Electronic delocalized mixed valence ions

Creutz-Taube ion [bis(pentaammine-ruthenium)pyrazine]D (30) provides an example of this. There is good reason to suppose (in spite of many earlier arguments to the contrary) that this is a fully delocalized mixed-valence system (27). In symmetry, the one-electron levels separated by energy gap 2J are calculated to have b u (bonding) and b (antibonding) symmetry,... 

Cua centers exist in two redox states [Cu(II)Cu(I)] and [Cu(I)Cu(I)]. The oxidized species is a fully delocalized mixed-valence pair (formally two Cu+ 1.5 ions), as revealed by EPR spectroscopy (Kroneck et al., 1988, 1990). Despite the similar coordination geometry around copper, these systems display sharper NMR lines than do the BCP due to a shorter electron relaxation time of the paramagnetic center (wlO "s) (dementi and Luchinat, 1998). NMR studies are available for the native Cua centers from the soluble fragments of the The. thermophilus, Paracoc-cus denitrificans, Paracoccus versutus, and Bacillus subtilis oxidases (Bertini et al., 1996 Dennison et al., 1995 Luchinat et al., 1997 Salgado et al., 1998a) and Pseudomonas stutzeri N2O reductase (Holz et al., 1999), as well as for engineered Cua sites in amicyanin (Dennison et al., 1997) and Escherichia coli quinol oxidase (Kolczak et al., 1999). 

Related spectra for the oxalate and terephthalate bridged Mo4-containing compounds supported by pivalate ligands are shown in Fig. 9. Here it is clearly evident that on the EPR time scale, 10 s , the oxalate cation involves complete delocalization of the positive charge over all four Mo atoms. The single electron in the HOMO sees equally all four Mo atoms. Here the presence of two spin active nuclei in the M center is more easily seen. In contrast, the EPR spectmm of the terephthalate radical cation is localized on one M02 center the mixed-valence ion is valence-trapped [34]. 

In the thermodynamically redox-stable resting state, CcOs all Cu ions are in the Cu state and all hemes are Fe . From this state, CcOs can be reduced by one to four electrons. One-electron reduced CcOs are aerobically stable with the electron delocalized over the Cua and heme a sites. The more reduced forms—mixed-valence (two-electron reduced), three-electron reduced, and fully (four-electron) reduced—bind O2 rapidly and reduce it to the redox level of oxide (—2 oxidation state) within <200 p-s [Wikstrom, 2004 Michel, 1999]. This rate is up to 100 times faster than the average rate of electron transfer through the mammalian respiratory chain under normal... 

These results suggest that the critical factor in the substrate-mediated intermolecular interactions which occur within the close-packed DHT layer is the inherent strong reactivity of the diphenolic moiety with the Pt surface. The interaction of adsorbates with each other through the mediation of the substrate is of fundamental importance in surface science. The theoretical treatment, however, involves complicated many-body potentials which are presently not well-understood (2.). It is instructive to view the present case of Pt-substrate-mediated DHT-DHT interactions in terms of mixed-valence metal complexes (2A) For example, in the binuclear mixed-valence complex, (NH3)5RU(11)-bpy-Ru(111) (NH 3)5 (where bpy is 4,4 -bipyridine), the two metal centers are still able to interact with each other via the delocalized electrons within the bpy ligand. The interaction between the Ru(II) and Ru(III) ions in this mixed-valence complex is therefore ligand-mediated. The Ru(II)-Ru(III) coupling can be written schematically as ... 

In any mixed-valence compound, the first problem to be addressed is one of description. Is the compound localized or "delocalized In a localized description the stationary state quantum mechanical solution for the odd electron is oscillatory in nature and has the electron transferring back and forth between the metal ion sites. Spectroscopic data are available for... 

Over the past 10-15 years, several model systems that maintain the copper ion mixed-valence, delocalized electronic state with short Cu-Cu bond distances as in the CcO enzyme—Cu -Cu Cu -Cu =Cu Cu - —have been... 

A condition where metal ions within a coordination complex or cluster are present in more than one oxidation state. In such systems, there is often complete delocalization of the valence electrons over the entire complex or cluster, and this is thought to facilitate electron-transfer reactions. Mixed valency has been observed in iron-sulfur proteins. Other terms for this behavior include mixed oxidation state and nonintegral oxidation state. 

This cluster formally contains three iron(III) and one iron(E). It is present in a class of proteins called high potential iron-sulfur proteins (HiPIP). It has also been prepared through oxidation of [(RS)4Fe4S4]2 model compounds [57]. Both in the model compound at low temperatures and in proteins there is electron delocalization on one mixed valence pair [58-62]. Therefore, the polymetallic center is constituted by two iron ions at the oxidation state +2.5 and two iron ions at the oxidation state +3. Hamiltonian (6.20), or a more complicated one [40, 41,43], can be used to describe the electronic structure. Indeed, a delocalization operator is sometimes needed in the Hamiltonian [40,41,43]. Consistently with magnetic Mossbauer data the S M subspin involving the mixed valence pair is 9/2, whereas the S n subspin involving the iron(IH) ions is 4. Mossbauer and EPR data do not exclude % and 3, respectively, for the two pairs [57] in any case, the... 

In most instances, the magnetic structure of a compound can be understood to be based on interacting localized spin centers, such as classical 3d/4d/5d transition metal ions and 4f lanthanide or 5f actinide cations with unpaired electrons. Note that while the assumption of localized moments is valid for many compounds comprising such spin centers, even partial electron delocalization in mixed-valence coordination compounds renders many localized spin models inapplicable. 

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