Cobalt complexes ligand effects

Similar effects are observed in the iron complexes of Eqs. (9.13) and (9.14). The charge on the negatively charged ligands dominates the redox potential, and we observe stabilization of the iron(iii) state. The complexes are high-spin in both the oxidation states. The importance of the low-spin configuration (as in our discussion of the cobalt complexes) is seen with the complex ions [Fe(CN)6] and [Fe(CN)6] (Fq. 9.15), both of which are low-spin. 

Kanemasa et al.63 reported that cationic aqua complexes prepared from the /ram-chelating tridentate ligand (i ,f )-dibenzofuran-4,6-diyl-2,2,-Mv(4-phcnyloxazolinc) (DBFOX/Ph) and various metal(II) perchlorates are effective catalysts that induce absolute chiral control in the Diels-Alder reactions of 3-alkenoyl-2-oxazolidinone dienophiles (Eq. 12.20). The nickel(II), cobalt(II), copper(II), and zinc(II) complexes are effective in the presence of six equivalents of water for cobalt and nickel and three equivalents of water for copper and zinc. 

A cobalt complex containing this type of ligand is effective in the sodium borohydride-mediated enantioselective reduction of a variety of a,/ -unsaturated carboxylates. As can be seen from Scheme 6-8, in the presence of a catalytic amount of a complex formed in situ from C0CI2 and chiral ligand 11, reduction proceeds smoothly, giving product with up to 96% ee. The chiral ligand can easily be recovered by treating the reaction mixture with acetic acid. 

Table III. Effect of Ligand Environment on Catalytic Activity of Cobalt Complexes...

Measurements of the equilibrium constants of the reactions imply that the stabilities of the monosubstituted complexes are predominantly determined by steric effects of the ligand, reflecting a very crowded space around the metal in this system. The large ligands PPh3 or P(c-C6H,) do not react with the cobalt complex. 

Electronic effects become apparent in the M—NCS/M—SCN linkage switches observed in a series of Pd11 (iso)thiocyanate complexes. Ligands positioned trans to the pseudohalide and that are suited to accept electron density from the metal into empty orbitals (backbonding) stabilize the Pd—NCS linkage isomer. However, this rationale is contradicted by the trend in Co—(NCS) bonding in a series of cobalt complexes (see ref. 204b for a review). 

Spectroelectrochemistry [Fig. 41(a,h)] measurements showed that the reversible wave at 0.2 V involves two electrochemical processes, corresponding to the Ru (III)Ru(III)Ru(III)/Ru(III)Ru(III)Ru(II) E° = 0.21 V) and Co(III/II)P( ° = 0.07 V) redox pairs. Surprisingly, in the him, there is an inversion in the redox potentials observed in solution (Table IV), so that the peripheral clusters are reduced before the cobalt porphyrin. This fact was ascribed to axial ligand effects, in changing from the acetonitrile solution to the solid-hlm-water interface (170). This is a very important aspect since now the peripheral complexes in the reduced form can act as electron relays enhancing the catalytic activity of the cobalt porphyrin center. 

Corroles are tetrapyrrole macrocycles that are closely related to porphyrins, with one carbon atom less in the onter periphery and one NH proton more in their inner core. They may also be considered as the aromatic version (identical skeleton) of the only partially conjugated corrin, the cobalt-coordinating ligand in Vitamin B. Two potential application of corroles are in tumor detection and their use in photovoltaic devices. Selective snbstitntion of corroles via nitration, hydroformylation, and chlorosulfonation for the gallinm were studied in detail and the respective mechanistic pathways and spectroscopic data were reported, (an example is shown in Fignre 27). Overall, over 139 varions corroles were synthesized and the effect of various metal complexation pertaining to their selective reactivity examined. ... 

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