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Rhodium chiral dirhodium catalysts

The use of chiral additives with a rhodium complex also leads to cyclopropanes enantioselectively. An important chiral rhodium species is Rh2(5-DOSP)4, which leads to cyclopropanes with excellent enantioselectivity in carbene cyclopro-panation reactions. Asymmetric, intramolecular cyclopropanation reactions have been reported. The copper catalyzed diazoester cyclopropanation was reported in an ionic liquid. ° It is noted that the reaction of a diazoester with a chiral dirhodium catalyst leads to p-lactones with modest enantioselectivity Phosphonate esters have been incorporated into the diazo compound... [Pg.1238]

The rhodium carbenoid (55) generated from diazocompound (50) has been shown to react efficiently with 1,3-dipolar nitrones in a formal [3 + 3] manner to produce heterocyclic cycloadducts (56) in high yields. Using chiral dirhodium catalysts such 0 as (51) or equivalent (R = methyl instead of adamantyl), the process exhibits a very high level of enantioinduction. [Pg.211]

McKervey and Ye have developed chiral sulfur-containing dirhodium car-boxylates that have been subsequently employed as catalysts for asymmetric intramolecular C-H insertion reactions of y-alkoxy-ot-diazo-p-keto esters. These reactions produced the corresponding ci -2,5-disubstituted-3(2H)-furanones with diastereoselectivities of up to 47% de. Moreover, when a chiral y-alkoxy-a-diazo-p-keto ester containing the menthyl group as a chiral auxiliary was combined with rhodium(II) benzenesulfoneprolinate catalyst, a considerable diastereoselectivity enhancement was achieved with the de value being more than 60% (Scheme 10.74). [Pg.352]

In rhodium(II)-catalyzed intermolecular cyclopropanation reactions, chiral dirhodium(II) carb-oximidates provide only limited enantiocontrol. " Tetrakis(5-methoxycarbonyl-2-pyrrolidonato)dirhodium [18, Rh2(MEPY)J, in both enantiomeric forms of the carboxamide ligands, produces the highest enantioselectivities. As can be seen for the cyclopropanation of styrene with diazoacetates, a high level of double diastereoselectivity results from the combination of this chiral catalyst with /- or d-menthyl diazoacetate, but not with diazoacetates bearing other chiral residues.In terms of trans/cis selectivity and enantioselectivity for styrene giving 19 this catalyst is comparable to the Aratani catalysts, but they cannot match the high enantiocontrol of the chiral copper catalysts developed by Pfaltz, Masamune, and Evans vide supra). [Pg.461]

Synthesis of the chiral catalysts to introduce enantioselectivity in carbene transfer reactions is a subject of great interest. Often copper and rhodium chiral catalysts are of choice for the carbene transfer reactions. In some reports, immobilized chiral dirhodium (II) catalyst were employed successfully in asymmetric cyclopropanation reactions. Ubeda and coworkers reported the immobilization of chiral Rh2(02CR)2(PC)2 (PC = ort/io-metalated phosphine) compounds on cross-linked polystyrene (PS) resin by an... [Pg.222]

C-H alkylation and amination reactions involving metal-carbenoid and metal-nitrenoid species have been developed for many years, most extensively with (chiral) dirhodium(ll) carboxylate and carboxamidate complexes as catalysts [45]. When performed in intramolecular settings, such reactions offer versatile methods for the (enantioselective) synthesis of hetero- and carbocy-cles. In the past decade, Zhang and coworkers had explored the catalysis of cobalt(II)-porphyrin complexes for carbene- and nitrene-transfer reactions [46] and revealed a radical nature of such processes as a distinct mechanistic feature compared with typical metal (e.g., rhodium)-catalyzed carbenoid and nitrenoid reactions [47]. Described below are examples of heterocycle synthesis via cobalt(II)-porphyrin-catalyzed intramolecular C-H amination or C-H alkylation. [Pg.331]

