Mark H. Barley

Mechanism of reduction of bound nitrite to ammonia

Electrochemical experiments on the oxidation of the complexes (I) and reduction of the complexes (II) have given insight into the mechanistic details of how bound nitrite is converted into ammonia.

Picosecond flash photolysis of carbonyl complexes of ruthenium(II) porphyrin .pi. cation radicals

With picosecond transient absorption techniques we have investigated photolysis of the Ru(lI) octaethylporphyrin 1r cation radicals Ru(OEP+·)CO(L): L = EtOH (4a). py (4b). 1m (4c). Br- (4d). Excitation with 35-ps flashes at 532 nm results in the formation and decay of transient states having lifetimes less than the flash duration. The transient lifetimes for 2A!u ground-state 1r cation radicals are shorter than those observed after excitation of species with the 2A 2u ground state. The transient behavior is rationalized in terms of both release of CO followed by rapid geminate recombination and of rapid radiationless decay via nondissociative states. The latter process seems more likely, but the former cannot be ruled out. Low-lying (d. 1r) charge-transfer states of the 1r cation radicals might provide effective routes for deactivation. Photolysis with 355-nm flashes results in the formation of similar short-lived transients. However. in the case of 4a and 4b. having mainly the 2A 2u ground state. a longer-lived photo product is observed. This new transient could be the carbonyl-free 1r cation radical. but it is more likely the Ru(lIl) species obtained upon release of the CO followed by internal electron transfer from metal to ring. The quantum yield of the long-lived photoproduct appears to be low «25%). Decarbonylation with 355-nm pump pulses is ascribed to the population of a dissociative state. such as (d .... dz2). not accessible with the lower energy 532-nm excitation flashes. Apparently. rapid deactivation to the ground state competes favorably with ligand release even in these cases. The behavior is discussed in terms of the electronic states of the ring. metal, and ligands. The relevance of these findings to the release of ligands by hemoglobin and myoglobin as well as by other transition metal porphyrin complexes is considered.

Reversible intramolecular electron transfer within a ruthenium(III) porphyrin-ruthenium(II) porphyrin π-cation radical system induced by changes in axial ligation

Reaction of the octaethylporphyrinatobis(triphenylarsine)ruthenium(III) cation with CO generates the carbonyl(triphenylarsine)ruthenium(II) porphyrin π-cation radical species viaan intramolecular electron transfer; the process is quantitatively reversible.

The design of a thin layer, infrared-transparent electrochemical cell and its use in the study of cluster species

Abstract The design of a thin layer, infrared-transparent electrochemical cell is described, and its application to the study of the IR spectra of some air sensitive reduced cluster species is demonstrated.

Redox chemistry of ruthenium porphyrins: evidence for internal electron transfer and the characterization of [RuIII(OEP+˙)] species

An internal electron transfer process from ruthenium(II) to an octaethylporphyrin radical moiety is induced by changes in axial ligation, and the species formed by a two-electron oxidation of ruthenium(II) porphyrins is characterized as a ruthenium(III) porphyrin cation radical.

The novel electrochemistry of the decaosmium cluster [Os10C(CO)24]2–

Electrochemical studies of [Os10C(CO)24]2– have allowed five oxidation states to be characterized; the two-electron reduction of [Os10C(CO)24]2– has been resolved at –50 °C into a reversible process followed by an irreversible wave associated with a structural change.