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Schiff bases supports

Schiff base ligands are a particularly suitable alternative in ROP of lactide because of their ease of preparation and the possibility to easily tunable steric and electronic properties. Chisholm and coworkers reported Schiff base-supported zinc amide and phenoxide complexes 51a, b (Fig. 10) [75], which catalyze the polymerization of L-lactide in benzene at room temperature yielding 90% conversion in 3 h for 51a and 72 h for 51b. The significant difference in reactivity between the catalysts can be taken from the rate of initiation, which is slower for 51a owing to presence of bulky 2,6-ferf-butylphenoxide leaving group. [Pg.237]

Kinetic investigations failed to distinguish between a one-step reaction of the olefin epoxidation type and a two-step reaction through an adduct such as 4. The formation of Z,E isomeric mixtures of oxaziridines from sterically definite Schiff bases supports the two-step mechanism. [Pg.65]

Figure 4.5 Preparation of Schiff base-supported chromium catalyst... Figure 4.5 Preparation of Schiff base-supported chromium catalyst...
As has been outlined for the Strecker synthesis, the Ugi reaction also proceeds via initial formation of a Schiff base from an aldehyde and an amine. The imine intermediate is attacked by the isocyanidc, a process which is supported by protonation of the imine by the carboxylic acid component. The resulting a-amino nitrilium intermediate is immediately trapped by the carboxylate to give an 6>-acyl imidiate. All steps up to this stage are reversible. Only the final oxygen to nitrogen acyl shift is irreversible and delivers the A-acyl-a-amino amide as the thermodynamically favored product which contains two amide groups. [Pg.782]

The diastereodifferentiating effect of the galactosylamine template in these Strecker reactions is rationalized in terms of a preferred conformation 5 of the Schiff bases which is stabilized by a (7i-double bond into the carbohydrate ring. This conformation is supported by a strong NOE in the H-NMR spectrum between the anomeric and the iminc proton. [Pg.795]

The immobilization of metal catalysts onto sohd supports has become an important research area, as catalyst recovery, recycling as well as product separation is easier under heterogeneous conditions. In this respect, the iron complex of the Schiff base HPPn 15 (HPPn = iVA -bis(o-hydroxyacetophenone) propylene diamine) was supported onto cross-linked chloromethylated polystyrene beads. Interestingly, the supported catalyst showed higher catalytic activity than the free metal complex (Scheme 8) [50, 51]. In terms of chemical stability, particularly with... [Pg.89]

Much work has been devoted to the study of Schiff base complexes, in particular M(salen), where M = metal, has been the subject of extensive work 114). The early work by Calvin et al. (section 111(A)) suggested that the 2 1 (M O2) dioxygen adduct, type I, formed by Co(salen) in the solid state, contains a peroxo linkage. An X-ray analysis 115, 116) of the complex (Co Salen)202(DMF)2 supports this hypothesis see Fig. 5 for the pertinent results of this study. [Pg.17]

For 10-fold 13C labelled retinal, it has been shown that the differences between chemical shifts for polyene chain carbons of the chromophore in its native environment and detergent-solubilised system were small67 Analysis of the environment of the Schiff base has supported the model of stabilisation based on the protonation by a complex counterion. Three factors were responsible for the excessive positive charge in polyene (i) electronegative nitrogen, (ii) protonation and (iii) counterion strength. [Pg.156]

In Sn(II) complexes, the tin atom was located above the di-Schiff base coordination plane, while in Sn(IV) complexes, it was coplanar with the imine coordination framework. The position of the metal was supported by X-ray data. For the compounds studied, the 119Sn chemical shift values varied from 501.4 to —1015.9 ppm. Increase in the coordination number from Sn(II) to Sn(IV) led to an increase in the tin shielding. The differences of up to 3.0 ppm between 5119Sn values for the complexes, being derivatives of R,R and S,S 1,2-diaminocyclohexane, were observed. [Pg.173]

Another example where PEG played the role of polymeric support, solvent, and PTC was presented by the group of Lamaty [72]. In this study, a Schiff base-proteded glycine was reacted with various electrophiles (RX) under microwave irradiation. No additional solvent was necessary to perform these reactions and the best results were obtained using cesium carbonate as an inorganic base (Scheme 7.64). After alkylation, the corresponding aminoesters were released from the polymer support by transesterification employing methanol in the presence of triethylamine. [Pg.339]

The practical applications of NaBH4 reductions on mineral surfaces for in situ generated SchifFs bases have been successfully demonstrated. The solid-state reductive amination of carbonyl compounds on various inorganic solid supports such as alumina, clay, silica etc. and especially on K 10 clay surface rapidly afford secondary and tertiary amines [126]. Clay behaves as a Lewis acid and also provides water from its interlayers thus enhancing the reducing ability of NaBH4 [22],... [Pg.203]

Studies involving 2,6-diacetylpyridine derivatives. Detailed studies by Nelson and coworkers supported by X-ray structural work by Drew and coworkers have elucidated many aspects of the template synthesis of metal complexes of a Schiff-base ligand series which includes the N4-donor system (83) and the N5-systems (84)-(86) (Nelson, 1980). Since... [Pg.41]

Other examples involved the use of chiral Schiff base-zinc complexes as catalysts [33 a] and polymer-supported chiral N-tritylaziridino alcohols as catalysts. The stereoselectivity was reported to be up to 97% ee for aUphatic and up to 96% ee for aromatic aldehydes [103]. [Pg.221]

Iu search for efficieut aud greeuer processes over the past few years various heterogeneous catalysts such as titanium incorporated mesoporous molecular sieves [45,46], Schiff-base complexes supported on zeolite [47] and Zn(II)-Al(III) layered double hydroxide (LDH) [48], oxomolybdenum(VI) complexes supported on MCM-41 and MCM-48 [49], polyoxometallate supported materials [50], Co and Mn-AlPO s [51] etc. have been developed and studied for the catalytic epoxidatiou of a-pinene. Many of these processes suffer from drawbacks and limited applicability due to the poor conversion and also the selectivities. Sacrificial aldehydes are often used as an oxygen acceptor in such processes to achieve reasonable yield and selectivities but, this procedure leads to an increase in the E-factors and decrease in the atom economy [51]. [Pg.136]

As for the V-Schiff-base monomer in alcohol solutions, two diastereomers exist due to two possible directions of the V=0 to the face of the tridentate ligands. The energy difference between the two diastereomers was calculated to be less than Ikjmol , indicating that the diastereomers coexist in similar concentrations in solutions. However, a chiral V center was created by supporting the V monomers on Si02. [Pg.384]

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See also in sourсe #XX -- [ Pg.18 ]



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