究结果表明, 提高工作温度会导致更多的甲醇渗透到阴极, 加大阴极氧气还原反应的电荷转移电阻; 只有采用大的空气流量,才会有效地防止水淹, 加大氧气向催化剂层的传质, 促进阴极反应的进行; 适当提高甲醇的流量可以促进阳极和阴极电化学反应的进行, 但是过高的甲醇流速可能会降低电极表面的温度, 加剧甲醇的渗透.     

杂多酸修饰的电极对于甲醇电氧化的促进作用

采用杂多酸修饰光滑铂电极,研究其对甲醇电催化氧化的作用,发现与未修饰光滑铂电极相比,分别经磷钨酸和硅钨酸修饰的电极上甲醇电催化氧化速率明显增加.     

Study on Coupled Chemiluminescene Reaction of Ru(l,10-PhenanthroIine)32+-Methanol-Ce(Ⅳ)

It was reported that some hydroxyl/carbonyl carboxylic acids can enhance the chemiluminescence light emission intensity of Ru(phen)₃²⁺(Phen=1,10-phenanthroline) with Ce(Ⅳ). Further studies showed that methanol can also enhance the light emission intensity. In sulfuric acid medium, methanol was oxidized by eerie sulfate, the rate of oxidation depended directly on the concentration of cerium(Ⅳ) and methanol. The reaction rate changes inversely with sulfuric acid. The reaction occurs without the intermediate formation of a complex.     

Electrochemical Behavior of Methanol Influenced by Polyaniline Incorporated with Ferrocenesulfonic-carboxylic Acid

After the synthesis of polyaniline in the presence of ferrocenesulfoniccarboxylic acid, its influence on the electrochemical reaction of methanol was studied. The result indicates that the ferrocenyl in ferrocenesulfoniccarbexylic acid plays an important role in the electrocatalytic oxidation of methanol. CH3OH is adsorbed on PANI-Fc before its electrocatalytic oxidation. When the concentration of methanol is 2 mol/L, it begins to be oxidized. The effect of scan rate on the electrochemical reaction of methanol was also studied and 5 mV/s was favourable. It is another method to insert a metal catalyst in polyaniline without its electrodeposition.     

Hydrocarbon Formation in the Catalytic Conversion of Methanol Over Zeolite ZSM-5

The reaction mechanism of methanol conversion to hydrocarbons on HZSM-5 zeolite was studied. From the selectivity plots of products in an integral fixed-bed flow reactor, paraffins were classified as primary and secondary stable products, light olefins as primary unstable products, aromatics as primary and secondary unstable or stable products. The results of the ¹⁴C-labelled methanol reaction indicated that the C₁–C₅ surface intermediates generated by dimethyl ether / methanol equilibrium gave paraffins and olefins at 300°C. The concentration of intermediates and adsorbed methanol on ZSM-5 decreased with increasing temperature. The distribution of radioactivity showed that propylene played an important role in the autocatalysis of the reaction.     

Control of methanol oxidation by ionic behavior in supercritical water

In supercritical water the rate of methanol oxidation was controlled by ionic behavior as follows: the oxidation rate of methanol decreased with increasing proton and hydroxide ion concentration, possibly due to stabilization of the reactant, while that of CO was suppressed by added protons and enhanced by added hydroxide ions.     

Optimization of methanol biosynthesis byMethylosinus trichosporium OB3b: An approach to improve methanol accumulation

Methylosinus trichosporium OB3b is a methanotrophic bacterium containing methane mono-oxygenase, catalyzing hydroxylation of methane to methanol. When methane is oxidized, the product is subsequently oxidized by methanol dehydrogenase contained in the same bacterium. To prevent further oxidation of methanol, the cell suspension was treated by cyclopropanol, an irreversible inhibitor for methanol dehydrogenase, leading to extracellular methanol accumulation. However, the reaction was terminated at approx 3 h with a final methanol concentration below 2.96 mmol/g dry cell. The methanol production efficiency (the ratio of the produced methanol per methane consumption) was 2.90%. By selecting the culture conditions and the reaction conditions, the reaction continued for 100 h, resulting in a methanol concentration of 152 mmol/g dry cell. This level was 51 times higher than that of the conventional reaction, and the methanol production efficiency was 61%.     

