3.7- dimethyl-10-ethyl complex with

Creosol, 33, 17 Crotonaldehyde, 33, IS 34, 29 diethyl acetal, 32, 5 Cupric acetate monohydrate, 36, 77 Cuprous oxide-silver oxide, 36, 36, 37 Cyanamide, 34, 67 36, 8 Cyanoacetamide, 32, 34 Cyanoacetic acid, 31, 25 Cyanoacetylurea, 37, 16 >-Cyanobenzaldehyde, 30, 100 >-Cyanobenzaldiacetate, 36, 59 3-Cyano-5,6-dimethyl-2(l)-pyridone, 32,34 N-2-Cyanoethylaniline, 36, 6 N-2-Cyanoethyl- -anisidine, 36, 7 Cyanoethylation, of aniline, 36, 6 of ethyl phenylcyanoacetate, 30, 80 N-2-Cyanoethyl-m-chloroaniline, 36, 7 Cyanogen, 32, 31 Cyanogen iodide, 32, 29 Cyanogen iodide, complex with sodium iodide, 32, 31... 

As a first step toward a dopamine-jS-hydroxylase mimic, basket-shaped receptor 17 was functionalized with two sets of bis-[2-(3,5-dimethyl-l-pyra-zolyl)ethyl]amine ligands to give compound 35 (see Scheme 5). Reaction of 35 with Cu(C104,)2-6H20 yielded complex 36 which was fully characterized [39], Ligand system 35 binds dopamine derivative 37 and phloroglucinol (1,3,5-trihydroxybenzene) with association constants of = 60 and 3500 respectively. The affinity of the Cu(I) analogon of 36 for 37 was very similar to that of 36 itself and amounted to Ka = 60 M L Resorcinol is bound in the cavity of the Cu(I) complex with a Xj-value of 2(XX) M". ... 

Dramatic changeover is observed not only in the ene/HDA product ratio, but also in the absolute stereochemistry upon changing the central metal from Ti to Al. Thus, Jprgensen et al. reported the HDA-selective reaction of ethyl glyoxylate with 2,3-dimethyl-1,3-butadiene catalyzed by a BINOL-derived Al complex [25], where the HAD product was obtained with up to 89% periselectivity and high enantiopurity (Scheme 8C.9). The absolute configuration was opposite to that observed by using BINOL-Ti catalyst. 

The selectivity of the Complex Formation is a very interesting subject, y - Cyclodextrin, (y - CD) has been found to form inclusion complexes with poly (methyl vinyl ether) (PMVE), poly(ethyl vinyl ether) (PEVE), and poly(n- propyl vinyl ether) (PnPVE) of various molecular weights to give stoichiometric compounds in crystalline states. However, a- cyclodextrin (a - CD) and (3 - Cyclodextrin ((3- CD) did not form complexes with poly (alkyl vinyl ether)s of any molecular weight, y -CD did not form complexes with the low molecular weight analogs, such as diethyl ether and trimethylene glycol dimethyl ether. 

In the presence of Lewis acids, N-substituted aniline complexes of [Os] also add electrophiles at C4, again at the arene face opposite to that involved in metal coordination. This reaction has been shown to be general for a broader range of Michael acceptors than may be utilized with anisole complexes of [Os]. The N-ethyl aniline complex, for example, adds Michael acceptors and acetals in yields ranging from 53-95 % (Table 13, entries 1-6) [27]. The N,N-dimethyl aniline complex (entries 7-9) also adds Michael acceptors to C4 in moderate to high yields (Table 13) and adds to the <5-carbon of an a,/ ,y,<5-un saturated ester (entry 3). 

Unsaturated acetals. Reaction of ethyl diazoacetate with dimethyl acetals of a,(3-unsaturated aldehydes catalyzed by BE, ethciate gives as the main product acetals of P. y-unsaturated aldehydes by a carbon-carbon insertion. A similar reaction with ketals gives a complex mixture. The reaction is less selective with diethyl acetals. 

Diphenyl carbonate from dimethyl carbonate and phenol Dibutyl phthalate from butanol and phthalic acid Ethyl acetate from ethanol and butyl acetate Recovery of acetic acid and methanol from methyl acetate by-product of vinyl acetate production Nylon 6,6 prepolymer from adipic acid and hexamethylenediamine MTBE from isobutene and methanol TAME from pentenes and methanol Separation of close boiling 3- and 4-picoline by complexation with organic acids Separation of close-boiling meta and para xylenes by formation of tert-butyl meta-xyxlene Cumene from propylene and benzene General process for the alkylation of aromatics with olefins Production of specific higher and lower alkenes from butenes... 

Enantioselective allylic substitutions catalyzed by transition-metal complexes are a powerful method for constructing complex organic molecules [4f,55]. Palladium-based catalysts have often given excellent results. To expand the scope of the reaction, a new enantioselective allylic alkylation catalyzed by planar-chiral ruthenium complexes was developed [56]. For example, the reaction of l,3-diphenyl-2-propenyl ethyl carbonate with sodium dimethyl malonate in the presence of 5 mol% of a planar chiral (S)-ruthenium complex (Figure 5.3) at 20 °C for 6 h in THE resulted in the formation of the corresponding chiral allylic alkylated product of dimethyl 2-((2 )(lS)-l,3-diphenylprop-2-enyl)propane-l,3-dioate in 99% yield vsdth 96% e.e. (Eq. 5.33). 

Styrene cyclopropanation continues to attract much interest. Cationic complex CpFe(CO)2(THF) BF4" mediates carbene transfer from ethyl diazoacetate with high cis selectivity cis trans = 85 15) [38]. On the other hand, Tp Cu(C2H4), where Tp is hydrotris(3,5-dimethyl-l-pyrazolyl)borate, is one of the rare catalysts to promote carbene transfer from ethyl diazoacetate to alkenes and also to alkynes. While cyclopropanes are formed in high yield, cyclopropenes are obtained only in moderate yield [39]. The same complex also catalyzes nitrene transfer from PhI=NTs to alkenes to produce aziridines in high yields. 

Solid state Wittig-Horner reaction of 4-methyl- (43a), 4-ethyl- (43b) and 3,5-di-methylcyclohexanone (44) as their inclusion complex with optically active host compound and (carbethoxymethylene)triphenylphosphorane (45) gave optically active 4-methyl- (46a), 4-ethyl- (46b) and 3,5-dimethyl-l-(carbethoxymelhy-lene)cyclohexane (47), respectively [16]. For example, when a mixture of the finely powdered 1 1 inclusion complex of 43a with 2b (1.5 g) and 45 (2.59 g) was kept at 70 C, the Wittig-Horner reaction was completed within 4 h. To the reaction mixture was added ether-petroleum (1 1) and the precipitated solid (Ph PO... 

Similarly, ra 5-cyclopropanes were obtained from alkenes, such as styrene and 2,5-dimethyl-hexa-2,4-diene, with relative yields > 90% when a diazoacetate bearing a bulky ester group was decomposed by a copper catalyst with bulky salicylaldimato ligands. Several metal complexes with bulky Cj-symmetrlc chiral chelating ligands are also suitable for this purpose, e.g. (metal/ligand type) copper/bis(4,5-dihydro-l,3-oxazol-2-yl)methane copper/ethyl-enediamine ruthenium(II)/l,6-bis(4,5-dihydro-l, 3-oxazol-2-yl)pyridine cobalt(III)/ salen. The same catalysts are also suited for enantioselective reactions vide infra). For the anti selectivity obtained with an osmium-porphyrin complex, see Section 1.2.1.2.4.2.6.3.1. 

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