Lewis acids carbenoid catalysts

Suga et al. (197) reported the first stereocontrolled 1,3-dipolar cycloaddition reactions of carbonyl ylides with electron-deficient alkenes using a Lewis acid catalyst. Carbonyl ylides are highly reactive 1,3-dipoles and cannot be isolated. They are mainly generated through transition metal carbenoid intermediates derived in situ from diazo precursors by treatment with a transition metal catalyst. When methyl o-(diazoacetyl)benzoate is treated with A-methylmaleimide at reflux... 

One of the attractions of dirhodium paddelwheel complexes is their ability to catalyse a wide variety of organic transformations such as C-H insertions, cyclopropanations and ylide formation. A review on the application of high symmetry chiral Rh2(II,II) paddlewheel compounds highlights their application as catalysts for asymmetric metal carbenoid and nitrenoid reactions, and as Lewis acids.59 Their impressive performance as catalysts in C-H functionalisation reactions has been exploited in the synthesis of complex natural products and pharmaceutical agents. A recent review on catalytic C-H functionalisation by metal carbenoid and nitrenoid insertion demonstrates the important role of dirhodium species in this field.60... 

An alternative approach to aziridine synthesis involves transfer of a carbenoid species to imines. Jacobsen achieved the first asymmetric aziridination of imines by transfer of copper carbenoids derived from copper bis-oxazohne catalysts and ethyl diazoacetate onto imines, but this process only proceeds with moderate yield and selectivity. Better results have been achieved by addition of ethyl diazoacetate to imines in the presence of enantiopure Lewis acids such as the boron-based catalysts prepared from vaulted biaryls such as VAPOL (4.154) and B(OPh)3. A range of aryl and alkyl N-benzylaldimines, for example (4.155) and (4.156), undergo aziridination to give ds-aziridines with high ee using this procedure. 

Rh and Cu complexes are commonly employed in metal carbenoid-involved asymmetric C—H bond functionalization while chiral catalysts based on Ir, Ru, and Fe as well as Lewis acids came into this area recently. This section aims to introduce the recent developments in asymmetric C—H bond functionalization achieved by metal carbenoids. 

Introduction. The principal uses of CUSO4 in organic synthesis stem from the chemical properties of Cu +. Firstly Cu + functions as a Lewis acid towards electron donor functions and can thus promote a variety of acid-catalyzed processes. Secondly Cu + reacts readily with diazo compounds to give carbenoid intermediates useful in subsequent addition reactions. Thirdly Cu + functions as an effective redox catalyst in several mixed oxidizing systems. 

Many rhodium(II) complexes are excellent catalysts for metal-carbenoid-mediated enantioselective C-H insertion reactions [101]. In 2002, computational studies by Nakamura and co-workers suggested the dirhodium tetracarboxylate catalyzed diazo compounds insertion reaction to alkanes C-H bonds proceed through a three-centered hydride-transfer-like transition state (Fig. 25) [102]. Only one rhodium atom of the catalyst is involved in the formation of rhodium carbene intermediate, while the other rhodium atom served as a mobile ligand, which enhanced the electrophilicity of the first one and facilitate the cleavage of rhodium-carbon bond. In this case, the metal-metal bond constitutes a special example of Lewis acid activation of Lewis acidic transition-metal catalyst. 

---