Transition reactions using polymer-supporte

The RuH2(PPh3)4-catalyzed addition of active methylene compounds can also be applied to conjugate additions to a,/3-unsaturated carbonyl compounds (Michael additions). In 1989, Murahashi reported the first example of the transition metal-catalyzed Michael addition of active methylene compounds [74]. One of the notable advances of this catalytic reaction is that the addition of C-H bonds to a,/3-unsaturat-ed carbonyl compounds give Michael adducts without contamination by the corresponding aldol products (Eq. 9.56) [74]. Recently, Murahashi applied their aldol and Michael addition reactions to a solid-phase synthesis using polymer-supported nitriles (Scheme 9.12) [76]. In this case, four component reactions took place with high diastereoselectivity. 

Polyquiaolines have been used as polymer supports for transition-metal cataly2ed reactions. The coordinatkig abiUty of polyqukioline ligands for specific transition metals has allowed thek use as catalysts ki hydroformylation reactions (99) and for the electrochemical oxidation of primary alcohols (100). 

Transition-metal organometallic catalysts in solution are more effective for hydrogenation than are metals such as platinum. They are used for reactions of carbon monoxide with olefins (hydroformyla-tion) and for some ohgomerizations. They are sometimes immobihzed on polymer supports with phosphine groups. 

Abstract An overview on the microwave-enhanced synthesis and decoration of the 2(lH)-pyrazinone system is presented. Scaffold decoration using microwave-enhanced transition-metal-catalyzed reactions for generating structural diversity, as well as the conversion of the 2(lH)-pyrazinone skeleton applying Diels-Alder reactions to generate novel heterocyclic moieties are discussed. The transfer of the solution phase to polymer-supported chemistry (SPOS) is also described in detail. 

Three approaches have been tested, as already described above for inorganic supports. The first attempts concern the direct reaction of transition metal carbonyls with unmodified organic polymers like poly-2-vinyl-pyridine.61 62 However, this kind of anchoring is restricted to only a few complexes. Various polymers have been functionalized with donor groups 63-72 ligand displacement reactions using these afforded the corresponding immobilized complexes. Finally, tests with modified complexes and unmodified polymers are scarce because of the low stability of these complexes under the conditions of reactions. 

The Fischer-Tropsch activity of resin 5 and the unique reaction conditions have important consequences. The use of a reaction solvent raises the possibility of controlling heat removal in this appreciably exothermic process. The apparent homogeneous nature of the catalytic species suggests that other soluble Fischer-Tropsch catalysts may be forthcoming. Finally, CpCo-(00)2 possesses catalytic activity not found in soluble CpCo-(00)2 this demonstrates that attachment to a polymer support not only may induce changes in catalytic activity of a transition metal complex, but also might give rise to completely new activity (51,52,53). 

Although much work has already been devoted to the use of polysoaps in micellar cataylsis application, in particular as models for esterases [79] and systems for photochemical catalyzed reactions [80], only a few reports have appeared on the use of such polymer supports in transition metal catalysis. 

The counter-ions of some of the quaternary onium groups were exchanged with an anionic phosphine compound, which was then used to complex palladium. Thus, a polymer material containing phase transfer catalyst and transition-metal catalyst groups was obtained (Fig. 20). The Heck-type vinyla-tion reaction [137] was used to examine the catalytic activity of the heterogeneous system. The polymer-supported catalyst was found to compare favourably with the homogeneous system (Fig. 21). 

The use of numerous polymer-supported optically active phase transfer catalysts was further extended by Kelly and Sherrington11351 in a range of phase transfer reactions including a variety of displacement reactions, such as sodium borohydride reductions of prochiral ketones, epoxidation of chalcone, addition of nitromethane to chalcone and the addition of thiophenol to cyclohexanone. Except in the chalcone epoxidation, all the examined resin catalysts proved to be very effective. However, with none of the chiral catalyst system examined was any significant ee achieved. The absence of chiral induction is a matter of debate, in particular over the possible reversibility of a step and the minimal interaction within an ion pair capable of acting as chiral entities in the transition state and/or the possible degradation of catalysts and leaching. 

Polymer-supported benzenesulfonyl azides have been developed as a safe diazotransfer reagent. ° These compounds, including CH2N2 and other diazoalkanes, react with metals or metal salts (copper, paUadium, and rhodium are most commonly used) to give the carbene complexes that add CRR to double bonds. Diazoketones and diazoesters with alkenes to give the cyclopropane derivative, usually with a transition-metal catalyst, such as a copper complex. The ruthenium catalyst reaction of diazoesters with an alkyne give a cyclopropene. An X-ray structure of an osmium catalyst intermediate has been determined. Electron-rich alkenes react faster than simple alkenes. ... 

A ligand of a metal complex is one of the most appropriate templates for a molecular-imprinted metal-complex catalyst. Several ligands have been reported as candidates because of their analogy to transition states or reaction intermediates for target reactions [51-64], Several metal complexes with single-site Co, Cu, Zn, Ti, Ru, Rh, and Pd species have been used as active metal sites coordinated with template ligands (Table 22.1). Acrylate polymers [54, 55, 60, 63, 64] or polystyrene-divinylbenzene (DVB) polymers [51, 53, 56] are common polymer supports for molecularly imprinted catalysts. 

This chapter will walk through the various forms these catalytic resins take. The catalysts covered in this review fall into three classes, (i) transition metals covalently bonded to the polymer support through an organometallic bond, (ii) transition metals coordinated to the polymer support, typically in ionic form and (iii) transition metal clusters that are formed by precipitating metals into nanoparticles within the polymeric framework. Additionally, this chapter covers the synthetically useful and industrially practiced reactions catalyzed by transition metals loaded onto organic supports and comments on the mechanisms and reusability aspects of the processes [1]. 

Covalent bonding refers to the materials made in which the transition metal is bonded directly to the resin through an organometallic bond. Two different approaches can be used to covalently attach metal complexes to polymer supports (i) synthesis of appropriate functional monomers and their (co)polymerization to form catalytically active polymers (Scheme 11.1) or (ii) attachment of metal complexes to preformed functional polymer supports by chemical reactions. Following these approaches, both soluble and cross-linked chiral polymeric metal complexes can be prepared. An example of an organometallic tin catalyst suitable for transesterification was reported by workers at Rohm and Haas Company [3]. 

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