Reaction parameters solvent

The stereoisomers of olefin saturation are often those derived by cis addition of hydrogen to the least hindered side of the molecule (99). But there are many exceptions and complications (97), among which is the difficulty of determining which side of the molecule is the least hindered. Double-bond isomerization frequently occurs, and the hydrogenation product is the resultant of a number of competing reactions. Experimentally, stereochemistry has been found to vary, sometimes to a marked degree, with olefin purity, reaction parameters, solvent, and catalyst 30,100). Generalizing, it is expedient, when unwanted products arise as a result of prior isomerization, to avoid those catalysts and conditions that are known to favor isomerization. 

The practical aspects of the dilution principle, i.e., the choice between different possible reactants and reaction parameters (solvent, rate of addition, amount of solvent), are determined as empirically today as in those days when the basic ideas of the principle were developed. Quantitative approaches were attempted by several authors but the pretension of a complete mathematical description considering the multitude of possible types of reactions is rather illusory. One can only hope to obtain general rules for the experimental procedure. Some of thrae approaches are outlined briefly ... 

The observed regioselectivity can be perturbed to varying degrees by choice of reaction parameters. Solvent polarity can play a role in the control of regioselectivity, as would be predicted by the polar exci-plex model. The regioselectivity of the dimerization of cyclopentenone (equation 11) produces a larger proportion of the head-to-head adduct in more polar solvents. The photoaddition of enone (11) to al-kene (12) also displays a pronounced solvent dependence (equation 12). A consequence of the solvent effect is that nonpolar solvents tend to produce products which would be predicted from the polar exci-plex model, while more polar solvents result in somewhat more of the minor product but do not cause complete reversal of the regioselectivity. 

The Knoevenagel condensation reaction of benzaldehyde with ethylcyanoacetate (Scheme 1) was first studied on CsNaY 7Cs in order to check the better conditions to control the different reaction parameters (solvent effect on the rate and on the selectivity of the uncatalyzed and catalyzed reactions, mass effect of the catalyst, concentration effect of both reactants) [21],... 

However, gas substrates such as carbon monoxide (CO) can be easily introduced in a packed-bed reactor. ThanesNano researchers reported aminocarbonylation of aryl halides with amines and CO gas at high pressure and high temperature under flow conditions, which afforded the corresponding amides in moderate-to-high yield (Scheme 7.24) [101]. In this paper, they described that reaction parameters (solvent, base, catalyst, pressure, temperature, and so on) were rapidly optimized in the reactions, which required less than 2 min. As a continuous study, the authors reported a double carbonylation reaction of iodobenzene to give a-ketoamides in a flow reactor [102]. 

Treatment of Decalin with acetyl chloride and aluminum chloride in ethylene chloride as solvent gives a complex mixture of products as shown (15). By variation of the reaction parameters, however, it is possible to maximize the yield of the remarkable reaction product, 10 j3-vinyl-/m j-Decalin l/8,r oxide (5). This vinyl ether undoubtedly... 

Various rules have been devised with partial success (70,30,99), but it is difficult to formulate encompassing generalities in a reaction subject to the influence of so many reaction parameters, The stereochemislrycan be affected importantly by the catalyst (35,36,64,65,77,89,94), solvent (63), substrate structure, and haplophilic effects (77). 

Aziridines, like oxiranes, undergo hydrogenolysis easily with or without inversion of configuration, depending on the catalyst, reaction parameters, and various additives 65aJ08). For example, hydrogenolysis of 2-methyl-2-phenylaziridine in ethanol occurs mainly with inversion over palladium but with retention over platinum, Raney nickel, or Raney cobalt. Benzene solvent or alkali favor retention over palladium as well. 

A closely related asymmetric synthesis of chiral sulphoxides, which involves a direct oxidation of the parent sulphides by t-butylhydroperoxide in the presence of metal catalyst and diethyl tartrate, was also reported by Modena and Di Furia and their coworkers-28-7,288 jjje effect 0f the reaction parameters such as metal catalyst, chiral tartrate and solvent on the optical yield does not follow a simple pattern. Generally, the highest optical purities (up to 88%) were observed when reactions were carried out using Ti(OPr-i)4 as a metal catalyst in 1,2-dichloroethane. 

Also the impact of various reaction parameters on enzymatic synthesis of amide surfactants from ethanolamine and diethanolamine has been studied, although the possibilities of acyl migration are not investigated. However, it was found that the selectivity of the reaction depended on the solubility of the product in the solvent used, and that the choice of solvent was critical to obtain an efficient process [17]. 

To pursue the development of environmentally benign synthesis routes for ionic liquids, the alkylation step (Menschutkin reaction) was investigated by the authors in detail. The preparation of the ionic liquid 1-hexyl-3-methyhmidazohum chloride ([CeMlMJCl) was taken as a representative experiment (Scheme 7.2). The process parameters temperature (T = 70-100°C), solvent (ethanol, xylene, cyclohexane, n-heptane, solvent free), concentration of the N-base (c = 1.6-6.7 M), molar ratio n n = 1 0.5-1 4) and reaction time (f = 10-144 h) were investigated. In addition, the N-base was altered in order to proof the transferability of the reaction parameters. 

