Addition reactions, solvent effects

In addition to the boron trifluoride-diethyl ether complex, chlorotrimcthylsilanc also shows a rate accelerating effect on cuprate addition reactions this effect emerges only if tetrahydrofuran is used as the reaction solvent. No significant difference in rate and diastereoselectivity is observed in diethyl ether as reaction solvent when addition of the cuprate, prepared from butyllithium and copper(I) bromide-dimethylsulfide complex, is performed in the presence or absence of chlorotrimethylsilane17. If, however, the reaction is performed in tetrahydrofuran, the reaction rate is accelerated in the presence of chlorotrimethylsilane and the diastereofacial selectivity increases to a ratio of 88 12 17. In contrast to the reaction in diethyl ether, the O-silylated product is predominantly formed in tetrahydrofuran. The alcohol product is only formed to a low extent and showed a diastereomeric ratio of 55 45, which is similar to the result obtained in the absence of chlorotrimethylsilane. This discrepancy indicates that the selective pathway leading to the O-silylated product is totally different and several times faster than the unselective pathway" which leads to the unsilylated alcohol adduct. A slight further increase in the Cram selectivity was achieved when 18-crown-6 was used in order to increase the steric bulk of the reagent. 

Apart from these SET reactions, solvent effects in reactions of organomagnesium reagents with carbonyl compounds have been studied rather extensively. The reaction of ethylmagnesium bromide with benzophenone (Scheme 15) in diethyl ether yields 94% of the expected addition reaction product, 1,1-diphenyl-1-propanol, and 6% benzhydrol, resulting from a reduction reaction of the Grignard reagent [36]. In tetrahydrofuran this reaction yields 21 and 77%. respectively, of both products. 

For irradiation at a higher dose rate, the radical-radical combination reactions (R6) wiU efficiently occur and compete with the addition reactions of radicals and solute molecules to initiate the polymerization (R2), while the addition reactions (R2) effectively occur during irradiation at a lower dose rate, because of the reduction of radical loss (Nakagawa 2010). This will lead to an increased polymer yield with a decreasing dose rate. As solvent radicals work not only as an initiator (R2) but also the terminator (R4) of polymerization, the probability for polymer radicals to terminate with solvent radicals (R4) will be less by irradiation at a lower dose rate. This will make it easy for polymer radicals (R5) to produce a polymer with a higher molecular weight. 

It is not difficult to incorporate this observation into the general mechanisms for hydrogen halide additions. These products are formed as the result of solvent competing with halide as the nucleophilic component of the addition reaction. Solvent addition can occur via the concerted mechanism or through a carbonium ion mechanism. Added halide salts can serve as a halide ion source, which increases the likelihood of capture of the carbonium ion intermediate by halide ion. The effect of halide salts can be detected kinetically. For example, the presence of tetramethylam-monium chloride increases the rate of addition of hydrogen chloride to cyclohexene. Similarly, lithium bromide increases the rate of addition of hydrogen bromide to cyclopentene." ... 

Ortho-cycloaddition takes place with a olefin which has low ionization potential in comparison to benzene where polar nature of reaction overpowers the symmetry imposed barrier to this reaction. Polar nature of ortho-cyclo-addition is supported by the fact that in case of doner substituted ethylenes, reaction is promoted by polar solvent, but in meta-addition no solvent effect is there, o-and p-photocycloadditions are disallowed to occur as concerted addition between of benzene and Sq of alkene until mixing of charge-transfer states occurs. 

The reaction of 1-octyne with PhSeH in the presence of Pd(OAc)2 in benzene at 80°C for 15 h provided the Markovnikov-type adduct, 2-(phenylseleno)-l-octene (1) in 62% yield (1) [21], The reaction conducted in toluene with employing 40 mol% of pyridine or 2,2 -bipyridyl as an additive produced 1 in 38 or 63% yields, respectively. In addition, the solvent effect is remarkable and pyridine is the best solvent to form 1 (2). 

