Norbomadiene, hydrogenation

Experimentally, this reaction sequence was observed with hydrogen 70) or a substituted octenyl group721 in position 7 of the norbomadiene. In the calculations a methyl group was used as marker, to show the course of the rearrangement. 

Similar low activities were found in the hydrogenation of 1-octene [47]. The use of [Ni(PPh3)2I2] in the hydrogenation of norbomadiene resulted in considerable amounts of nortricyclene, via transannular ring closure, whereas 1,5-cyclo-octadiene yielded bis-cyclo-[3.3.0]oct-2-ene. According to these authors, the re-... 

The binuclear precursor (di-,u-chloro-bis-[ /4-2,5-norbomadiene]-rhodium(I)) = [(Rh(NBD)Cl]2 is well suited for the in-situ preparation of a variety of homogeneous hydrogenation catalysts, if tertiary phosphines (here PMe3, PMe2Ph,... 

Olefinic compounds such as a-pinene (309) and /Dpi none (312) undergo hydrogen abstraction followed by rearrangement and amino-oxyl insertion (310, 313) and addition reactions (311, 314, 315), as shown in reactions 43 and 44627. Other olefinic compounds such as norbomadiene, cyclo-octene and cyclo-octa-1,5-diene gave analogous results628. 

Bimolecular surface reactions reactants adsorption, 29 111-112 with single reactant, 29 108-109 1,1 -Binaphthyl, dehydrocyclization, 28 318 Binary oxides, 32 119 Binding energy, 32 160-162 chemisorbed sulfur, 37 281 hydrogen, sulfur effect, 37 295-296 shift, Pd, 37 62-64 ZnO/SiOj, 37 21-22 Binor-S, see Norbomadiene Biological systems, hydrogen in, activation of, 11 301... 

Racemic diphosphines may be resolved by using transition metal complexes that contain optically active olefinic substrates (Scheme 11) (24). When racemic CHIRAPHOS is mixed with an enantiomerically pure Ir(I) complex that has two ( —)-menthyl (Z)-a-(acetam-ido)cinnamate ligands, (S,5)-CHIRAPHOS forms the Ir complex selectively and leaves the R,R enantiomer uncomplexed in solution. Addition of 0.8 equiv of [Rh(norbomadiene)2]BF4 forms a catalyst system for the enantioselective hydrogenation of methyl (Z)-a-(acetamido)cinnamate to produce the S amino ester with 87% ee. Use of the enantiomerically pure CHIRAPHOS-Rh complex produces the hydrogenation product in 90% ee. These data indicate that, in the solution containing both (S,S)-CHIRAPHOS-Ir and (/ ,/ )-CHIRAPHOS-Rh complexes, hydrogenation is catalyzed by the Rh complex only. 

The cyclobutane derivative (55) gave an optical yield of 91% in the hydrogenation of a-acetamidocinnamic acid. The catalyst was here prepared in situ from [RhCl(l,5-hexadiene)]2. The corresponding 1,2-derivative of cyclopentane gave an optical yield of only 73% and the cyclopropane and cyclohexane derivatives gave 15% and 36% respectively.235 [RhCl(cod)2] in presence of the norbomadiene-based ligand NORPHOS (56) gave up to 96% optical yields with a-acetamidocinnamic acid as substrate.236... 

This ligand, in combination with a rhodium complex prepared in situ from Rh(NBD)2+C104 (NBD = norbomadiene), can be used for an enantioselective hydrogenation of prochiral ketones to secondary alcohols (equation IV).5... 

A Diels-Alder approach to varenicline was recently published by Dr. Reddy s Laboratories. Entry to a key bicyclic intermediate is achieved by an iodide-catalyzed Diels-Alder reaction of tetrabromo dimethyl pyrazine (47) with excess norbomadiene. Dihydroxylation of 48, oxidative cleavage, and reductive amination prepares N-p-methoxybenzyl varenicline (50), which is deprotected under transfer hydrogenation conditions to give varenicline (1) in 10% yield for the sequence.47 This approach continues the theme of building the piperidine of 1 through olefin oxidative cleavage and reductive amination, but by doing so late in the sequence however, the approach... 

Hydrocyanation is also catalyzed by [Pd(PPh3)4] (103) and [Pd P(OPh), 4] (132), again in both cases in the presence of excess ligand. Complex (132) is an effective catalyst for the addition of hydrogen cyanide to cyclic monoenes and dienes such as norbomene and norbomadiene ethylene also reacted readily. The product obtained from norbomene was the exo isomer (equation 165). When norbomadiene was the substrate, some of the endo product was formed. ... 

Only limited data are available for the kinetics of oxo synthesis with the water-soluble catalyst HRh(CO)(TPPTS)3. The hydroformylation of 1-octene was studied in a two-phase system in presence of ethanol as a co-solvent to enhance the solubility of the olefin in the aqueous phase [115]. A rate expression was developed which was nearly identical to that of the homogeneous system, the exception being a slight correction for low hydrogen partial pressures. The lack of data is obvious and surprising at this time, when the Ruhrchemie/ Rhone-Pou-lenc process has been in operation for more than ten years [116]. Other kinetic studies on rhodium-catalyzed hydroformylation have been published, too. They involve rhodium catalysts such as [Rh(nbd)Cl]2 (nbd = norbomadiene) [117] or [Rh(SBu )(CO)P(OMe)3]2 [118], or phosphites as ligands [119, 120]. 

Enantioselective hydrogenation of prochiral carbonyl compounds with Wilkinson-type catalysts is less successful than the hydrogenation of prochiral olefins. Both rates and enantioselectivities are greatly diminished in the hydrogenation of ketones, compared with olefins. Enantioselectivities only occasionally reach 80% ee, e. g., in the hydrogenation of acetophenone with the in-situ catalyst [Rh(nbd)Cl]2/DIOP, where nbd = norbomadiene [71]. The Ru-based BINAP catalysts improved this situation, by allowing the hydrogenation of a variety of functionalized ketones in enantioselectivities close to 100% ee [72]. 

The mechanism of photocatalytic hydrogenation has been studied (by IR) with norbomadiene (nbd) and Group 6 metal carbonyls with respect of the role of H2... 

Both silver(I) and dimethylammonium polystyrene sulfonate polymers activated hydrogenations of nor-bornene and norbomadiene using this same catalyst. HCL absorption was a factor in these latter two activations. 

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