Polymer-bounded catalysts

The polymer-bound catalysts A-C. (Table 31) are prepared by reaction of the corresponding amino alcohols with partially chloromethylated 1 -2% cross-linked polystyrene. In the case of A, the enantioselectivity of the addition of dialkylzincs to aldehydes is higher than with the corresponding monomeric ephedrine derivatives (vide supra). Interesting insights into the mechanism of the alkylation of aldehydes by dialkylzinc reagents can be obtained from the experi-... 

The rate for the simple polymer-bound TADDOLate published in [107] was taken from [110]. Newer results show a similar rate for both polymer-bound catalysts described herein. 

The use of such an oxazaborolidine system in a continuously operated membrane reactor was demonstrated by Kragl et /. 58] Various oxazaborolidine catalysts were prepared with polystyrene-based soluble supports. The catalysts were tested in a deadend setup (paragraph 4.2.1) for the reduction of ketones. These experiments showed higher ee s than batch experiments in which the ketone was added in one portion. The ee s vary from 84% for the reduction of propiophenone to up to >99% for the reduction of L-tetralone. The catalyst showed only a slight deactivation under the reaction conditions. The TTON could be increased from 10 for the monomeric system to 560 for the polymer-bound catalyst. 

Allen (106) also studied cobalt hydroformylation with a polymer-bound catalyst. The polymer was formed from diphenyl-p-styrylphosphine cross-linked with divinylbenzene. 2-Hexene was the substrate, and reaction conditions were 175°C and 1500-3000 psi of 1/1 H2/CO. The product aldehyde was 55% linear, and the effluent product solution contained 20-50 ppm cobalt. 

The important factor of rhodium elution from polymer-bound catalysts... 

Polymer-bound catalysts containing both quaternary ammonium centres and oligo-(oxyethylene) links of the type shown in Scheme 1.10 have been synthesized [34]. There is an increase in catalytic activity resulting from a cooperative effect of the two types of catalyst upon nucleophilic reactions, compared to that of simple quaternary ammonium catalysts and crown ethers. 

Although the lariat ethers (29-31) were conceived on principles related to biological activity, they are interesting candidates for study as either free phase transfer catalysts, or as polymer-bound catalysts. In the latter case, the sidearm could serve both a complexing function and as a mechanical link between macroring and polymer. Polymeric phase transfer catalyst systems have been prepared... 

Janda, Bolm and Zhang generated soluble polymer-bound catalysts for the asymmetric dihydroxylation by attaching cinchona alkaloid derivatives to polyethylene glycol monomethyl ether (MeO-PEG) [84—87]. Since these polymeric catalysts like (24) are soluble in many common solvents they are often as effective as their small homogenous counterparts. Janda et al. prepared catalyst (24) in which two dihydroquinidine (DHQD) units were linked together by phthalazine and finally were attached to MeO-PEG via one of the bicyclic ring system moieties (Scheme... 

The polymer-bound catalyst was recyclable by filtration and showed just slightly decreased activity when reused. Catalyst (33) also promotes asymmetric Reissert-type reactions [106]. 

Scheme 4.31 Polymer-bound catalyst (51) in hydrogen transfer reactions.

Scheme 4.37 The Pauson-Khand reaction using polymer-bound catalyst (60).

Soluble polymer-bound catalysts for epoxidation reactions have also been explored, with a complete study into the nature of the polymeric backbone performed by Janda [70]. Chiral (salen)-Mn complexes were appended to MeO-PEG, NCPS, Jan-daJeF and Merrifield resin via a glutarate spacer. It was found that for the Jacobsen epoxidation of ds-/ -mefhylstyrene, the enantioselectivities for each polymer-supported catalyst were comparable (86-90%) to commercially available Jacobsen catalyst (88%). Both soluble polymer-supported catalysts could be used twice before a decline in yield and enantioselectivity was observed. However, neither soluble polymer support proved as suitable as the insoluble JandaJel-supported (salen)-Mn complex for the epoxidation because residual impurities during precipitation and leaching of Mn from the complex, resulted in lowered yields. 

Starting from the commercially available aldehyde (12), styrene (13) was prepared by a straightforward synthetic sequence (Scheme 11.3). Subsequent esterification of the phenol with succinate-derivatized poly(ethylene glycol) monomethyl ether (MeO-PEG) appended the styrene unit to approximately 50% of the free acid groups in (14). The loading in (15) was estimated by 500 MHz NMR spectroscopy to be about 0.1 mmol g . In a final step, the polymer-bound catalyst was ob-... 

Highly Efficient and Recyclable Polymer-Bound Catalyst for Olefin Metathesis Reactions, S. Randl, N. Buschmann, S.J. Connon, et at, Synlett 2001, 1547-1550. 

Scheme 14. Dynamic kinetic resolution of epibromohydrin with polymer bound catalyst 36.

Scheme 6.20 THP ethers obtained from the THP protection of various hydroxy substrates utilizing polymer-bound catalyst 17.

The affinity of the polymer-bound catalyst for water and for organic solvent also depends upon the structure of the polymer backbone. Polystyrene is nonpolar and attracts good organic solvents, but without ionic, polyether, or other polar sites, it is completely inactive for catalysis of nucleophilic reactions. The polar sites are necessary to attract reactive anions. If the polymer is hydrophilic, as a dextran, its surface must be made less polar by functionalization with lipophilic groups to permit catalytic activity for most nucleophilic displacement reactions. The % RS and the chemical nature of the polymer backbone affect the hydrophilic/lipophilic balance. The polymer must be able to attract both the reactive anion and the organic substrate into its matrix to catalyze reactions between the two mutually insoluble species. Most polymer-supported phase transfer catalysts are used under conditions where both intrinsic reactivity and intraparticle diffusion affect the observed rates of reaction. The structural variables in the catalyst which control the hydrophilic/lipophilic balance affect both activity and diffusion, and it is often not possible to distinguish clearly between these rate limiting phenomena by variation of active site structure, polymer backbone structure, or % RS. 

The nucleophilic displacement reaction of benzyl chloride with solid potassium acetate in various solvents under solid/solid/liquid conditions was faster with the polymer-bound catalyst 57 than with the soluble analog 58 181) (See Eq. (13)). 

The modified polymer 70a with the larger concave pyridine was then tested in the base catalyzed addition of ethanol to diphenylketene (59a) and proved to be catalytically active [17]. To compare the polymer bound concave pyridine 70a to the corresponding free concave pyridine 3k (MeO-substituted in 4-position of the pyridine ring), the same quantities of pyridine units were used, in solution (3k) or in suspension (70a) respectively. The polymer bound catalyst 70a catalyzed 2-3 times slower than the analogous 4-methoxy-substituted... 

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