These effects can be attributed mainly to the inductive nature of the chlorine atoms, which reduces the electron density at position 4 and increases polarization of the 3,4-double bond. The dual reactivity of the chloropteridines has been further confirmed by the preparation of new adducts and substitution products. The addition reaction competes successfully, in a preparative sense, with the substitution reaction, if the latter is slowed down by a low temperature and a non-polar solvent. Compounds (12) and (13) react with dry ammonia in benzene at 5 °C to yield the 3,4-adducts (IS), which were shown by IR spectroscopy to contain little or none of the corresponding substitution product. The adducts decompose slowly in air and almost instantaneously in water or ethanol to give the original chloropteridine and ammonia. Certain other amines behave similarly, forming adducts which can be stored for a few days at -20 °C. Treatment of (12) and (13) in acetone with hydrogen sulfide or toluene-a-thiol gives adducts of the same type. 

Purification of a chemical species by solidification from a liquid mixture can be termed either solution crystallization or ciystallization from the melt. The distinction between these two operations is somewhat subtle. The term melt crystallization has been defined as the separation of components of a binaiy mixture without addition of solvent, but this definition is somewhat restrictive. In solution crystallization a diluent solvent is added to the mixture the solution is then directly or indirec tly cooled, and/or solvent is evaporated to effect ciystallization. The solid phase is formed and maintained somewhat below its pure-component freezing-point temperature. In melt ciystallization no diluent solvent is added to the reaction mixture, and the solid phase is formed by cooling of the melt. Product is frequently maintained near or above its pure-component freezing point in the refining sec tion of the apparatus. 

A decisive solvent effect is also observed with other a,/ -epoxy ketones. Specifically, 3jS-hydroxy-16a,17a-epoxypregn-5-en-20-one and its acetate do not react with thiocyanic acid in ether or chloroform. However, the corresponding thiocyanatohydrins are formed by heating an acetic acid solution of the epoxide and potassium thiocyanate. As expected, the ring opening reaction is subject to steric hindrance. For example, 3j6-acetoxy-14f ,15f5-epoxy-5) -card-20(22)-enoIide is inert to thiocyanic acid in chloroform, whereas the 14a,15a-epoxide reacts readily under these conditions.Reactions of 14a,15a-epoxides in the cardenolide series yields isothiocyanatohydrins, e.g., (135), in addition to the normal thiocyanatohydrin, e.g., (134). 

The reactions of enamines as 1,3-dipolarophiles provide the most extensive examples of applications to heterocyclic syntheses. Thus the addition of aryl azides to a large number of cyclic (596-598) and acyclic (599-602) enamines has led to aminotriazolines which could be converted to triazoles with acid. Particular attention has been given to the direction of azide addition (601,603). While the observed products suggest a transition state in which the development of charges gives greater directional control than steric factors, kinetic data and solvent effects (604-606) speak against zwitterionic intermediates and support the usual 1,3-dipolar addition mechanism. 

Both reactions were carried out under two-phase conditions with the help of an additional organic solvent (such as iPrOH). The catalyst could be reused with the same activity and enantioselectivity after decantation of the hydrogenation products. A more recent example, again by de Souza and Dupont, has been reported. They made a detailed study of the asymmetric hydrogenation of a-acetamidocin-namic acid and the kinetic resolution of methyl ( )-3-hydroxy-2-methylenebu-tanoate with chiral Rh(I) and Ru(II) complexes in [BMIM][BF4] and [BMIM][PFg] [55]. The authors described the remarkable effects of the molecular hydrogen concentration in the ionic catalyst layer on the conversion and enantioselectivity of these reactions. The solubility of hydrogen in [BMIM][BF4] was found to be almost four times higher than in [BMIM][PFg]. 

An analogous solvent effect was observed upon treatment of the chiral a-alkoxy aldehyde 11 with 2-lithio-4-methylfuran in the presence of zinc bromide. This highly diastereoselective addition reaction was the key step in a synthesis of the enantiomcrically pure C-10-C-20 fragment of the immunosuppressant KK 506139. 

Similar additions may be performed with the enamine 13. However, with 3-buten-2-one or methyl 2-propenoate Lewis acid catalysis is needed to activate the Michael acceptor chloro-trimethylsilane proved to be best suited for this purpose. A remarkable solvent effect is seen in these reactions. A change from THF to HMPA/toluene (1 1) results in a reversal of the absolute configuration of the product 14, presumably due to a ligand effect of HMPA235. 

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