Rh2 4 catalyst

Of course, new variants of the (N + C=C) approach continue to be reported. Muller and coworkers, who recently reviewed the field of rhodium(II)-catalyzed aziridinations with [N-(p-nitrobenzenesulfonyl)imino]phenyliodinane <96JP0341>, have explored the application of this technology to asymmetric synthesis. Thus, treatment of c/s-p-methylstyrene (141) with PhI=NNs and Pirrung s catalyst [Rh2 (-)(R)-bnp 4] in methylene chloride medium afforded the corresponding aziridine (142) in 75% yield and 73% ee <96TET1543>. 

In 2005, Doyle et al. reported an original sequence of two successive intramolecular cyclopropanations involving a bis(diazoacetates), using a sterically encumbered oxaimidazolidine carboxylate dirhodium(II) catalyst, Rh2[(45, 5)-BSPIM]4. An excellent result, depicted in Scheme 6.16, was obtained resulting from a double diastereoselection. 

As for cyclopropanation of alkenes with aryldiazomethanes, there seems to be only one report of a successful reaction with a group 9 transition metal catalyst Rh2(OAc)4 promotes phenylcyclopropane formation with phenyldiazomethane, but satisfactory yields are obtained only with vinyl ethers 4S) (Scheme 2). Cis- and trans-stilbene as well as benzalazine represent by-products of these reactions, and Rh2(OAc)4 has to be used in an unusually high concentration because the azine inhibits its catalytic activity. With most monosubstituted alkenes of Scheme 2, a preference for the Z-cyclopropane is observed similarly, -selectivity in cyclopropanation of cyclopentene is found. These selectivities are the exact opposite to those obtained in reactions of ethyl diazoacetate with the same olefins 45). Furthermore, they are temperature-dependent for example, the cisjtrcms ratio for l-ethoxy-2-phenylcyclopropane increases with decreasing temperature. 

A very impressive example of the synthetic utility of this chemistry is the one-pot enantioselective double G-H activation reaction of 86 to generate chiral spiran 87 (Equation (73)).172 In this case, the phthalimide catalyst Rh2(enantiotopically selective aromatic C-H insertions of diazo ketoesters (Equation (74)).216 Moreover, dirhodium(n) tetrakisIA-tetrafluorophthaloyl- )-/ /-leucinate], Rh2(hydrogen atoms of the parent dirhodium(n) complex are substituted by fluorine atoms, dramatically enhances the reactivity and enantioselectivity (up to 97% ee). Catalysis... 

Du Bois originally used rhodium(n) acetate and rhodium triphenylacetate (tpa) as catalysts and found that regio-and diastereocontrol was influenced by the catalysts, but neither was particularly effective when low catalyst loadings were used. Inspired by the bridged dirhodium catalysts which have been developed for carbenoid chemistry,40,273,274 a second generation catalyst Rh2(esp)2 116 (esp = a,a,a, o -tetramethyl-l,3-benzenedipropionate) was designed which was capable of much higher turnover numbers (Scheme ll).275 Furthermore, this catalyst was effective in intermolecular reactions. 

Considerable interest has been shown in developing asymmetric variants of the Si-H insertion. The chiral auxiUary (Jl)-pantolactone has performed quite well in this chemistry, as illustrated in the formation of 169 in 79% diastereomeric excess (Eq. 19) [28]. A wide variety of chiral catalysts have been explored for the Si-H insertion chemistry of methyl phenyldiazoacetate [29, 117-119]. The highest reported enantioselectivity to date was obtained with the rhodium prolinate catalyst Rh2(S-DOSP)4, which generated 170 with 85% enantiomeric excess (Eq. 20) [120]. 

The intramolecular C-H insertion reaction of phenyldiazoacetates on cyclohexadiene, utilizing the catalyst Rh2(S-DOSP)4, leads to the asymmetric synthesis of diarylacetates (Scheme 8). Utilizing the phenyl di azoacetate 38 and cyclohexadiene, the C-H insertion product 39 was produced in 59% yield and 99% ee. Oxidative aromatization of 39 with DDQ followed by catalytic hydrogenation gave the diarylester 40 in 96% ee. Ester hydrolysis followed by intramolecular Friedel-Crafts gave the tetralone 31 (96% ee) and represents a formal synthesis of sertraline (5). Later studies utilized the catalyst on a pyridine functionalized highly cross-linked polystyrene resin. ... 

