Absolute configuration of complexes

Absolute configuration of complexes. 495-496 Absolute electronegativity, 351 Absolute hardness. 351 Absorption spectra of lanthanide and actinide ions. 604-607 Acceptor number CAN). 370 Achiral molecules, and point groups, 64 Acids. 2... 

Tarczay G, Magyarfalvi G, Vass E (2006) Towards the determination of the absolute configuration of complex molecular systems matrix isolation vibrational circular dichroism study of (R)-2-amino-l -propanol. Angew Chem Int Ed 45 1775-1777... 

X-ray determination of the absolute configuration of complex 13 (240) allows one to assign retention of configuration at silicon in the reaction shown in equation [70]. 

Chemical conversion of compounds to intermediates of known absolute configuration is a method routinely used to determine absolute configuration (86). This is necessary because x-ray analysis is not always possible suitable crystals are required and deterrnination of the absolute configuration of many crystalline molecules caimot be done because of poor resolution. Such poor resolution is usually a function of either molecular instability or the complex nature of the molecule. For example, the relative configuration of the macroHde immunosuppressant FK-506 (105) (Fig. 8), which contains 14 stereocenters, was determined by x-ray crystallographic studies. However, the absolute configuration could only be elucidated by chemical degradation and isolation of L-pipecoUc acid (110) (80). 

Figure B The absolute configuration of the optical isomers of a metal tris-chelates complex such as [Co(en)3]. (a) A configuration and (b) A configuration.

The absolute configuration of products obtained in the highly stereoselective cycloaddition reactions with inverse electron-demand catalyzed by the t-Bu-BOX-Cu(II) complex can also be accounted for by a square-planar geometry at the cop-per(II) center. A square-planar intermediate is supported by the X-ray structure of the hydrolyzed enone bound to the chiral BOX-copper(II) catalyst, shown as 29b in Scheme 4.24. 

Absolute configurations of the isoxazolidines obtained in the nitrone cydoaddition reactions described in Schemes 7.21 and 7.22 were determined to be 3S,41 ,5S structure by comparison of the optical rotations as well as retention times in a chiral HPLC analysis with those of the authentic samples. Selection of the si face at C/ position of 3-crotonoyl-2-oxazolidinone in nitrone cydoadditions was the same as that observed in the Diels-Alder reactions of cyclopentadiene with 3-croto-noyl-2-oxazolidinone in the presence of the J ,J -DBF0X/Ph-Ni(C104)2-3H20 complex (Scheme 7.7), and this indicates that the s-cis conformation of the dipolaro-phile has participated in the reaction. 

The absolute configuration of transition metal complexes. R. D. Gillard and P. R. Mitchell, Struct. Bonding (Berlin), 1970,7, 46-86 (165). 

Absolute configurations of metal complexes determined by X-ray analvsis. Y. Saito, Coord. Chem. Rev., 1974,13,305-337 (52). 

Utilization of the Pfeiffer effect and outer-sphere complexation for the prediction of absolute configurations of optically active metal complexes. S. Kirschner and I. Bakkar, Coord. Chem. Rev., 1982,43, 325-335 (27). 

Thus, the enantiomeric contents in a pair of sulphoxides can be determined by the NMR chemical shifts in the methine or methylene protons in the two diastereomeric complexes which are stabilized by the hydrogen bond between the hydroxyl and the sulphinyl groups147-151 (Scheme 13). Similarly, the enantiomeric purity and absolute configurations of chiral sulphinate ester can be determined by measuring the H NMR shifts in the presence of the optically active alcohols152. 

Binaphthol-derived titanium complexes [64], prepared from chiral ligands 65 (Figure 3.13), also performed very well in the cycloadditions of conjugated aldehydes with cyclic and acyclic dienes. Judging from the absolute configurations of endo and exo adducts, this catalyst should cover the re-face of carbonyl on its u tz-coordination to s-trans a,/l-unsaturated aldehydes, and hence dienes should approach selectively from the si-face. 

Gillard RD, Mitchell PR (1970) The Absolute Configuration of Transition Metal Complexes. 7 46-86... 

Cycloamylose forms inclusion complexes stereoselectively with the enantiomers of isopropyl methylphosphinate (124) from which it was possible to isolate one enantiomer with an optical purity of 66%. The absolute configuration of menthyl methylphosphinate has been revised to the opposite of that previously assigned. 

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