Organic reactions, liquid-phase

Adapted from Bhaumik et al. 244). Reaction conditions reaction time, 12 h reactant H202 = 1 1 catalyst (TS-1, Si/Ti = 29), 20 wt% with respect to reactant temperature, 353 K. a Tri solid catalyst + two immisible liquid phases (organic reactant + H202 in water) bi solid catalyst + one homogeneous liquid phase (organic reactant + aqueous H202 + CH3CN as cosolvent). 

Catalysis by Hydrotalcite in Liquid-phase Organic Reactions... 

The number of papers dealing with catalysis by Au was more or less than 5 a year in the 1980s but reached 700 in 2005 and 600 in 2006. There are three major streams in current research activities on Au catalysts expansion of applications, especially to liquid-phase organic reactions [4], discussion on the active states of Au [5], and exploration of new forms of Au catalysts. The last stream has emerged recently and is represented by Au submicron tube [6], nanoporous Au [7, 8], polymer stabilized Au colloids [9] and Au on solid polymers [10, 11], which in turn provide valuable information for determining what states of Au are surprisingly active and selective. 

How far should one go in search of the sources of science "The past is a well of ineffable depth wrote Thomas Mann beginning his novel Joseph and his Brothers. As far as chemical kinetics is concerned, it is far from being true. Certainly, one can trace its remote sources (as far back as Empedocles and Aristotle), but the origin of this science is quite certain it is the 1850s-1870s. The basic concepts of chemical kinetics as a science were formulated at that time on the basis of liquid-phase organic reactions. 

However, continuous reactors, generally fixed bed reactors, which are currently used in gas phase reactions in refining and the petrochemical industry, can also be used for liquid phase organic synthesis in the presence of zeolite catalysts. Better results in terms of catalyst stability are often obtained. However, efforts have still to be made to encourage Organic Chemists to substitute fixed bed reactors, whose setup is relatively simple, to batch reactors, which are virtually the only devices used in academic organic chemistry. 

Doi, S., J.H. Clark, D.J. Macquarrie and K. Milkowski, New Materials Based on Renewable Resources Chemically Modified Expanded Corn Starches as Catalysts for Liquid Phase Organic Reactions, Chemical Communications, 2632-2633 (2002). 

The present volume continues our effort to provide diverse exposure. We include two articles devoted to stereochemical aspects of catalytic reactions (J. K. A. Clarke and J. J. Rooney R. L. Augustine), and one (J. D. Morrison, W. F. Masler, and M. K. Neuberg) devoted to the control of a yet more subtle level of chemical structure asymmetry (or optical activity) a comprehensive review of liquid phase organic oxidation catalysis (R. A. Sheldon and J. K. Kochi) a review of specific adsorption and poisoning action as a means to learn more about active sites (H. Knozinger) and some of the latest considerations to catalysis of molecular orbital theory (R. C. Baetzold). 

Smith K, Fry CV, Tzimas M, The use of solid supports and supported reagents in liquid phase organic reactions, in Chem. Waste Minimization (Ed. J.H. Clark), pp. 86-115, 1995, Blackie, Glasgow, UK. 

Minor uses of vanadium chemicals are preparation of vanadium metal from refined pentoxide or vanadium tetrachloride liquid-phase organic oxidation reactions, eg, production of aniline black dyes for textile use and printing inks color modifiers in mercury-vapor lamps vanadyl fatty acids as driers in paints and varnish and ammonium or sodium vanadates as corrosion inhibitors in flue-gas scrubbers. 

For liquid-phase reactions taking place in solution, the solvent usually dominates the situation. As a result, changes in the density of the solute do not affect the overall density of the solution significantly and therefore it is essentially a constant-volume reaction process. Most liquid-phase organic reactions do not change density during the reaction, and represent still another case to which the constant-volume simplifications apply. An important exception to this general rule exists for polymerization processes. 

So far several excellent reviews covering reactions on zeolite and clay have made reference to a variety of organic reactions (5-13). This article will exclusively focus on liquid-phase organic reactions carried out below 1(X)°C on zeolite and clay, comparing them with reactions carried out by existent synthetic methods from the standpoint of synthetic organic chemistry. 

