Chirality transfer ligands

Keller, H. J., and Soos,-Z. G. Solid Charge-Transfer Complexes of Phenazines. 127, 169-216 (1985). Kellogg, R. M. Bioorganic Modelling — Stereoselective Reactions with Chiral Neutral Ligand Complexes as Model Systems for Enzyme Catalysis. 101, 111-145 (1982). 

In another context, chiral thioimidazolidine ligands have been successfully applied to the ruthenium-catalysed asymmetric hydrogen transfer of several aryl ketones by Kim et al., furnishing the corresponding chiral alcohols with high yields and enantioselectivities of up to 77% ee (Scheme 9.12). ... 

The employment of silver(i) complexes having a chiral carbene ligand L (Figure 19) and the empirical formula [AgBrL] has been reported for use as both carbene-transfer reagents to the corresponding dichloropalladium(n)... 

Chan has discovered a completely atropdiasteroselective synthesis of a biaryl diphosphine by asymmetric intramolecular Ullmann coupling or Fe(m)-promoted oxidative coupling. A chiral atropisomeric biaryl bisphosphine ligand 2 was synthesized through this central-to-axial chirality transfer.38 Recently, a xylyl-biaryl bisphosphine ligand, Xyl-TetraPHEMP, was introduced by Moran, and is found to be effective for the Ru-catalyzed hydrogenation of aryl ketone.39... 

Recently, the use of chiral carbanionic ligands as non-transferable ligands has received attention. Gais and BoBhammer have successfully applied cyclic ct-sulfonimidoyl carbanion 24 in the conjugate addition of alkylcuprates to cycloalkenones (Scheme 14).30... 

The previous section discussed chelation enforced intra-annular chirality transfer in the asymmetric synthesis of substituted carbonyl compounds. These compounds can be used as building blocks in the asymmetric synthesis of important chiral ligands or biologically active natural compounds. Asymmetric synthesis of chiral quaternary carbon centers has been of significant interest because several types of natural products with bioactivity possess a quaternary stereocenter, so the synthesis of such compounds raises the challenge of enantiomer construction. This applies especially to the asymmetric synthesis of amino group-substituted carboxylic acids with quaternary chiral centers. 

Chirality transfer in catalytic asymmetric hydrogenation can be achieved not only by using powerful chiral ligands such as BINAP or DuPhos but also by the formation of a dynamic conformational isomer. The availability of many enantiomerically pure diols allows the production of electron-deficient, bi-dentate phosphate in the form of 27. The backbone O-R -O can define the chirality of the 0-R2-0 in complex 28, hence realizing the chirality transfer.44... 

Studies of the transfer of Br+ and I+ from amine-coordinated halonium ions to acceptor l-co-alkenols have been undertaken to determine the mechanism in an effort to assist in the development of chiral transfer reagents. Transfer of Br+ and I+ from two commercially available dimeric hydroquinine and hydroquinidine ligands ((DHQ)2PHAL and (DHQD)2PHAL) to various 1, (o-alkenols and l,co-alkenoic acids is shown to provide enantiomeric excesses of 4-47% depending on the acceptor alkene. 

A catalytic asymmetric [4+2]-cydoaddition of a vinylallene with butadiene has been achieved successfully, in which a palladium complex modified by a ferrocene-derived chiral monophosphine ligand proved to be a superior catalyst transferring chirality to the product (Scheme 16.80) [90],... 

Chiral effector ligands can be a variety of molecules, including amino acids. The chiral alcohol products of the chiral-transfer reactions in Fig. 11.4 cycle back into these reactions by subsequent tomplexation with the pool of diisopropyl zinc. 

A number of conjugate additions delivering excellent enantioselectivities through the use of organocuprates in the presence of stoichiometric amounts of chiral (non-transferable) ligands are known today [7-9]. 

The use of copper catalysts based on chiral phosphorus ligands to assist 1,4-additions of dialkylzinc reagents has in recent years produced major breakthroughs, with excellent enantioselectivities. A number of monodentate and bidentate phos-phoramidites, phosphites, phosphonites, and phosphines are now available as chiral ligands for alkyl transfer to a variety of cyclic and acyclic enones. So far. 

Ikariya and Noyori et al. also reported the synthesis of new chiral Cp Rh and Cp Ir complexes (13 and 14) bearing chiral diamine ligands [(R,R)-TsCYDN and (R,R)-TsDPEN] (Scheme 5.10) these are isoelectronic with the chiral Ru complex mentioned above, and may be used as effective catalysts in the asymmetric transfer hydrogenation of aromatic ketones [42], The Cp Ir hydride complex [Cp IrH(R,R)-Tscydn] (14c) and 5-coordinated amide complex (14d), both of which would have an important role as catalytic intermediates, were also successfully prepared. 

Analogous water-soluble Cp Rh and Cp lr complexes were prepared by Williams et al., and used in the asymmetric transfer hydrogenation of aromatic ketones under aqueous conditions [43]. These catalyst complexes contain water-soluble chiral diamine ligands (Scheme 5.11), and were prepared in situ by reacting [Cp MCl2]2 (M = Rh, Ir) with ligands 15a or 15b in the presence of a base, and used immediately. The results of the asymmetric transfer hydrogenation of... 

---