Activation of a C-H bond requires a metallocarbenoid of suitable reactivity and electrophilicity.105-115 Most of the early literature on metal-catalyzed carbenoid reactions used copper complexes as the catalysts.46,116 Several chiral complexes with Ce-symmetric ligands have been explored for selective C-H insertion in the last decade.117-127 However, only a few isolated cases have been reported of impressive asymmetric induction in copper-catalyzed C-H insertion reactions.118,124 The scope of carbenoid-induced C-H insertion expanded greatly with the introduction of dirhodium complexes as catalysts. Building on initial findings from achiral catalysts, four types of chiral rhodium(n) complexes have been developed for enantioselective catalysis in C-H activation reactions. They are rhodium(n) carboxylates, rhodium(n) carboxamidates, rhodium(n) phosphates, and < // < -metallated arylphosphine rhodium(n) complexes. [Pg.182]

As shown in the previous two sections, rhodium(n) dimers are superior catalysts for metal carbene C-H insertion reactions. For nitrene C-H insertion reactions, many catalysts found to be effective for carbene transfer are also effective for these reactions. Particularly, Rh2(OAc)4 has demonstrated great effectiveness in the inter- and intramolecular nitrene C-H insertions. The exploration of enantioselective C-H amination using chiral rhodium catalysts has been reported by several groups.225,244,253-255 Hashimoto s dirhodium tetrakis[A-tetrachlorophthaloyl-(A)-/ r/-leuci-nate], Rh2(derived rhodium complex, Rh2(i -BNP)4 48,244 afforded moderate enantiomeric excess for amidation of benzylic C-H bonds with NsN=IPh. [Pg.196]

Dirhodium(II) tetrakis(carboxamides), constructed with chiral 2-pyrroli-done-5-carboxylate esters so that the two nitrogen donor atoms on each rhodium are in a cis arrangement, represent a new class of chiral catalysts with broad applicability to enantioselective metal carbene transformations. Enantiomeric excesses greater than 90% have been achieved in intramolecular cyclopropanation reactions of allyl diazoacetates. In intermolecular cyclopropanation reactions with monosubsti-tuted olefins, the cis-disubstituted cyclopropane is formed with a higher enantiomeric excess than the trans isomer, and for cyclopropenation of 1-alkynes extraordinary selectivity has been achieved. Carbon-hydro-gen insertion reactions of diazoacetate esters that result in substituted y-butyrolactones occur in high yield and with enantiomeric excess as high as 90% with the use of these catalysts. Their design affords stabilization of the intermediate metal carbene and orientation of the carbene substituents for selectivity enhancement. [Pg.45]

Chiral rhodium(II) carboxamides are exceptional catalysts for highly enantio-selective intermolecular cyclopropenation reactions (50). With ethyl diazoacetate and a series of alkynes, use of dirhodium(II) tetrakis[methyl 2-pyrrolidone-5-(R)-carboxylate], Rh2(5R-MEPY)4, in catalytic amounts ( 1.0 mol %) results in the formation of ethyl eyelopropene-3-earboxylates (eq 4) with enantiomeric excesses... [Pg.53]

For enantioselective intramolecular cyclopropanation with chiral catalysts, tetrakis[(5)- and (7 )-5-methoxycarbonyl-2-pyrrolidonato]dirhodium 30 and related rhodium complexes such as 31 and 32 (only the S -enantiomer is shown) appear the best choices at this time. With the appropriate catalyst, impressive enantiomeric excesses have been obtained for intramolecular cyclopropanations of unsaturated diazoacetates and diazoacetamides, as is illustrated by the following examples (see also Houben-Weyl, Vol. E21c, p3234). [Pg.492]

Yields and cnantioselectivities are low in reactions with disubstituted alkyncs. Asymmetric synthesis of lactams A rhodium catalyst with a chiral oxazolidinonc ligand, dirhodium(II) tctrakis[methyl 2-oxazolidinonc-4 (S)-carboxylate] (1), can effect... [Pg.303]