In summary, zeolites have been successfully applied as catalysts or promoters in several fundamental liquid-phase organic reactions under mild reaction conditions. The functions of the zeolites in promoting the liquid-phase reactions can be characterized by (1) synergistic effects of acidic and basic sites of the zeolites on the reactants, (2) a decrease in the activation entropy of reactions owing to preadsorption of reactants in close proximity, (3) an increase in the effective surface area of the reagent owing to high dispersion... 

The use of solid acids in liquid-phase organic reactions provides the advantage of a much more simple work-up procedure compared with that of liquid acids. As work up, only filtering of the reaction mixture through a Celite pad is required in order to separate a solid catalyst from organic products. 

Environmentally friendly catalysis of liquid phase organic reactions using chemically modified mesoporous materials... 

Chemical surface modification techniques provide effective routes to mesoporous solid catalysts which are active in various liquid phase organic reactions including selective oxidations, nucleophilic substitutions, and oevenagel reactions. 

Polymerizations as part of liquid-phase organic reactions are also influenced by mass and heat transfer and residence time distribuhon [37, 48]. This was first shown with largely heat-releasing radical polymerizations such as for butyl acrylate (evident already at dilute concentration) [49]. Here, a clear influence of microreactor operation on the polydispersity index was determined. Issues of mass transfer and residence time distribution in particular come into play when the soluhon becomes much more viscous during the reachon. Polymerizahons change viscosities by orders of magnitude when carried out at high concentration or even in the bulk. The heat released is then even more of an issue, since tremendous hot spots may arise locally and lead to thermal runaway, known in polymer science as the Norrish-Tromsdorff effect. 

The use of solid acids has been traditionally biased towards large-scale continuous vapour phase processes such as catalytic cracking and paraffin isomerisations. However, it is increasingly recognised that there is also a great need for solid acid catalysts which are effective in liquid-phase organic reactions such as those employed in many batch-type reactors by fine, speciality and pharmaceutical intermediate chemical manufacturers. This has contributed towards a substantial recent research effort into the development of new solid acid catalysts.86-91... 

Various mesoporous materials such as MCM-41, MCM-48, SBA-1 and KIT-1 have been rendered more acidic by treatment with reagents including ethanolic solutions of AICI3 and A1(N03)3 and slurries of Al(OPri)3 in non-polar solvent (e.g. hexane) followed by calcination of the resulting solid at temperatures of > 800 K to give solid adds.117 These treatments create either framework or nonframework aluminium centres which can act as Lewis add catalytic sites. The materials are more commonly assodated with vapour-phase reactions such as cracking rather than liquid-phase organic reactions.118... 

Figure 4.10 Preparation of supported aluminium chloride for liquid-phase organic reactions...

Boron trifluoride is also widely used as a Lewis add in industrial processes. It is less active than aluminium trichloride but has the advantages of being more tolerant of air exposure (it is deactivated but not destroyed by water). It is normally used as a complex, such as the etherate, which gets around the difficulties of working with a gas. Several versions of supported BF3 have been reported. The most recent and possibly most interesting for liquid-phase organic reactions involves the complexation of the Lewis acid with the surface of a silica support in the presence of a protic molecule, typically an alcohol (Figure 4.12).119 120... 

Alternatively, the solid acid can be prepared by incorporating the same reagent in a sol-gel preparation. The materials are catalytically active for a number of typically acid-catalysed liquid-phase organic reactions. These include the benzoylation of activated aromatics such as m-xylene and the alkylation of aromatics using alkenes. They are orders of magnitude more active than conventional acidic ion-exchange resins, but less active than some forms of supported aluminum chloride.125... 

Immobilization of such catalytically highly efficient HPA into an insoluble, readily recoverable solid acid is, therefore, an interesting and significant research target because environmentally benign solid-acid catalysts should replace problematic sulfuric acid and aluminum chloride. Several efforts have been made to immobilize HPA. Active carbon tightly entraps HPA inside its pores to form an insoluble solid acid that catalyzes liquid-phase organic reactions in polar media... 

Liquid-phase Organic Reactions over Silica-occluded H3PWj2O40... 

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