Diazo compounds tetrakis

Decomposition of diazo compounds by iron porphyrins is a convenient method for the synthesis of non-heteroatom carbene-iron porphyrins [22]. Reaction of [Fe(F2o-TPP)] [F20-TPP = meso-tetrakis(pentafluorophenyl)porphyrinato dianion] with diazo compounds N2C(Ph)R (R = Ph, C02Et, C02CH2CH=CH2) under an inert atmosphere afforded complexes [Fe(F2o-TPP)C(Ph)R] in 65-70% yields (Scheme 2). Like the halocarbene complex [Fe(TPP)(CCl2)], [Fe(F2o-TPP)CPh2] reacted with Melm to afford six-coordinate species [(MeIm)Fe(F2o-TPP)CPh2] in 65% isolated yield. 

Rh(II) carboxylates, especially Rh2(OAc)4> have emerged as the most generally effective catalysts for metal carbene transformations [7-10] and thus interest continues in the design and development of dirhodium(II) complexes that possess chiral51igands. They are structurally well-defined, with D2h symmetry [51] and axial coordination sites at which carbene formation occurs in reactions with diazo compounds. With chiral dirhodium(II) carboxylates the asymmetric center is located relatively far from the carbene center in the metal carbene intermediate. The first of these to be reported with applications to cyclopropanation reactions was developed by Brunner [52], who prepared 13 chiral dirhodium(II) tetrakis(car-boxylate) derivatives (16) from enantiomerically pure carboxylic acids RlR2R3CC OOH with substituents that were varied from H, Me, and Ph to OH, NHAc, and CF3. However, reactions performed between ethyl diazoacetate and styrene yielded cyclopropane products whose enantiopurities were less than 12% ee, a situation analogous to that encountered by Nozaki [2] in the first applications of chiral Schiff base-Cu(II) catalysts. 

Intermolecular insertion to aryl C—H bonds is possible. The asymmetric intramolecular reaction of the a-diazo compound 354 catalysed by Rh2[(S)-PTTL]4, Rh2[(S)—PTTL]4 = dirhodium tetrakis[N-phthaloyl(S)—t—leucinate], afforded indane... 

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... 

The assumption that formation of episulphides from diazo-compounds and thioketones proceeds via formation of unstable thiadiazolines now seems warranted because MiddIeton has isolated 2,2,5,5-tetrakis(trifluoro-methyl)-l,3,4-thiadiazoline (27) and 2,2-bis(trifluoromethyl)-5-bis(trifluoro-methyl)methylene-l,3,4-thiadiazoline (28) from products obtained by treatment of hexafluorothioacetone and bis(trifluoromethyI)thioketen, respectively, with bis(trifluoromethyI)diazomethane at sub-zero temperatures thermolysis of these thiadiazolines yields the corresponding episulphides ... 

In a similar manner, transfer of oxocarbenes from a-diazo ketones to benzene mediated by tetrakis(trifluoroacetato)dirhodium(II) yields, in some cases, 7-(l-oxoalkyl)cyclohepta-l,3,5-trienes. These compounds undergo facile acid-catalyzed isomerization to benzyl ketones 36. In other cases, the latter products are formed directly under the conditions of the carbenoid reaction " for examples, see Houben-Weyl, Vol. E19b, pl313. 

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. 

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). 

Transition metal-catalysed methods for carbenoid insertion into C-H bonds remain well documented. The asymmetric intramolecular Cu(II)-catalysed C-H insertion reactions of (i) a-diazo-/ -keto esters and phosphonates and (ii) a-diazo sulfones have been described. One can note that the optimal reaction conditions have been found to be quite similar regardless of the nature of the carbenoid precursor the best conditions featured CUCI2 as Cu(II)-source, bis(oxazoline) (68) as chiral ligand and sodium tetrakis[3,5-bis(trifluoromethyl)phenyl] borate (i.e., NaBARF) as additive. Under the so-optimized reaction conditions, each of these carbenoid sources have been eonverted into five-membered cyclopentanone-based derivatives (69), whereas a-sulfonyl diazo esters (70) have led to six-membered cyclic compounds (71), thus featuring a distinct but well-known selectivity. In a related work, the asymmetric C-H insertion cyclization of (70) to (71) has also been achieved under Rh(II)-catalysis, using a combination of Rh2(5-pttl)4 (72) as chiral catalyst and menthyl ester as chiral auxiliary. As already mentioned in the previous section, allene-containing substrates (49) have been shown to undergo an intramolecular C-H insertion process under Rh(II)-catalysis. ... 

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