Double-chelation

However, the decarbonylation reaction can be suppressed by the use of specially tailored chelating groups. Intermolecular processes involving dienes and salicylaldehydes are now known, and are thought to proceed via a double chelation mechanism, akin to the Jun-type system. Rhodium-catalyzed reactions lead to hydroacylated products, under relatively mild conditions (Equation (134)).117... 

Guided by the double-chelation assisted hydroacylation between salicylaldehydes and dienes developed by the group of Tanaka and Suemune, Dong and co-workers presented the asymmetric intermolecular hydroacylation reactions between salicylaldehydes and sulfide-functionalized terminal alkenes. High levels of enantio- and regio-selectivity control was obtained when biindane-derived phosphoramidite ligand L7 was used (Scheme 8.22). 

Double-Chelation-Assisted Rh-Catalyzed Intermolecular Hydroacylation Between Salicylaldehydes and 1,4-Peneta- or 1,5-Hexadienes... 

Pden(OH2)2] reacts with the neutral molecule ethanolamine to form a double chelate product. Potentiometric titrations showed that when ethanolamine was replaced by amino acids, however, deprotonation was necessary before the hydroxy group oxygen would coordinate. ... 

Formula I represents one of the resonating structures of m-dinitro-benzene. Formula II represents the compound formed upon the addition of ammonia. Obviously such double chelation is not to be expected from triethylamine. 

Copper(I) tends towards a tetrahedral coordination geometry in complexes. With 2,2 -bipyr-idine as a chelate ligand a distorted tetrahedral coordination with almost orthogonal ligands results. 2,2 -Bipyridine oligomers with flexible 6,6 -links therefore form double helices with two 2,2 -bipyridine units per copper(I) ion (J. M. Lehn, 1987,1988). J. M. Lehn (1990 U. Koert, 1990) has also prepared such helicates with nucleosides, e.g., thymidine, covalently attached to suitable spacers to obtain water-soluble double helix complexes, so-called inverted DNA , with internal positive charges and external nucleic bases. Cooperative effects lead preferentially to two identical strands in these helicates when copper(I) ions are added to a mixture of two different homooligomers. 

Particularly alkyl halides which have a perfluoroalkyl group at the /3-position undergo smooth carbonylation. Probably the coordination of fluorine to form a five-membered chelate ring accelerates the reaction. Double carbonylation to give the a-keto amide 915 is possible in Et NH with the fluorine-bearing alkyl iodide 914[769,770]. The ester 917 is obtained by the carbonylation of the /3-perfluoroalkyl iodide 916 in ethanol. 

Acyl-, 4-alkoxycarbonyl- and 4-phenylazo-pyrazolin-5-ones present the possibility of a fourth tautomer with an exocyclic double bond and a chelated structure. The molecular structure of (138) has been determined by X-ray crystallography (Table 5). It was shown that the hydroxy group participates in an intramolecular hydrogen bond with the carbonyl oxygen atom of the ethoxycarbonyl group at position 4 (8OCSCII21). On the other hand, the fourth isomer is the most stable in 4-phenylazopyrazolones (139), a chelated phenyl-hydrazone structure. 

Addition of pyrazole to C—X double bonds is also common. Formaldehyde gives stable adducts (260) and (261) (69BSF2064), but in the addition to ketones, (262) is only observed at low temperatures (Section 4.04.1.3.3(i)). However, hexafluoroacetone forms a stable adduct (262 R = Cp3) that has been used as a chelating agent (Section 4.04.2.1.3(iv)). Addition of pyrazoles to aryl isocyanates affords (263) the addition is also reversible, but it requires high temperatures to dissociate the adduct (Section 4.04.1.5.1). 

The first synthesis of enterobactin, a microbial chelator and transporter of environmental iron, was accomplished by the coupling of three protected L-serine units and macrocyclization by the double activation method. 

These results may be rationalized by assuming a chelation model. The nucleophile preferentially attacks the less hindered side of the C — N double bond as depicted. 

The stereochemical course of the reaction may be explained by assuming a fivc-membered chelate with the nucleophile attacking the less hindered side of the C—N double bond (alkoxy-mediated S -attack)18. This model is supported by the fact that (he stereoselectivity of the reaction clearly diminishes if smaller nucleophiles, e.g., ethylmagnesium bromide, are employed. The use of valinol methyl ether effects slightly better results19. 

The diastereoselectivity of the reaction may be rationalized by assuming a chelation model, which has been developed in the addition of Grignard reagents to enantiomerically pure a-keto acetals7,8. Cerium metal is fixed by chelation between the N-atom, the methoxy O-atom and one of the acetal O-atoms leading to a rigid structure in the transition state of the reaction (see below). Hence, nucleophilic attack from the Si-face of the C-N double bond is favored4. 

The combination of metal tuning and double stereodifferentiation helps to prepare chelation and nonchelation products in the imine series7. In the case of an alkoxy substituent adjacent to the aldimino, the chelation product 10 is predominantly obtained with allylmagnesium chloride, chloromagnesium allyltriethylaluminate or allylzinc bromide, while the use of allyl-boronates or allyltitanium triisopropoxide, which lack the requisite Lewis acidity for chelation, gives 11 with good Cram selectivity. 

Substantially high diastereoselectivity was accomplished by the conjugate addition of Grignard reagents to the amide 1 derived from 1-ephedrine32. The reagent attacked from the Re-face of the double bond, as shown in 2, via a chelated intermediate. Low asymmetric induction was observed when butyllithium was used instead of butylmagnesium bromide. 

In contrast, the diastereoselectivity of the conjugate addition of a chiral alkenylcoppcr-phosphinc complex to 2-mcthyl-2-cyclopentenone was dictated by the chirality of the reagent63. The double Michael addition using the cyclopentenone and 3-(trimethylsilyl)-3-buten-2-one and subsequent aldol condensation gave 4 in 58 % overall yield. The first Michael addition took place from the less hindered face of the m-vinylcopper, in which chelation between copper and the oxygen atom fixed the conformation of the reagent. 

Barluenga et al. have described novel vinylcarbene complexes containing a cyclic BF2 chelated structure which temporarily fixes the s-cis conformation of the exocyclic C=C and Cr=C double bonds. These boroxycarbene complexes behave as dienophiles with 2-amino-l,3-butadienes in a remarkably regio- and exo-selective way. Moreover, high degrees of enantioselectivity are reached by the use of chiral 2-aminodienes derived from (S)-methoxymethylpyrrolidine [101] (Scheme 54). 

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