Addition reactions, Michael, catalytic

Acrylonitrile, polymerization, 120 Activity of phase-transfer catalysts Sjj2 reactions, 170-175 weak-nucleophile Sj.Ar reactions, 175-182 Acyltetracarbonyl cobalt compound, cleavage in the carboxyalkylation of alkyl halides, 150 Addition reactions, Michael, catalytic asymmetric, 69,70f... 

In particular, a,P-unsaturated aldehydes seldom give 1,4 addition. The Michael reaction has traditionally been performed in protic solvents, with catalytic amounts of base, but more recently better yields with fewer side reactions have... 

There is a possibiUty that (hydroxymethyl)phosphines might be catalyzing hydration of activated olefinic moieties in lignin. The Michael addition reaction shown in eq. (6a) is catalyzed by 5% THP in water at ambient conditions, with 70% conversion of the acrylonitrile no such reaction is seen with aciyhc acid or the methyl ester, but analogous hydromethoxylation of these compounds is seen in MeOH (42) (eq. (6b), R = H or Me). There is a report on similar catalytic use of tiialkylphosphines, which, like THP, are strong nucleophiles (43). 

However, when 2,6-dimethylbenzoquinone with sodium ( >3,5-hexadienoate (generated in situ) was reacted in water in the presence of a catalytic amount of sodium hydroxide, pentacyclic adducts were formed via deprotonation of the Diels-Alder adduct followed by tandem Michael-addition reactions with another molecule of 2,6-dimethylbenzoquinone (Eq. 12.25).83 Similar results were obtained with sodium ( >4,6-heptadienoate. 

Heterobimetallic asymmetric complexes contain both Bronsted basic and Lewis acidic functionalities. These complexes have been developed by Shibasaki and coworkers and have proved to be highly efficient catalysts for many types of asymmetric reactions, including catalytic asymmetric nitro-aldol reaction (see Section 3.3) and Michael reaction. They have reported that the multifunctional catalyst (f )-LPB [LaK3tris(f )-binaphthoxide] controls the Michael addition of nitromethane to chalcones with >95% ee (Eq. 4.140).205... 

A dodecakis(NCN-Pdn) catalyst, synthesized in the group of Van Koten (Figure 4.24), was applied in the a continuous double Michael addition reaction between methyl vinyl ketone (MVK) and ethyl a-cyanoacetate.[34] The reaction was performed in the deadend reactor discussed in paragraph 4.2.1. Two catalytic runs were performed differing in the amount of catalyst and in the applied flow (both increased by a factor 2.5). Both runs showed high productivity for more than 24 h (Figure 4.25). 

But catalytic reduction of the same phenyl propionic acid gives cis cinnamic acid. Therefore by adding hydrogen under various conditions, one can obtain a desired isomer. The conversion of acetylene into olefinic compounds has been carried out not only for the sake of obtaining the adduct, but Michael studied the various addition reactions for the sake of obtaining a desired product cis or trans. For example, he found that the addition of bromine to acetylene-dicarboxylic acid leads predominantly to the formation of trans isomer. 

Typical acceptors in Michael additions are reducible and their radical anions often undergo dimerization (hydrodimerizations). Either the radical anions or more likely the dimer dianions can act as EGBs toward the donor in the Michael addition. Since the reaction is catalytic in base when the product anion is more basic than the donor anion, the Michael addition can take place by reduction of a small fraction (2-10%) of the acceptor [129]. The reaction takes place in 20 to 77% yield... 

Superoxide anion formed in situ in a solution exposed to air (i.e. with only a small concentration of O2) has been used as an EGB to generate nitroalkane anions that may add to activated alkenes or to carbonyl compounds [130, 131]. An example is shown in Scheme 33. The reaction is catalytic since the product anion can act as a base toward the nitroalkane. Using the nitroalkane as the solvent favors the proton transfer pathway over the competing addition of the product anion to a second molecule of activated alkene, a pathway that may lead to polymerization [130]. In some cases, better yields of the Michael addition product were obtained if a stoichiometric amount of the anion was formed ex situ (with O2 as the PB), and the activated alkene added subsequently ]130, 132]. 

Michael Reactions The Michael and analogous conjugate addition reactions represent a cornerstone of classical and modern chemical synthesis, and not surprisingly, therefore, catalytic variants of this venerable reaction have received... 

The yields obtained after 10 min in a batch reactor with MgO, CaO, or SrO exceeded 92%, whereas with BaO the yield was lower (72%), probably because of its low surface area (2m /g). When alkaline earth hydroxides were used as basic catalysts, the yields were lower than for the corresponding oxides. The most active hydroxides were Sr(OH)2 8H2O and Ba(OH)2 8H2O, which gave the additional compound in yields of 75% and 70%, respectively, whereas carbonates were characterized by very poor activity. As observed for other reactions, the catalytic activity of MgO strongly depends on the pre-treatment temperature. A maximum in activity was observed when MgO was pre-treated at 673 K. At this temperature, decomposition of Mg(OH)2 to MgO is not complete, and Mg(OH)2 remains in the catalyst. It was suggested that the surface OH groups act as active sites, as for the Michael addition reactions described above. 

