Rhodium catalysts coupling

Based on these preliminary findings, related couplings to pyruvates and iminoacetates were explored as a means of accessing a-hydroxy acids and a-amino acids, respectively. It was found that hydrogenation of 1,3-enynes in the presence of pyruvates using chirally modified cationic rhodium catalysts delivers optically enriched a-hydroxy esters [102]. However, chemical yields were found to improve upon aging of the solvent 1,2-dichloroethane (DCE), which led to the hypothesis that adventitious HC1 may promote re-... 

To date, reports have involved palladium catalysts for Suzuki and Sono-gashira coupling reactions [63-66], rhodium catalysts for silylations of alcohols by trialkylsilanes [67,68], and tin-, hafnium-, and scandium-based Lewis acid catalysts for Baeyer-Villiger and Diels-Alder reactions [69]. Regardless of exact mechanism, this recovery strategy represents an important direction for future research and applications development. Finally, a particularly elegant protocol where CO2 pressure is used instead of temperature to desorb a fluorous rhodium hydrogenation catalyst from fluorous silica gel deserves emphasis [28]. 

The rhodium catalyst was recycled batch-wise four times. It was found that a short induction period occurred during the first reaction cycle. The following cycles showed a constant rate and no loss of activity was detected. A ligand-to-rhodium ratio of 5 1 led to a constant yield of 95% per cycle after 1 h. Within the four cycles a total turnover number of 1000 with a maximum turnover frequency of 234 h was achieved. The leaching of rhodium and phosphorus into the aqueous layer was determined by inductively coupled plasma atomic emission spectrometry. Rhodium leaching amounted to 14.2 ppm in the first run, then dropped to 3.6 ppm (second run) and reached values of 0.95 and 0.63 ppm in the third and fourth runs, respectively. 

Analysis of the Mukaiyama-type aldol coupling (Eq. 2) and the well-known hydrosilyla-tion of a,/l-unsaturated carbonyl compounds 11 in the presence of a rhodium catalyst, indicate that both can be explained by the intervention of the rhodium enolate 13. This line of reasoning provided the impetus to develop a new crossed aldol coupling using a hydrosilane, an a,yS-unsaturated ketone 11, and an aldehyde to form 15 (Scheme 6.4). 

Alternatively, rhodium catalysts have been revealed to be effective for the coupling of two alkynes with an isocyanide to afford the iminocyclopentadienes 62 and 62 in high yield (Tab. 11.9) [36bj. The coordinating solvent dibutyl ether, in combination with por-tionwise addition of the isocyanides, is key to the success of this transformation. 

Monometallic ruthenium, bimetallic cobalt-ruthenium and rhodium-ruthenium catalysts coupled with iodide promoters have been recognized as the most active and selective systems for the hydrogenation steps of homologation processes (carbonylation + hydrogenation) of oxygenated substrates alcohols, ethers, esters and carboxylic acids (1,2). 

In addition to copper and rhodium catalysts commonly used in the generation of metal carbene complexes, other transition metals have also been explored in the diazo decomposition and subsequent ylide generation.Che and co-workers have recently studied ruthenium porphyrin-catalyzed diazo decomposition and demonstrated a three-component coupling reaction of a-diazo ester with a series of iV-benzylidene imines and alkenes to form functionalized pyrrolidines in excellent diastereoselectivities (Scheme 20). ... 

Initial studies showed that the encapsulated palladium catalyst based on the assembly outperformed its non-encapsulated analogue by far in the Heck coupling of iodobenzene with styrene [7]. This was attributed to the fact that the active species consist of a monophosphine-palladium complex. The product distribution was not changed by encapsulation of the catalyst. A similar rate enhancement was observed in the rhodium-catalyzed hydroformylation of 1-octene (Scheme 8.1). At room temperature, the catalyst was 10 times more active. For this reaction a completely different product distribution was observed. The encapsulated rhodium catalyst formed preferentially the branched aldehyde (L/B ratio 0.6), whereas usually the linear aldehyde is formed as the main product (L/B > 2 in control experiments). These effects are partly attributed to geometry around the metal complex monophosphine coordinated rhodium complexes are the active species, which was also confirmed by high-pressure IR and NMR techniques. 

Intramolecular hydrosilylations of functionalized alkenes followed by hydrogen peroxide oxidation provide powerful methods for organic syntheses86-88. The reactions of allylic O-dimethylsilyl ethers 59 promoted by platinum catalysts, e.g. Karstedt s catalyst and Pt(PPh3)2(CH2=CH2), or rhodium catalysts, e.g. Rh(acac)(COD) and [RhCl(CH2=CH2)2]2> proceed via 5-endo cyclization to give oxasilacyclopentanes 60 with a couple of exceptions in which siloxatanes 61 are formed (Scheme ll)87,89. 

The first example of silylation of C-H bonds in arenes with hydrosilanes was reported by Curtis [2]. Later, silylation of C-H bonds with triethylsilane using a rhodium catalyst was reported (Scheme 3) [3, 4], The reaction of arenes with bis(hydrosilane) using a platinum catalyst involves a bis(silyl)platinum species in the coupling reaction (Scheme 3) [5]. In these non-chelation-assisted reactions possible regioisomers should be formed. 

The per cent of dicyclohexylamine formed in hydrogenation of aniline increases with catalyst in the order ruthenium < rhodium platinum, an order anticipated from the relative tendency of these metals to promote double bond migration and hydrogenolysis (30). Small amounts of alkali in unsupported rhodium and ruthenium catalysts completely eliminate coupling reactions, presumably through inhibition of hydrogenolysis and/or isomerization. Alkali was without effect on ruthenium or rhodium catalysts supported on carbon, possibly because the alkali is adsorbed on carbon rather than metal (22). 

Potential difference in reactivity between two G-B bonds allowed the transformation of l,2-bis(boryl)-l-alkenes to 1-alkenylboranes via a cross-coupling with the aryl, 1-alkenyl, benzyl, and cinnamyl halides (Equation (23)).211-213 This tandem procedure synthetically equivalent to a yy/z-carboboration of alkynes was used for synthesizing Tamoxifen derivatives via stepwise double coupling with two of the G-B bonds.212,213 Hydrogenation of the resulting bisborylalk-enes with a chiral rhodium catalyst is synthetically equivalent to an asymmetric diboration of alkenes (Equation (24)).214... 

The cross-coupling of allyl alcohols with aryl- and vinylboronic acids has been accomplished in [C4Ciim][BF4] and [C4Ciim][PF6] with rhodium catalysts.1"31 While no reaction takes place in polar solvents such as water or DMF, good results were obtained in [C4Ciim][PF6], see Scheme 6.12, and rhodium(I) as well as rhodium(III) compounds worked well in the latter solvent. The presence of copper salts as well as acids led to an increase of the reaction rate. 

In some cases, it is possible to couple an alcohol with an organometallic compound. Allylic alcohols are coupled with alkylmagnesium bromides in the presence of Ti(OiPr)4, for example. Allylic alcohols can be coupled with arylboronic acids in ionic liquid solvent and a rhodium catalyst. The palladium-catalyzed... 

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