The tuning of solubility with a relatively small jump or fall in pressure can possibly bestow many benefits with respect to rates, yields, and selectivity. Reaction parameters can be changed over a wide range. Replacement of solvents with high boiling points by supercritical (SC) fluids offers distinct advantages with respect to removal of the solvent. SC fluids like CO2 are cheap and environmentally friendly the critical temperature of CO2 is 31 C and the critical pressure 73.8 atm (Poliakoff and Howdle, 1995). Eckert and Chandler (1998) have given many examples of the use of SC fluids. Alkylation of phenol with tcrt-butanol in near critical water at 275 °C allows 2- erf-butyl phenol to be formed (a major product when the reaction is kinetically controlled 4-rert-butyl phenol is the major product, when the reaction is... 

Since around 1950, in studies of solvent effects for organic reactions, empirical solvent parameters have been used these parameters represent the capabilities of solvents for the solute-solvent interactions (especially Lewis acid-base interactions). Though the solute-solvent interactions should depend on the solute as well as on the solvent, the empirical solvent parameters are considered to be irrelevant to solutes in other words, the use of only these parameters enables us to evaluate the solvation energies. Strictly... 

The enantioselective hydrogenation of a,p-unsaturated acids or esters, using 5wt% Pt/Al203 or Pd/Al203 commercial catalysts doped with cinchonidine (CD), was deeply investigated to evidence the specific activity of Pd or Pt and the role of the reaction parameters and solvent polarity. Finally, the steric and electronic effects of different substituent groups were also studied. 

Fundamental studies of coal liquefaction have shown that the structure of solvent molecules can determine the nature of liquid yields that result at any particular set of reaction conditions. One approach to understanding coal liquefaction chemistry is to use well-defined solvents or to study reactions of solvents with pure compounds which may represent bond-types that are likely present in coal [1,2]. It is postulated that one of the major routes in coal liquefaction is initiation by thermal activation to form free radicals which abstract hydrogen from any readily available source. The solvent may, therefore, function as a direct source of hydrogen (donor), indirect source of hydrogen (hydrogen-transfer agent), or may directly react with the coal (adduction). The actual role of solvent thus becomes a significant parameter. 

Using the results of an earlier study concerning enantioselective copper-catalyzed intramolecular C—H insertion of metal carbenoids,109 an interesting system for optimizing the proper combination of ligand, transition metal, and solvent for the reaction of the diazo compound (75) was devised (see Scheme 19).110 The reaction parameters were varied systematically on a standard 96-well microtiter/filtration plate. A total of five different ligands, seven metal precursors, and four solvents were tested in an iterative optimization mode. Standard HPLC was used to monitor stereoselectivity following DDQ-induced oxidation. This type of catalyst search led to the... 

The issue of parallel versus sequential synthesis using multimode or monomode cavities, respectively, deserves special comment. While the parallel set-up allows for a considerably higher throughput achievable in the relatively short timeframe of a microwave-enhanced chemical reaction, the individual control over each reaction vessel in terms of reaction temperature/pressure is limited. In the parallel mode, all reaction vessels are exposed to the same irradiation conditions. In order to ensure similar temperatures in each vessel, the same volume of the identical solvent should be used in each reaction vessel because of the dielectric properties involved [86]. As an alternative to parallel processing, the automated sequential synthesis of libraries can be a viable strategy if small focused libraries (20-200 compounds) need to be prepared. Irradiating each individual reaction vessel separately gives better control over the reaction parameters and allows for the rapid optimization of reaction conditions. For the preparation of relatively small libraries, where delicate chemistries are to be performed, the sequential format may be preferable. This is discussed in more detail in Chapter 5. 

A simple, efficient, and high-yielding synthesis of quinazolin-4-ylamines and thieno[3,2-d]pyridin-4-ylamines based on the condensation of appropriately functionalized N -(2-cyanophenyl)-N,N-dimethylformamidines and primary amines has been reported by Han and coworkers (Scheme 6.253) [440]. Optimization of the reaction parameters resulted in the use of acetonitrile/acetic acid as a solvent mixture and of 1.2 equivalents of the requisite amine. In general, microwave heating at 160 °C for 10 min provided excellent product yields. 

Aldol reaction of keto-acid 21 with aldehyde 10 and esterification of the resulting acids with alcohol 22 led rapidly to cyclization precursor 23 and its 6S,7R-diastereomer (not shown). RCM using ruthenium initiator 3 (0.1 equiv) in dichloromethane (0.0015 M) at 25 °C afforded macrolactones 24a and 24b in a 1.2 1 ratio. Deprotection and epoxidation of the desired macrolactone, 24a, afforded epothilone A (4) via 25a (epothilone C) (Scheme 5). Varying a number of reaction parameters, such as solvent, temperature and concentration, failed to improve significantly the Z-selectivity of the RCM. However, in the context of the epothilone project, the formation of the E-isomer 24b could actually be viewed as beneficial since it allowed preparation of the epothilone A analog 26 for biological evaluation. 

---