Water Catalysis of the Reaction between Methanol and OH at 294 K and the Atmospheric Implications

The rate coefficient for the reaction CH₃OH+OH was determined by means of a relative method in a simulation chamber under quasi‐real atmospheric conditions (294 K, 1 atm of air) and variable humidity or water concentration. Under these conditions, a quadratic dependence of the rate coefficient for the reaction CH₃OH+OH on the water concentration was found. Thus the catalytic effect of water is not only important at low temperatures, but also at room temperature. The detailed mechanism responsible of the reaction acceleration is still unknown. However, this dependence should be included in the atmospheric global models since it is expected to be important in humid regions as in the tropics. Additionally, it could explain several differences regarding the global and local atmospheric concentration of methanol in tropical areas, for which many speculations about the sinks and sources of methanol have been reported.     

纤维素在亚/超临界甲醇中液化条件对主要化合物产物的影响

在反应温度240-320 ℃、甲醇用量0-200 mL、反应时间0-200 min的条件下,采用间歇式高温高压反应釜对玉米秸秆纤维素在亚/超临界甲醇中进行液化实验,结合GC-MS分析,研究不同液化反应条件下,生物油中轻油、重油产率及液化产物中烃类、醇类、酯类、酸类等主要化合物的组分分布及其变化规律。结果表明,反应温度和甲醇用量对化合物的分布与含量影响较大,反应温度和甲醇用量增加,促进纤维素向烃类、醇类、酯类转化,各化合物含量随之增加,并使轻油、重油产率升高,当反应条件为：甲醇用量160 mL,温度320 ℃,反应时间30 min时,生物油产率达到最高25.1%。生物油中组分含量顺序为：烃类>醇类>酯类>酸类,各化合物最高相对含量分别为77.2%、19.0%、30.9%、20.8%。初步分析发现,随着温度的升高和甲醇量的增加,自由基活性逐渐增强,当甲醇用量超过160 mL、温度超过300 ℃时,醇类以及酯类等化合物进一步发生氧化、缩合等反应形成酸类等化合物,造成化合物产率减小,进而使生物油产率降低。     

Methanol Oxidation at Platinum in Alkaline Media: A Study of the Effects of Hydroxide Concentration and of Mass Transport

The hydroxide ion concentration dependence of the methanol oxidation reaction at Pt was studied using microelectrode voltammetry and rotating disk electrode voltammetry. Both methods suggest that the rate of methanol oxidation is limited by hydroxide mass transport at low hydroxide concentrations, while it is inhibited by hydroxide adsorption at high concentrations. It was possible to shift from the transport-limited regime to the inhibitory regime by varying the bulk concentration of hydroxide or by varying mass transport to the electrode. Rotating ring-disk electrode voltammetry was employed to qualitatively assess changes in the diffusion layer pH. The results indicated a decrease in the surface pH during methanol oxidation, as expected, but also that the pH reached a steady state during hydroxide transport limited methanol oxidation.     

Photolysis of Retinol in Liposomes and Its Protection with Tocopherol and Oxybenzone

Abstract— In this work the stabilities of retinol in methanolic solutions and liposomal suspensions exposed to UV light were compared using absorbance spectroscopy and the ability of a-tocopherol and the sunscreen additive, oxybenzone, to reduce the rate of retinol decomposition assessed. Retinol in methanol decolorized almost completely within a few minutes of exposure to a 6 W 350 nm wavelength lamp. From the concentration dependence of the reaction rates it appears that retinol activated by light can decompose either directly or after collision with a second retinol molecule. Several reaction products are formed, α-Tocopherol solutions were unaffected by 350 nm light but they did darken when irradiated with 250 nm wavelength light. Addition of a-tocopherol or removal of oxygen from the retinol in methanol solutions reduced only slightly the rates of retinol photolysis. When dispersed in water within liposomes made of equimolar egg phosphatidylcholine (PC) and cholesterol, up to six-fold increases in the decomposition rate of the retinol were observed. The reaction rate could be reduced but only slightly by increasing the ratio of PC to retinol. A mechanism that explains the concentration dependence of the retinol photolysis is that the reduction in reaction rate on diluting the retinol concentration within a given liposome was due to the prevention of the reaction between one light-activated retinol molecule with another within the same liposome. Incorporation of oxybenzone into the liposomes reduced the reaction rates. The results suggested that most of the protection in this case arises through the oxybenzone closest to the light source absorbing the light, thereby preventing it reaching retinol much further into the sample. Incorporation of a-tocopherol into the liposomes could also reduce substantially the photolysis rate of co-entrapped retinol. The mechanism of protection in this case appears to be via the tocopherol quenching activated retinol molecules. The close proximity of the tocopherol to the retinol within a single liposome has shown to be important in this case. Only slight protection of retinol in one liposome by tocopherol in another was observed under the conditions studied. This means that the protection by tocopherol will still be observed if the liposome dispersions are diluted considerably or if only thin samples are exposed to light.