Chiral linear polymeric catalysts

Chiral Linear Polymeric Catalysts 1115 Catalyst recycling... 

Chiral polymers have been applied in many areas of research, including chiral separation of organic molecules, asymmetric induction in organic synthesis, and wave guiding in non-linear optics [ 146,147]. Two distinct classes of polymers represent these optically active materials those with induced chirality based on the catalyst and polymerization mechanism and those produced from chiral monomers. Achiral monomers like propylene have been polymerized stereoselectively using chiral initiators or catalysts yielding isotactic, helical polymers [148-150]. On the other hand, polymerization of chiral monomers such as diepoxides, dimethacrylates, diisocyanides, and vinyl ethers yields chiral polymers by incorporation of chirality into the main chain of the polymer or as a pedant side group [151-155]. A number of chiral metathesis catalysts have been made, and they have proven useful in asymmetric ROM as well as in stereospecific polymerization of norbornene and norbornadiene [ 156-159]. This section of the review will focus on the ADMET polymerization of chiral monomers as a method of chiral polymer synthesis. 

Linear polymers carrying chiral oxazaborolidine as a pendant group were prepared from a methylhydrosiloxane-dimethylsiloxane copolymer [72]. Borane reduction using the polymeric oxazaborolidine 25 gave (i )-phenylethylalcohol of 97% ee which is as high as in analogous reaction with non-polymeric catalyst. This chiral polymer can be retained by a nanofiltration membrane thus will be suitable for use in a continuously operated membrane reactor. 

Hu et al. [31] reported a new type of macro molecular chiral catalysts for asymmetric catalysis using Suzuki coupling polymerization and obtained optically active ephedrine-bearing dendronized polymers. Their finding showed that the optically active dendronized polymers have characteristics joined features like huge numbers of catalytic sites, more solubility and nanoscopic dimensions towards more acceptable in comparison to its existing chiral catalysts of linear polymeric and dendritic nature. 

The soluble polymer-supported catalysts have also been used for asymmetrically catalyzed reactions Following a procedure for the preparation of insoluble polymeric chiral catalysts a soluble linear polystyrene-supported chiral rhodium catalyst has been prepared. This catalyst displays high enantiomeric selectivity compared to the low molecular weight catalyst. Thus, hydroformylation of styrene using this catalyst produces aldehydes in high yields. The branched chiral hy drotropaldehy de is formed in 95% selectivity. 

For the polymerization of ethene chiral, metallocenes are not necessary but high activity and linear polymers are wanted. Table 3 compares some metallocene catalysts for the polymerization of ethene. 

Cyclopolymerization. As discussed earlier, nonconjugated dienes can be polymerized with metallocene-based catalysts to afford cyclopol5miers. In contrast to linear polyolefins which have only two microstructures of maximum order (isotactic and syndiotactic), cyclic polymers have four microstructures due to the possibility of configurational isomerism (cis vs trans) in the main chain (Fig. 16). Of these the frares-diisotactic structure contains no mirror planes of S5unmetry and is chiral by virtue of its main-chain stereochemistry (481). Two criteria for chirality of this microstructure are the presence of trans rings and isotacticity (the same... 

The radical initiation has been reported to give optically active products also in the case of vinyl monomers containing a rather labile chirality center such as an asymmetric sulfoxide moiety [22]. Similarly to racemization occurs in the polymerization of chiral 1-alkynes by Fe(AcAc)3 /AIR3 catalyst which gives linear polymers with alternate double bonds along the main chain [23]. 

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