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Trivalent cation transition

The site preference of several transition-metal ions is discussed in References 4 and 24. The occupation of the sites is usually denoted by placing the cations on B-sites in stmcture formulas between brackets. There are three types of spinels normal spinels where the A-sites have all divalent cations and the B-sites all trivalent cations, eg, Zn-ferrite, [Fe ]04j inverse spinels where all the divalent cations are in B-sites and trivalent ions are distributed over A- and B-sites, eg, Ni-ferrite, Fe Fe ]04 and mixed spinels where both divalent and trivalent cations are distributed over both types of sites,... [Pg.188]

The rare earth (RE) ions most commonly used for applications as phosphors, lasers, and amplifiers are the so-called lanthanide ions. Lanthanide ions are formed by ionization of a nnmber of atoms located in periodic table after lanthanum from the cerium atom (atomic number 58), which has an onter electronic configuration 5s 5p 5d 4f 6s, to the ytterbium atom (atomic number 70), with an outer electronic configuration 5s 5p 4f " 6s. These atoms are nsnally incorporated in crystals as divalent or trivalent cations. In trivalent ions 5d, 6s, and some 4f electrons are removed and so (RE) + ions deal with transitions between electronic energy sublevels of the 4f" electroiuc configuration. Divalent lanthanide ions contain one more f electron (for instance, the Eu + ion has the same electronic configuration as the Gd + ion, the next element in the periodic table) but, at variance with trivalent ions, they tand use to show f d interconfigurational optical transitions. This aspect leads to quite different spectroscopic properties between divalent and trivalent ions, and so we will discuss them separately. [Pg.200]

A large number of bivalent and trivalent cations were utilized as catalysts in this reaction. The effectiveness of the cation as a catalyst strictly paralleled its power of forming a complex with the malonate ion, a model for the transition state of the reaction. This parallelism strikingly shows that the ability of a metal ion to catalyze this process depends on its ability to complex with the transition state. [Pg.25]

Values of A0 are generally higher for trivalent cations than for corresponding divalent ions. This is demonstrated by the data summarized in table 2.5 for divalent and trivalent transition metal ions in simple oxide structures and in hydrated environments. For example, A0 values for Fe2+ and Fe3+ ions in aqueous solution are 10,400 cm-1 and 13,700 cm-1, respectively. [Pg.27]

One property of a transition metal ion that is particularly sensitive to crystal field interactions is the ionic radius and its influence on interatomic distances in a crystal structure. Within a row of elements in the periodic table in which cations possess completely filled or efficiently screened inner orbitals, there should be a decrease of interatomic distances with increasing atomic number for cations possessing the same valence. The ionic radii of trivalent cations of the lanthanide series for example, plotted in fig. 6.1, show a relatively smooth contraction from lanthanum to lutecium. Such a trend is determined by the... [Pg.240]

Figure 6.2 Octahedral ionic radii of first-series transition metal cations, (a) Divalent cations (b) trivalent cations. Filled circles high-spin cations open squares low-spin cations (data from Shannon, 1976). Figure 6.2 Octahedral ionic radii of first-series transition metal cations, (a) Divalent cations (b) trivalent cations. Filled circles high-spin cations open squares low-spin cations (data from Shannon, 1976).
Measurements of absorption spectra of oxides, glasses and hydrates of transition metal ions have enabled crystal field stabilization energies (CFSE s) in tetrahedral and octahedral coordinations to be estimated in oxide structures (see table 2.5). The difference between the octahedral and tetrahedral CFSE is called the octahedral site preference energy (OSPE), and values are summarized in table 6.3. The OSPE s may be regarded as a measure of the affinity of a transition metal ion for an octahedral coordination site in an oxide structure such as spinel. Trivalent cations with high OSPE s are predicted to occupy octahedral sites in spinels and to form normal spinels. Thus, Cr3, Mn3, V3+... [Pg.248]

Crystal field spectral measurements of transition metal ions doped in a variety of silicate glass compositions (e.g., Fox et al., 1982 Nelson et al., 1983 Nelson and White, 1986 Calas and Petiau, 1983 Keppler, 1992) have produced estimates of the crystal field splitting and stabilization energy parameters for several of the transition metal ions, examples of which are summarized in table 8.1. Comparisons with CFSE data for each transition metal ion in octahedral sites in periclase, MgO (divalent cations) and corundum, A1203 (trivalent cations) and hydrated complexes show that CFSE differences between crystal and glass (e.g., basaltic melt) structures,... [Pg.315]

The [a-SiW9034] polyanion is a useful species for synthesizing the adduct complexes [SiW,M3040]" , especially with M = Mo ", V, and di-or trivalent cations of the first transition series. [Pg.87]

This lacunary polyanion is used to synthetize adduct complexes [y-SiWioM204o]" , especially with V, Mo, W, and di- or trivalent cations of the Arst transition series. [Pg.89]

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Cations trivalent

Transition cations

Trivalent

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