Fluoride complexing metal ions

The effects of various fluoride complexing metal ions at 25°C can be roughly estimated from their complex formation constants (15) assuming, as has been concluded (17), that at any given acidity the Pu(>2 dissolution rate is first order with respect to free... 

Complexation of fluoride by metal ions in seawater has previously been overcome by the addition of TISAB solution. The reagent is presumed to release the bound fluoride by preferential complexation of the metal ions with EDTA type ligands present in the TISAB. Examination of the metal ions present in seawater [66,67] suggests that magnesium is the major species forming fluoride complexes. Theoretical calculations demonstrate that even this species is unlikely to interfere. 

The metal-ion complexmg properties of crown ethers are clearly evident m their effects on the solubility and reactivity of ionic compounds m nonpolar media Potassium fluoride (KF) is ionic and practically insoluble m benzene alone but dissolves m it when 18 crown 6 is present This happens because of the electron distribution of 18 crown 6 as shown m Figure 16 2a The electrostatic potential surface consists of essentially two regions an electron rich interior associated with the oxygens and a hydrocarbon like exterior associated with the CH2 groups When KF is added to a solution of 18 crown 6 m benzene potassium ion (K ) interacts with the oxygens of the crown ether to form a Lewis acid Lewis base complex As can be seen m the space filling model of this... 

The basic species in liquid HF is the fluoride ion or the solvated fluoride ion, HF2 . As in the case of water in which OH forms hydroxo complexes, fluoride ion forms complexes in liquid HF. This behavior gives rise to amphoterism with metals ions such as Zn2+ and Al3 +. In the case of Al3+, A1F3 is relatively insoluble in liquid HF so the amphoteric behavior can be shown as follows. 

Finally, impurities (water, certain metal ions, competitive anions) [103] can render [ F]fluoride non-reactive. The metal ions are supposed to complex the carbonate ion and thus reduce the pH which in turn reduces the efficiency of the reaction. Methods to purify the [ F]fluoride anion have been developed (see, e.g. [104]). 

The polymerization of olefins in the presence of halides such as aluminum chloride and boron fluoride but in the absence of hydrogen halide promoter may also be described in terms of the complex carbonium ion formed by addition of the metal halide (without hydrogen chloride or hydrogen fluoride) to the olefin (cf. p. 28). These carbonium ions are apparently more stable than those of the purely hydrocarbon type the reaction resulting in their formation is less readily reversed than is that of the addition of a proton to an olefin (Whitmore, 18). Polymerization in the presence of such a complex catalyst, may be indicated as follows (cf. Hunter and Yohe, 17) ... 

Most commonly, metal ions M2+ and M3+ (M = a first transition series metal), Li+, Na+, Mg2+, Al3+, Ga3+, In3+, Tl3+, and Sn2+ form octahedral six-coordinate complexes. Linear two coordination is associated with univalent ions of the coinage metal (Cu, Ag, Au), as in Ag(NH3)2+ or AuCL Three and five coordination are not frequently encountered, since close-packing considerations tell us that tetrahedral or octahedral complex formation will normally be favored over five coordination, while three coordination requires an extraordinarily small radius ratio (Section 4.5). Coordination numbers higher than six are found among the larger transition metal ions [i.e., those at the left of the second and third transition series, as exemplified by TaFy2- and Mo(CN)g4 ] and in the lanthanides and actinides [e.g., Nd(H20)93+ as well as UC Fs3- which contains the linear uranyl unit 0=U=02+ and five fluoride ligands coordinated around the uranium(VI) in an equatorial plane]. For most of the metal complexes discussed in this book a coordination number of six may be assumed. 

Silver ion also catalyzes nucleophilic reactions of thiol esters, including reactions of acetylhomocysteine thiolactone (12) and diethylethylphosphonothiolate (52). In the first reaction, an insoluble complex of silver ion and the substrate was first produced at pH 7.5, which then reacted with the nucleophile, in this case an amino group of a protein. In the second reaction silver ion complexes of the substrate were also postulated, on the basis that silver ion complexes with sulfur are much more stable than those with oxygen (I). The complexes postulated were 1 1 and 2 1 silver ion-substrate complexes. These complexes were suggested to react with the nucleophiles, water and fluoride ion, giving as products phos-phonic acid and phosphonyl fluoride, respectively, and silver mercaptide. It is evident that the last reaction at least must involve only the direct interaction of a silver ion with the sulfur atom of the thiol ester without chelate formation. Therefore it appears the metal ion-catalyzed reactions of thiol esters are unique, in that they involve complex formation, but not chelate formation in their catalytic mechanism. 

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