A vast array of chiral catalysts have been developed for the enantioselective reactions of diazo compounds but the majority has been applied to asymmetric cyclopropanations of alkyl diazoacetates [2]. Prominent catalysts for asymmetric intermolecular C-H insertions are the dirhodium tetraprolinate catalysts, Rh2(S-TBSP)4 (la) and Rh2(S-DOSP)4 (lb), and the bridged analogue Rh2(S-biDOSP)2 (2) [7] (Fig. 1). A related prolinate catalyst is the amide 3 [8]. Another catalyst that has been occasionally used in intermolecular C-H activations is Rh2(S-MEPY)4 (4) [9], The most notable catalysts that have been used in enantioselective ylide transformations are the valine derivative, Rh2(S-BPTV)4 (5) [10], and the binaphthylphosphate catalysts, Rh2(R-BNP)4 (6a) and Rh2(R-DDNP)4 (6b) [11]. All of the catalysts tend to be very active in the decomposition of diazo compounds and generally, carbenoid reactions are conducted with 1 mol % or less of catalyst loading [1-3]. 

The potential of the enantioselective intramolecular 1,3-dipolar cycloaddition was first described by Hodgson in the intramolecular version shown in Eq. (25). The Rh2(S-DOSP)4-catalyzed reaction of the diazoacetatoacetate 44 generated the tricyclic product 45 in 53% ee [38], but in a more recent study using the binaphthylphosphate catalyst Rh2(R-DDNP)4 (6b) the tricyclic product was formed in 90% ee [11]. 

Hashimoto has shown that the the valine-derived catalyst Rh2(S-BPTV)4 (5) is effective in intermolecular tandem cyclization/intermolecular cycloaddition resulting in the formation of 46 in 92% ee (Eq. (26) [10]. More recent studies have broadened the range of substrates that can be used in the reaction although the enantioselectivity is variable [38,39],... 

What was evident for macrocyclization involving metal carbene addition to alkenes is even more so for addition to alkynes [110]. However, here the chiral dirhodium(II) catalyst Rh2(4.S -IBAZ)4 exhibits the highest degree of enantiocontrol, superior even to Cu(MeCN)4PF6 (Eq. 5.22). 

Nearly equimolar amounts of the components are sufficient to obtain satisfying results even in large-scale runs. Cu(acac)2 is the most suitable catalyst Rh2(OAc)4, which is effective even at room temperature, might be preferable in exceptional cases. As expected, the cyclopropanation step occurs regioselectively (entries 4, 14) and stereospecifically (entries 9-11), thereby retaining the olefin configuration completely in the product. On the other hand, there is only a very moderate stereoselection as far as the methoxy carbonyl group is concerned, and usually cisjtrans mixtures are obtained 57). 

It is worthy of note that this reaction is still the subject of solid and productive interest, as shown by the following recent examples. Chiu has exploited a rhodium carbene-promoted intramolecular formation of a carbonyl ylid - cycloaddition cascade as the key reaction in the synthesis of the nucleus of the cytotoxic diterpenoids pseudolaric acids A and B [54]. Although the diastereoselectivity was preferential for the undesired isomer 64, use of Hashimoto s chiral rhodium catalyst Rh2(SBPTV)4 reversed the selectivity in favor of 65 (64 65, 1 1.4) [55] (Scheme 29). 

The C-H insertion reaction of aryldiazoacetates to furnish dihydrobenzofurans is best carried out with dimeric rhodium(ll) catalysts. Rh2(PTTL)4 has proven to be the catalyst of choice for the asymmetric version of this process, providing exclusively j-2-aryl-3-methoxycarbonyl-2,3-dihydrobenzofurans with an ee of up to 94% (Equation 142) <2002OL3887>. 

In this study chiral dirhodium catalysts (Rh2(MEPY)4) and Rh2(BNOX)4), developed by Doyle [10] (see Scheme 1) were immobilised. It can be anticipated that the spatial constraints induced by the carrier (MCM-41 or silica), and especially by the pores of MCM-41, are able to increase the influence of the chiral ligands. Earlier research [11,12] showed that enantioselective reduction catalysed by a palladium complex immobilised inside the pores of MCM-41 resulted in a threefold increase in enantioselectivity compared to the homogeneous palladium complex. In order to immobilise the homogeneous catalysts on the surface, an organic linker group was... 

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