The Michael reactions [149-152] between cyclohexanone and trons-nitroalkenes were also explored by Xiao and co-workers utilizing bifunctional pyrrolidine-thiourea 213 and the pyrrolidine-thioureas 214-217 (Figure 6.61) [344]. The model Michael reaction between cyclohexanone and trons-nitrostyrene identified water as the best solvent and 217 to be the most efficient catalysts concerning the activity and asymmetric induction (90% yield 96% ee dr 98 2 in 12 h at 35 °C) in the presence of benzoic acid (10mol%) as additive. The optimized catalytic system allowed the formation of a broad spectrum of Michael adducts such as 1-6 resulting from... 

The conjugate addition of heteronucleophiles to activated alkenes has been used very often in organic synthesis to prepare compounds with heteroatoms [3 to various activating functional groups, e.g. ketones, esters, nitriles, sulfones, sulfoxides and nitro groups. As in the Michael reaction, a catalytic amount of a weak base is usually used in these reactions (with amines as nucleophiles, no additional base is added). 

In the catalytic presence of tetrabutylammonium fluoride, a trimethylsilyl group is cleaved from AKtrimethylsilyl)rnethylbenzylimine to form the resonance-stabilized 2-aza-allyl anion which undergoes a Michael addition reaction with, for example, methyl acrylate, giving y-aminoesters.333 These types of aminoesters serve as a starting material for the elaboration of diversely substituted pyrrolidones.334... 

Next, the mechanism of the Type II reactions is discussed. To discriminate one of the enantiofaces of the acceptor it is desirable to place and to activate the electrophiles in a chiral environment. At the same time, effective activation of the Michael donor is required. In Shibasaki s ALB-catalyzed reaction (Scheme 3), it was proposed that the aluminum cation functioned as a Lewis acid to activate enones at the center of the catalyst, and that the Li-naphthoxide moiety deproton-ated the a-hydrogen of malonate to form the Li enolate (Scheme 9). Such simultaneous activation of both reactants at precisely defined positions became feasible by using multifunctional heterobimetallic complexes the mechanism is reminiscent of that which is operative in the active sites of enzymes. The observed absolute stereochemistry can be understood in terms of the proposed transition state model 19. Importantly, addition of a catalytic amount of KOt-Bu (0.9equiv. to ALB) was effective in acceleration of the reaction rate with no deterioration of the... 

The third part of this chapter reviews previously described catalytic asymmetric reactions that can be promoted by chiral lanthanoid complexes. Transformations such as Diels-Alder reactions, Mukaiyama aldol reactions, several types of reductions, Michael addition reactions, hydrosilylations, and hydroaminations proceed under asymmetric catalysis in the presence of chiral lanthanoid complexes. 

The mechanism for the Michael reaction is shown in Figure 20.6. Only a catalytic amount of base is needed because the initial adduct is itself an enolate anion and is basic enough to deprotonate the dicarbonyl compound, allowing additional reaction to occur. Other examples of the Michael reaction are provided in the following equations ... 

Several catalytic protocols have been developed for the 1,4-addition of silylcopper reagents to enones and other Michael acceptors. Lipshutz et al.183 treated phenyldimethylsilyllithium with dimethylzinc and used the silylzinc reagent PhMe2SiZnMe2Li thus formed as the nucleophile in copper-catalyzed 1,4-additions to various enones and enals, for instance, verbenone 248 which afforded the desired product 249 in almost quantitative yield (Equation (14)). Interestingly, the rather slow addition reaction is strongly accelerated by catalytic amounts of scandium triflate. 

Vinyl and ethynyl groups attached to an imidazole ring can be catalytically reduced to the saturated (or less unsaturated) species and cleaved by oxidation. The corresponding 4-carbaldehyde is formed in 71% yield when l-methyl-2,5-diphenyl-4-styrylimidazole is oxidized with osmium tetroxide. However, they may not react like aliphatic alkenes and alkynes not all addition reactions occur normally, Michael additions are known, and the compounds can act as dienophiles in DielsAlder reactions (e.g., Scheme 132). 

A related one-pot three component coupling reaction leading to allyli-dene tetrahydrofuran derivatives 80 and which combines a conjugate addition of a propargyl alcohol with an activated olefin and an in situ palladium-catalyzed carbopalladation-cyclization in the presence of a large excess of allyl chloride has been recently developed by Lu and Iiu (Scheme 31) [77]. The cyclization process is here initiated by addition of a catalytic amount of Pd(OAc)2 and in marked contrast with the above-discussed reactions, a catalytic cycle involving divalent palladium proceeds in the reaction. In this process, the ester enolate formed in the Michael addition undergoes... 

Figure 2.3, the Michael addition reactions of P-nitrostirenes (10) with 4-pentene-l-magnesium bromide (11a) or 3-butene-1-magnesium bromide (11b) generated the nitronates (12) or (13). Satisfactory to high yields of isoxazolidine derivatives (16) and (18) were obtained when nitronates (12) or (13) were treated, in situ, with ethyl chloroformate and catalytic amount of 4-dimethylaminopyridine (DMAP). 

---