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Eigen-Wilkins mechanism

These general comments regarding iron sequestration kinetics can be placed in the context of the Eigen-Wilkins mechanism for complexation (135). Initial complex formation proceeds by way of the formation of an encounter complex, Fe(H20)g+ L,... [Pg.221]

Several comprehensive texts [164-166] and papers [167-170] have been published on complexation reaction kinetics in aqueous, including environmental, solutions. In this section, we shall briefly examine the Eigen-Wilkins mechanism as a starting point for estimating the rates of metal complexation reactions in environmental aqueous systems (Sections 4.3.2-4.3.3) and as a basis for the definition of the lability criteria (Section 7.2). [Pg.469]

In the case of trace metals, adsorption is typically much faster than the time intervals for which it is practically possible to separate the cells. Therefore, in practice, values of kf and kr are most often estimated by assuming that water loss from the hydrated cation is rate-limiting (Eigen-Wilkins mechanism, see Section 4.3.1 above). In some cases, uptake transients can be observed at the start of a short-term uptake experiment or by using pulse-chase experiments for which a metal solution containing a radioactive tracer is replaced by a solution... [Pg.475]

Eigen-Wilkins mechanism, 42 5 Einsteinium, 20 111 melting point, 31 6... [Pg.88]

The formation of copper(II) complexes with terpy has been investigated fairly intensively. The interaction is pH dependent, and numerous hydroxy, aqua, and polynuclear species are present in aqueous solution 94, 245,278). In general, an Eigen-Wilkins mechanism appears to be operative, although the kinetics are complicated by ligand-protonation equilibria 263,390,391). In acidic solution, 1 1 complexes predominate (567). A number of substituted terpyridine ligands have been evaluated as potential colorimetric reagents for copper 400). The adsorption behavior of copper(II)-terpy complexes at silica surfaces has been studied 499). Such complexes are reasonably active as catalysts for the hydrolysis of fluorophosphate esters 456). [Pg.98]

S213 As discussed in Section 21.6, the Eigen-Wilkins mechanism for substitution in octahedral complexes suggests the formation of an encounter complex [V(H20)6] Cl , in the first, fast step ... [Pg.193]

The second-order term in the rate laws for reactions of low-spin iron(II) diimine complexes with such nucleophiles as hydroxide and cyanide ions has been established as arising from a bimolecular reaction between complex and nucleophile.182 Activation volumes that were obtained for reactions of CN and OH with Fc(phcn)2 1 and Fe(bpy)3 + were in the range of +19.7 to +21.5cm3mol-1.183 Because these observations were not readily accounted for by an associative mechanism, a mechanism analogous to the Eigen-Wilkins mechanism of complex formation was introduced in which dissociative activation dominates in determining the observed activation volumes. However, subsequently it was shown that solvation... [Pg.29]

These apparent contradictions are explained by the Eigen-Wilkins mechanism. [Pg.772]

The Eigen- Wilkins mechanism applies to ligand substitution in an octahedral complex. An encounter complex is first formed between substrate and entering ligand in a preequilibrium step, and this is followed by loss of the leaving ligand in the rate-determining step. [Pg.772]

Consider reaction 25.22. The first step in the Eigen-Wilkins mechanism is the diffusing together of MLg and Y to form a weakly bound encounter complex (equilibrium 25.23). [Pg.772]

Positive AK suggests dissociative D or Zj) the rate law suggests associative mechanism apply Eigen-Wilkins mechanism to account for apparent second order kinetics. [Pg.902]

Usually, the rate of formation of ML5,Y and the back-reaction to MLg and Y are much faster than the subsequent conversion of MLg,Y to products. Thus, the formation of MLg,Y is a pre-equilibrium. The equilibrium constant, K, can rarely be determined experimentally, but it can be estimated using theoretical models. The rate-determining step in the Eigen Wilkins mechanism is step 26.27 with a rate constant k. The overall rate law is equation 26.28. [Pg.890]

Metal Complex Formation - The Eigen-Wilkins Mechanism [10, 19,29]... [Pg.22]

A r-jump and stopped-flow study of the rapid anation of a five-co-ordinate copper(ii) aqua-complex by azide and thiocyanate has its main interest as a model system for the active site of a metalloenzyme. The kinetics conform to the Eigen-Wilkins mechanism (rate-determining water release, /d). ... [Pg.160]

NickeI(II) (rf ).— The mechanism of complex formation for some metal(ii) cations is now so well established, at least for simple ligands, that such reactions, particularly of nickel(n), are used to probe solvent and salt effects on kinetic patterns. Many of these studies are therefore dealt with in the Chapter on medium effects (Part II, Chapter 13). They include the reactions of nickel(n) and of magnes-ium(n) with chloride in aqueous alcohols, of nickel(ii) with imidazole in aqueous ethanol, with malonate in fructose-water solutions, with thiocyanate in methanol-DMSO mixtures, and with murexide or pada in various micellar media, and of several metal(n) cations with fluoride in aqueous salt solutions." In general, medium effects on observed rate constants (lit) for complex formation operate on the pre-association step (/fos) rather than on the interchange process (A i). The Eigen-Wilkins mechanism operates in all these media it has also been shown to operate for the bidentate ligand Etgdtc in DMSO, and even at the surface of a mercury electrode. ... [Pg.209]


See other pages where Eigen-Wilkins mechanism is mentioned: [Pg.8]    [Pg.10]    [Pg.37]    [Pg.309]    [Pg.84]    [Pg.96]    [Pg.27]    [Pg.539]    [Pg.17]    [Pg.772]    [Pg.773]    [Pg.782]    [Pg.324]    [Pg.210]    [Pg.214]    [Pg.776]    [Pg.889]    [Pg.901]    [Pg.57]    [Pg.208]    [Pg.210]    [Pg.232]    [Pg.292]    [Pg.297]    [Pg.95]   
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