Mixing mechanisms involved

From a practical point of view, power consumption is perhaps the most important parameter in the design of stirred vessels. Because of the very different flow patterns and mixing mechanisms involved, it is convenient to consider power consumption in low and high viscosity systems separately. 

The second mechanism is a concerted (Sch. 7) rearrangement involving symmetry-allowed processes. The third mechanism is a mixed mechanism, involving one concerted process leading to radicals and followed by radical combination to give the ODPM rearrangement products. 

Interestingly, of the two chiral products 79 and 80, only the former was obtained optically active, while the latter was always racemic. This was reasonably accounted for in terms of mixed mechanisms, involving the concerted stereospecific [2tts + 2TTa] cyclodimerization to 79, and the stepwise dimerization to a mixture of 79-81 via biradical 82 with a loss of the optical activity of 78E induced photochemically [60]. 

SORPTION. A general term for the attraction between a layer and a solute, without specification of the type of physical mechanism (i.e., adsorption, partition, ion exchange) or mixed mechanism involved. Sorbent is a related general term referring to the layer itself. 

The interaction of acid chlorides (167 X = Cl) with imines in the presence of bases such as triethylamine may involve prior formation of a ketene followed by cycloaddition to the imine, but in many cases it is considered to involve interaction of the imine with the acid chloride to give an immonium ion (168). This is then cyclized by deprotonation under the influence of the base. Clearly, the distinction between these routes is a rather fine one and the mechanism involved in a particular case may well depend on the reactants and the timing of mixing. Particularly important acid chlorides are azidoacetyl chloride and phthalimidoacetyl chloride, which provide access to /3-lactams with a nitrogen substituent in the 3-position as found in the penicillins and cephalosporins. 

An important mixing operation involves bringing different molecular species together to obtain a chemical reaction. The components may be miscible liquids, immiscible liquids, solid particles and a liquid, a gas and a liquid, a gas and solid particles, or two gases. In some cases, temperature differences exist between an equipment surface and the bulk fluid, or between the suspended particles and the continuous phase fluid. The same mechanisms that enhance mass transfer by reducing the film thickness are used to promote heat transfer by increasing the temperature gradient in the film. These mechanisms are bulk flow, eddy diffusion, and molecular diffusion. The performance of equipment in which heat transfer occurs is expressed in terms of forced convective heat transfer coefficients. 

As shown in Figure 16.10, this reaction mechanism involves nucleophilic attack by —SH on the substrate glyceraldehyde-3-P to form a covalent acylcysteine (or hemithioaeetal) intermediate. Hydride transfer to NAD generates a thioester intermediate. Nucleophilic attack by phosphate yields the desired mixed carboxylic-phosphoric anhydride product, 1,3-bisphosphoglycerate. Several examples of covalent catalysis will be discussed in detail in later chapters. 

Carboxylic acids can also be activated by the formation of mixed anhydrides with various phosphoric acid derivatives. Diphenyl phosphoryl azide, for example, is an effective reagent for conversion of amines to amides.140 The proposed mechanism involves formation of the acyl azide as a reactive intermediate. 

A two-step mechanism must be assumed for this very valuable reaction of carboxylic acids with CDI.[9] Obviously the first step is a nucleophilic attack of the carboxylic acid or —depending on the acidity —the carboxylate ion on the carbonyl group of CDI, leading after elimination of imidazole to a mixed anhydride of imidazole-iV-carboxylic acid and the attacking carboxylic acid. This intermediate must have a very short life-time since it has not been detected down to — 50 °C. Rapid cleavage of CO2 from this mixed anhydride involves exclusively the carbonyl group linked to the imidazole unit If... 

Thus Saltiel has concluded that the small increase in [T]S/[C], in going from benzene to acetone indicates that a mixed mechanism is operative for acetone-sensitized isomerization, that is, both triplet energy transfer and, to a minor extent, Schenck intermediates are involved. When acetophenone or benzophenone is used as a sensitizer the pss is close to the thermodynamic... 

Rule 3 applies to heterogeneous reactions with mixed mechanisms i. e. radical and ionic. These will have their radical component enhanced by sonication although the general mechanical effect from Rule 2 may still apply. Two situations which may occur in heterogeneous systems involving two mechan-... 

Regioselective syntheses of 1,3,5-unsymmetrically substituted benzenes (309) are catalyzed by Pd(dba)2/PPh3 mixed alkyne/diyne reactants give mixtures containing homocoupled and mixed products (24 21 from HC CPh + HC=CC= CC Hn). The probable mechanism involves oxidative addition to the Pd(0) center, insertion of the second diyne into the Pd—H bond, reductive coupling and subsequent jr-complexation of this product to Pd(0), followed by Diels-Alder cycloaddition of the third diyne and elimination of product. 

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