Catalysts bifunctional cyclization

Scheme 6.141 Mechanistic proposal for the 121-catalyzed asymmetric intramolecular Michael addition exemplified for the model substrates ( )-4-hydroxy-l-phenyl-2-buten-l-one (n = 0) and ( )-5-hydroxy-l-phenyl-2-buten-l-one (n = 1) 121 functions as push/pull-type bifunctional catalyst inducing the cyclization of boronic acid hemiester (1) to form intermediate (2) release ofdiol product (3) by oxidation.

Dieb-Alder catalyst. The key step in a recent total synthesis of androstanes is a SnCVcatalyzed Diels-Alder reaction of 1 with the (Z)-dienophile 2. The geometry of the diene favors addition ami to the C,0-methyl group, and the catalyst promotes the desired enrfo-orientation. A1C1, and BF3 ctherate are less suitable for additions involving aliphatic bifunctional dienophiles. The initial adduct a can be isolated, but in only 15-20% yield. The synthesis of the androstane 4 is completed by ketalizatioh of 3 followed by a novel cyclization affected with dimsylsodium. ... 

Dual-function catalysts possessing both metallic and acidic sites bring about more complex transformations. Carbocationic cyclization and isomerization as well as reactions characteristic of metals occurring in parallel or in subsequent steps offer new reaction pathways. Alternative reactions may result in the formation of the same products in various multistep pathways. Mechanical mixtures of acidic supports (silica-alumina) and platinum gave results similar to those of platinum supported on acidic alumina.214,215 This indicates that proximity of the active sites is not a requirement for bifunctional catalysis, that is, that the two different functions seem to operate independently. 

As seen in Figure 2.2 and from the corresponding discussion, dehydrocyclization is a key reaction in forming aromatic compounds.307 A study comparing dehydrocyclization over mono- and bifiinctional catalysts at atmospheric pressure and high pressure representative of naphtha reforming conditions concludes that primary aromatic products at all pressures are formed by direct six-carbon ring formation.313 Over bifunctional catalysts the acid-catalyzed cyclization is more rapid... 

The situation is much different when an acidic support is used. First, the C8 aromatic products have a distribution that approaches an equilibrium composition. The Pt catalyst on an acidic support is both more active and produces aromatics more selectively than Pt on a nonacidic support (84). It is concluded that the bifunctional mechanism involving cyclization by the acid site followed by a bifunctional ring expansion/dehydrogenation reactions is much more rapid than the monofunctional metal catalyzed dehydrocyclization reaction. For the catalyst based on an acidic support, the tin added initially acts as a catalyst poison (Figure 5), at least during the initial 1-2 weeks of usage. 

The catalyst is called bifunctional both the carrier and the metallic particles dispersed over the carrier exhibit different catalytic functions. The carrier contains chlorine ions and, as a consequence, it has acid properties and exhibits isomerization and cyclization activities. The metal particles consist of alloys of, for example, Pt/Re which exhibit hydrogenation/dehydrogenation activity. 

Annulation to carbonyl functions has also been achieved with Trost s bifunctional reagents. Whereas the parent silyl acetate (97) yields only simple alkylation products with aldehydes under normal conditions, addition of only a few mole % of trimethyltin acetate to the reaction mixture results in facile formation of methylenetetrahydrofurans Furthermore, excellent diastereoselectivity is observed in the cycloaddition to a galactose-derived aldehyde (125) (equation 136). The tin acetate co-catalyst also promotes addition to relatively unreactive ketone carbonyls, such as in the case of benzofuran (126) and the acetylenic ketone (127) (equations 137, 138). It is remarkable that even the sterically hindered enone (128) reacts preferentially at the ketone function (equation 139). A tributyltin analog (129) of (97) has been used in the stepwise formation of a methylenetetrahydrofuran from aldehydes. Similarly, pyrrolidines can be prepared from the corresponding imines in two steps via a Lewis acid-catalyzed 1,2-addition of the tin reagent, which is then followed by a Pd-catalyzed cyclization (equation 140). Direct formation of pyrrolidine from the imine is possible if one uses a mesylate analog of (97) and a nickel(O) catalyst (equation 141). ... 

On the other hand, there is the question of the close relationship between coke formation (catalyst stability) and aromatics cyclization (catalyst selectivity) over the acid sites present in the zeolites. On naphtha reforming, coke formation is a bifunctional reaction requiring the dehydrogenation capacity of the metallic function and the condensation capacity of the acidic function. Therefore, it is interesting to... 

Further applications of chiral ketene enolates to formal [4 + 2] type cyclization using the above-mentioned bifunctional catalyst systems have recently been discovered independently by the Lectka [48] and Nelson groups [49]. This highly interesting topic is discussed in Chapter 9 in detail. 

In the same year, Connon and coworkers [63] reported that the chiral bifunctional cinchona alkaloid-based thiouea 81a is also able to catalyze the addition of dimethyl chloromalonate 196 to nitroolefins 124, leading to the Michael adduct that cyclizes to form the cyclopropane 197 in the presence of DBU. Almost single diastereomeric nitrocyclopropanes (>98% de) were obtained in good yields. However, the enantios-electivity obtained with this type of catalyst was poor (<47% ee) (Scheme 9.69). 

For 1-hexene isomerization and for acid catalyzed Cg aromatic reactions all molecular sieves were evaluated in their calcined, powdered state. For the study of Cg aromatics, selected SAPO molecular sieves were aluminum exchanged or steam treated as noted in Table IV. For bifunctional catalysts used in paraffin cyclization/isomerization and ethylbenzene-xylene interconversions, the calcined molecular sieve powder was mixed with platinum-loaded chlorided gamma alumina powder. These mixtures were then bound using silica sol and extruded to form 1/16" extrudates which were dried and calcined at 500°C. The bifunctional catalysts were prepared to contain about 0.54 platinum and about 40 to 504 SAPO molecular sieve in the finished catalysts. 

Similarly, the formylpyrrolidine compound (108) was reduced with an excess of Raney nickel to afford the amino intermediate, which was then treated with trifluoroacetic acid in dichloromethane-methanol to result in cyclization, thus giving rise to the pyrrolidinobenzothiadiazepine (109) (75% yield) <89H(29)1529>. The ethoxycarbonyl derivative (110) was also reduced with iron powder in glacial acetic acid to form the corresponding amino derivative, which was then cyclized to the 1,2,5-benzothiadiazepin-4-one (111) (60% yield) by heating at 170°C in the presence of 2-hydroxypyridine as a bifunctional catalyst <92SC1433>. 

Giannetto has discussed dehydrocyclodimerization, i.e., the conversion of propane and butane to BTX aromatics over bifunctional catalysts (e.g., Ga-ZSM-5). The reaction occurs stepwise dehydrogenation, oligomerization, cyclization, and dehydrogenation follow each other. Some of these reaction steps are catalysed by the dehydrogenation function of the gallium, some by the acid sites of the ZSM-5, and some by both. Aromatization is a primary reaction on Ga-ZSM-5 but only a secondary one on H-ZSM-5. 

Highly functionalized tetrahydropyran-4-ones can be obtained through a silyl enol ether Prins cyclization promoted by a condensation reaction of hydroxy silyl enol ethers with Lewis-acid-activated aldehydes, with high diastereoselectivity (14JOC8733). Spirooxindole tetrahydropyran-4-ones are obtained from oxa-DA reaction of acyclic a,P-unsaturated methylke-tones and isatins mediated by a bifunctional enamine-metal Lewis acid catalyst, in good yields and moderate stereoselectivities (14S1339). 

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