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Coordination of cobalt

If our postulates are correct the most interesting feature of P-450 is the manner in which the protein has adjusted the coordination geometry of the iron and then provided near-neighbour reactive groups to take advantage of the activation generated by the curious coordination. Vallee and Williams (68) have observed this situation in zinc, copper and iron enzymes and referred to it as an entatic state of the protein. It is also apparent that some such adjustment of the coordination of cobalt occurs in the vitamin B12 dependent enzymes. As a final example we have looked at the absorption spectra of chlorophyll for its spectrum is in many respects very like that of a metal-porphyrin. This last note is intended to stress the features of chlorophyll chemistry which parallel those of P-450. [Pg.149]

Protection and Activation of Alkynes by the Coordination of Cobalt Carbonyl... [Pg.366]

Reaction of (9) with A1H((-Bu)2 liberates cyclooctene, but at 40 °C it slowly isomerizes thermally in solution to the stable CpCo derivative (11) (Scheme 18). In the presence of excess cod, this latter complex is converted catalytically to tetrahydropentalene. Ring contraction to the pentalenyl system can be understood as an intraligand reductive elimination see Reductive Elimination), the driving force of which may be coordination of cobalt to the double bond of free cod in solution. In the catalytic cycle some (10) is formed. [Pg.859]

The cobalamin coenzyme is bound by the apoenzyme with no significant change in the absorption spectrum." This suggests that no major change occurs in the coordination of cobalt(IIl). The first step of the reaction involves homo-lytic fission of the Co—C bond 2-184, 186-188... [Pg.100]

The studies presented here deal with the coordination of cobalt atoms in cobalt aluminophosphates (CoAPOs). The compounds investigated include those of CHA topology (CoMnAPO-34) [51] and of SOD topology [42].In the case of the CoMnAPO, a perfect fit to the filtered EXAFS function of the first coordination shell is obtained with four oxygen atoms at a distance Rco-o of 1-93 A. This result is consistent with the presumed incorporation of the Co atoms into the alu-minophosphate framework [51]. [Pg.449]

Ammonia forms a great variety of addition or coordination compounds (qv), also called ammoniates, ia analogy with hydrates. Thus CaCl2 bNH and CuSO TNH are comparable to CaCl2 6H20 and CuSO 4H20, respectively, and, when regarded as coordination compounds, are called ammines and written as complexes, eg, [Cu(NH2)4]S04. The solubiHty ia water of such compounds is often quite different from the solubiHty of the parent salts. For example, silver chloride, AgQ., is almost iasoluble ia water, whereas [Ag(NH2)2]Cl is readily soluble. Thus silver chloride dissolves ia aqueous ammonia. Similar reactions take place with other water iasoluble silver and copper salts. Many ammines can be obtained ia a crystalline form, particularly those of cobalt, chromium, and platinum. [Pg.338]

Cobalt exists in the +2 or +3 valence states for the majority of its compounds and complexes. A multitude of complexes of the cobalt(III) ion [22541-63-5] exist, but few stable simple salts are known (2). Werner s discovery and detailed studies of the cobalt(III) ammine complexes contributed gready to modem coordination chemistry and understanding of ligand exchange (3). Octahedral stereochemistries are the most common for the cobalt(II) ion [22541-53-3] as well as for cobalt(III). Cobalt(II) forms numerous simple compounds and complexes, most of which are octahedral or tetrahedral in nature cobalt(II) forms more tetrahedral complexes than other transition-metal ions. Because of the small stabiUty difference between octahedral and tetrahedral complexes of cobalt(II), both can be found in equiUbrium for a number of complexes. Typically, octahedral cobalt(II) salts and complexes are pink to brownish red most of the tetrahedral Co(II) species are blue (see Coordination compounds). [Pg.377]

The metal-vapor technique was applied to cobalt atoms and r-BuC = P (01JOM(635)212). The mixture of products that resulted includes the mixed-ligand sandwiches 170 and 171. Further interaction of complex 170 with [W(C0)5(THF)] leads to the coordination of the W(CO)5-group via the phosphorus heteroatom of the four-membered ring to yield 172. [Pg.40]

When, however, the ligand molecule or ion has two atoms, each of which has a lone pair of electrons, then the molecule has two donor atoms and it may be possible to form two coordinate bonds with the same metal ion such a ligand is said to be bidentate and may be exemplified by consideration of the tris(ethylenediamine)cobalt(III) complex, [Co(en)3]3+. In this six-coordinate octahedral complex of cobalt(III), each of the bidentate ethylenediamine molecules is bound to the metal ion through the lone pair electrons of the two nitrogen atoms. This results in the formation of three five-membered rings, each including the metal ion the process of ring formation is called chelation. [Pg.52]

It was shown that dibenzothiophene oxide 17 is inert to 1-benzyl-l,4-dihydro nicotinamide (BNAH) but that, in the presence of catalytic amounts of metalloporphyrin, 17 is reduced quantitatively by BNAH. From experimental results with different catalysts [meso-tetraphenylporphinato iron(III) chloride (TPPFeCl) being the best] and a series of substituted sulfoxides, Oae and coworkers80 suggest an initial SET from BNAH to Fe1 followed by a second SET from the catalyst to the sulfoxide. The results are also consistent with an initial coordination of the substrate to Fem, thus weakening the sulfur-oxygen bond in a way reminiscent of the reduction of sulfoxides with sodium borohydride in the presence of catalytic amounts of cobalt chloride81. [Pg.1063]

It is very common for inorganic chemists to neglect or ignore the presence of solvent molecules coordinated to a metal centre. In some cases, this is just carelessness, or laziness, as in the description of an aqueous solution of cobalt(ii) nitrate as containing Co ions. Except in very concentrated solutions, the actual solution species is [Co(H20)6] . In other cases, it is not always certain exactly what ligands remain coordinated to the metal ion in solution, or how many solvent molecules become coordinated. Solutions of iron(iii) chloride in water contain a mixture of complex ions containing a variety of chloride, water, hydroxide and oxide ligands. [Pg.13]

See other pages where Coordination of cobalt is mentioned: [Pg.285]    [Pg.84]    [Pg.411]    [Pg.826]    [Pg.395]    [Pg.826]    [Pg.4280]    [Pg.114]    [Pg.285]    [Pg.84]    [Pg.411]    [Pg.826]    [Pg.395]    [Pg.826]    [Pg.4280]    [Pg.114]    [Pg.64]    [Pg.393]    [Pg.170]    [Pg.380]    [Pg.382]    [Pg.531]    [Pg.616]    [Pg.1005]    [Pg.1116]    [Pg.1120]    [Pg.1123]    [Pg.1123]    [Pg.1130]    [Pg.1140]    [Pg.204]    [Pg.230]    [Pg.157]    [Pg.168]    [Pg.186]    [Pg.252]    [Pg.157]    [Pg.54]    [Pg.78]    [Pg.282]    [Pg.283]    [Pg.207]    [Pg.338]    [Pg.342]   
See also in sourсe #XX -- [ Pg.142 , Pg.143 , Pg.144 , Pg.145 , Pg.146 , Pg.147 , Pg.148 , Pg.149 , Pg.150 ]



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Coordination compounds of cobalt

Coordination symmetry of iron and cobalt in staurolite

Experiment 2.3 Analysis of Cobalt Coordination

Procedure 2.3.b Preparation of the Cobalt Coordination

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