Chiral arene chromium complexes

The aromatic products often contain an arene-complexed chromium tricarbonyl unit. The metal-free product is obtained by oxidation commonly using CAN or air under irradiation. The formation of complexed adducts can be used to prepare chiral chromium tricarbonyl arene complexes (Scheme 44, see Arene Complexes). 

The chromium-templated coupling of alkenyl- or arylcarbene, aUcyne and carbonyl ligands generates arene tricarbonylchromium complexes as primary benzannulation products which - based on their unsymmetric substitution pattern - bear a plane of chirality. Chiral arene complexes are powerful reagents in stereoselective synthesis however, the preparation of pure enantiomers is a lengthy and often tedious procedure, and thus diastereoselective benzannulation appears to be an attractive alternative. In order to lure the chromium fragment to one or the other face of the arene formed, chiral information may be incorporated in the carbene complex or the aUcyne. 

Due to the inherent unsymmetric arene substitution pattern the benzannulation reaction creates a plane of chirality in the resulting tricarbonyl chromium complex, and - under achiral conditions - produces a racemic mixture of arene Cr(CO)3 complexes. Since the resolution of planar chiral arene chromium complexes can be rather tedious, diastereoselective benzannulation approaches towards optically pure planar chiral products appear highly attractive. This strategy requires the incorporation of chiral information into the starting materials which may be based on one of three options a stereogenic element can be introduced in the alkyne side chain, in the carbene carbon side chain or - most general and most attractive - in the heteroatom carbene side chain (Scheme 20). 

Recently, Lacour, Sauvage and coworkers were able to show that the association of chiral [CuL2] complexes (L=2-R-phen,6-R-bpy and2-iminopyridine) with TRISPHAT 8 leads to an NMR enantiodifferentiation, which allows the determination of the kinetics of racemization of the complexes (bpy=2,2 -bipyri-dine phen=l,10-phenanthroline) [119]. This type of application has recently been reported in conjunction with chiral sandwich-shaped trinuclear silver(l) complexes [122]. Several reports, independent from Lacour s group,have confirmed the efficiency of these chiral shift agents [123-127]. Finally, TRISPHAT can be used to determine the enantiomeric purity of (r] -arene)chromium complexes. These results broaden the field of application of 8 to chiral neutral, and not just cationic, species [114,128,129]. 

Mulzer J, Ohler E (2004) Olefin Metathesis in Natural Product Syntheses. 13 269-366 Muniz K (2004) Planar Chiral Arene Chromium (0) Complexes as Ligands for Asymetric Catalysis. 7 205-223 Murai S, see Kakiuchi F (1999) 3 47-79... 

As well as organic chiral auxiliaries, organometallic fragments have found some application as chiral auxiliaries in conjugate addition reactions. Particularly noteworthy are chiral molybdenum allyl complexes [69], chiral iron complexes [70], and planar chiral arene chromium species [71]. 

In a further development of the norbornene/anihne OHA reaction, Salzer and coworkers used planar chiral arene-chromium-tricarbonyl-based diphosphines for the in situ formation of cis-trans mixtures of complexes 9 and 10 that gave enanti-oselectivities of 51% and 70%, respectively, at 333 K and with a 40-fold excess of naked fluoride , but activities were very low. In the same paper complex 6 was shown to be superior in both activity and enantioselectivity (64% ee) to the corresponding Josiphos compound 5 [15]. The activated N-H bond of benzamide was also stereoselectively added across the double bond of norbornene to afford N-benzoyl-e%o-aminonorbornane in up to 50% yield and 73% ee in the presence of 0.5mol% [IrCl((R)-MeO-bipheb)]2 at 373 K [16]. 

Unlike the ferrocenes, the arene complexes of chromium, in particular the arenechromi-umtricarbonyls, have seen much less use in asymmetric catalysis. This is beginning to change, however , and a number of synthetic transformations of arenechromiumtricar-bonyls owe their existence to the formation of planar chiral chromium complexes by... 

Three types of reaction systems have been designed and applied for the enantioposition-selective asymmetric cross-coupling reactions so far. First example is asymmetric induction of planar chirality on chromium-arene complexes [7,8]. T vo chloro-suhstituents in a tricarhonyl("n6-o-dichlorobenzene)chromium are prochiral with respect to the planar chirality of the 7t-arene-metal moiety, thus an enantioposition-selective substitution at one of the two chloro substituents takes place to give a planar chiral monosubstitution product with a minor amount of the disubstitution product. A similar methodology of monosuhstitution can be applicable to the synthesis of axially chiral biaryl molecules from an achiral ditriflate in which the two tri-fluoromethanesulfonyloxy groups are enantiotopic [9-11]. The last example is intramolecular alkylation of alkenyl triflate with one of the enantiotopic alkylboranes, which leads to a chiral cyclic system [12], The structures of the three representative substrates are illustrated in Figure 8F.1. 

Desymmetrisation by enantioselective ortholithiation has been achieved with ferrocenylcarboxamides 434,187 and also (with chiral lithium amide bases) a number of chromium-arene complexes.188 The chromium arene complex 435, on treatment with s-BuLi-(-)-sparteine, gives 436 enantioselectively, and reaction with electrophiles leads to 437. However, further treatment with r-BuLi generates the doubly lithiated species 438, in which the new organolithium centre is more reactive than the old, which still carries the (-)-sparteine ligand. Reaction of 438 with an electrophile followed by protonation therefore gives ent-431.m... 

Uemura and Kamikawa have presented a review on the stereoselective synthesis of axially chiral biaryls utilizing planar chiral (arene)chromium complexes [44]. 

The benzannulation affords arene-Cr(CO)3 complexes possessing a plane of chirality resulting from the unsymmetrical arene substitution pattern. This aspect is relevant to stereoselective synthesis, in which enantiopure arene tricarbonyl chromium complexes play a major role [56]. The benzannulation reaction avoids both harsh conditions incompatible with the retention of chiral information and the cumbersome separation of enantiomers, and is thus attractive for the diastereo- and enantioselective synthesis of arene complexes [17b, 57]. 

The first enantioselective functionalization of tricarbonylchromium arene complexes using chiral bases, to generate planar chiral chromium complexes, was reported by Simpkins and coworkers in 1994 and involved a directed orf/zo-lithiation and subsequent quench with an electrophile78. Both aromatic and benzylic functionalization of tricarbonylchromium arene complexes has been achieved. 

Direct nucleophilic addition of potassium enolates derived from bis(trimethylsilyl)ketene acetals to aromatic chromium-complexed aromatic ethers affords meta substituted products (Scheme 124). A very high degree of asymmetric induction is obtained upon reaction of chiral arene chromium tricarbonyl complexes. For example, alkylation of complex (80)gave (81)afterdecomplexation(Scheme 125). ... 

Bolm, C. Muniz, K. Planar Chiral Arene Chromium (0) Complexes Potential Ligands for Asymmetric Catalysis, Chem. Soc. Rev. 1999, 28, 51-59. 

Chung et al. [179] demonstrated that carbohydrate auxiliaries can also be employed for the preparation of chiral (arene)tricarbonyl complexes, which are useful intermediates in organic synthesis. The D-glucose-derived benzylidene acetal 284 was reacted with hexacarbonyl chromium... 

In 1997, Schinzer and coworkers (D. Schinzer, U. Abel, and P. G. Jones, Synlett 632 (1997)] reported as asymmetric synthesis of the cephalotaxine subunit (S,R)-2Si from (S)-286 (see Scheme 49). The stereochemistry of the 2-(dimethylphenylsilylmethyl)propenyl group in 286 was established through a planar chiral tj -chromium arene complex. 

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