Hashimoto and coworkers [69] have recently begun to explore the use of chiral rhodium catalysts in the intramolecular dipolar cycloadditirai reactions of indoles, and have applied their methodology to the synthesis of the Aspidosperma ring system. Thus, the cycloaddition of the cyclopropyl carbonyl ylides derived from cyclopropyl diazo-5-imido-3-ketoesters 135 upon treatment with dirhodium (11) tetrakis[Af-tetrachlorophthaloyl-(5)-ferf-leucinate] gave cycloadducts 136 along with the spiro[2.3]hexanes 137 in only moderate yields (Scheme 34). Although the reaction proceeds with exclusive endo diastereoselectivity, only moderate enantioselectivities of up to 66% enantiomeric excess (ee) could be obtained. [Pg.301]

Asymmetric cyclopropanation. The ability to effect ligand exchange between rhodium(II) acetate and various amides has lead to a search for novel, chiral rhodium(II) catalysts for enantioselective cyclopropanation with diazo carbonyl compounds. The most promising to date are prepared from methyl (S)- or (R)-pyroglutamate (1), [dirhodium(ll) tetrakis(methyl 2-pyrrolidone-5-carboxylate)]. Thus these complexes, Rh2[(S)- or (R)-l]4, effect intramolecular cyclopropanation of allylic diazoacetates (2) to give the cyclo-propanated y-lactones 3 in 65 S 94% ee (equation 1). In general, the enantioselectivity is higher in cyclopropanation of (Z)-alkenes. [Pg.303]

Another successful catalytic enantioselective 1,3-dipolar cycloaddition of Qf-diazocarbonyl compounds using phthaloyl-derived chiral rhodium(II) catalysts has been demonstrated [ill]. Six-membered ring carbonyl ylide formation from the a-diazo ketone 80 and subsequent 1,3-cycloaddition with DMAD under the influence of 1 mol % of dirhodium(II) tetrakis[M-benzene-fused-phthaloyl-(S)-phenylvaline], Rh2(S-BPTV)4 101 [112], has been explored to obtain the cycloadduct 102 in up to 92% ee (Scheme 31). [Pg.175]

Rhodium(II)-MEPY and rhodium(II)-MACIM (methyl 1-acetylimidazolidin-2-one-4-carboxylate) complexes are efficient chiral catalysts for intramolecular carbon-hydrogen insertion reactions of diazoacetates (224) and metal carbene transformations (225). Dirhodium(II) carboxylates of similar structure (eg, piperidinonate complexes of the Rh2(ligand)4 type) have been found efficient catalysts for asymmetric cyclopropanation of olefins (226). [Pg.701]

Diazo Compounds Decomposition with Chiral Rhodium Catalysts. The first chiral rhodium catalyzed asymmetric cyclopropanation was reported in 1989 (75). Structures of the catalysts were based on the framework of dirhodium(II) tetrakis(carboxylate) 1 with the carboxylate ligands replaced with... [Pg.885]

The dirhodium complexes of the general structure 7.64 and 7.65 have been found to be very effective. Note that in these complexes the oxidation state of rhodium is 2+, and there is a single metal-metal bond between the two metal atoms. A copper (I) complex such as 7.66 having a chiral bis-oxazoline ligand is an early example of a stereoselective cyclopropanation catalyst. In all these complexes L is a weakly coordinating ligand, usually a solvent molecule. [Pg.230]

See other pages where Rhodium chiral dirhodium catalysts is mentioned: [Pg.440]    [Pg.23]    [Pg.315]    [Pg.505]    [Pg.125]    [Pg.217]    [Pg.182]    [Pg.50]    [Pg.58]    [Pg.803]    [Pg.390]    [Pg.523]    [Pg.309]    [Pg.498]    [Pg.305]    [Pg.246]    [Pg.438]    [Pg.309]    [Pg.342]    [Pg.342]    [Pg.795]    [Pg.801]    [Pg.518]    [Pg.454]    [Pg.775]    [Pg.303]    [Pg.310]    [Pg.120]    [Pg.747]    [Pg.747]   
See also in sourсe #XX -- [ Pg.290 ]



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