Andrew W. Zanella scite author profile

Described are studies directed toward elucidating the controversial chemistry relating to the solution phase reactions of nitric oxide with the iron(II) porphyrin complex Fe(TPP)(NO) (1, TPP = meso-tetraphenylporphinato2-). The only reaction observable with clean NO is the formation of the diamagnetic dinitrosyl species Fe(TPP)(NO)2 (2), and this is seen only at low temperatures (K(1) < 3 M(-1) at ambient temperature). However, 1 does readily react reversibly with N2O3 in the presence of excess NO to give the nitro nitrosyl complex Fe(TPP)(NO2)(NO) (3), suggesting that previous claims that 1 promotes NO disproportionation to give 3 may have been compromised by traces of air in the nitric oxide sources. It is also noted that 3 undergoes reversible loss of NO to give the elusive nitro species Fe(TPP)(NO2) (4), which has been implicated as a powerful oxygen atom transfer agent in reactions with various substrates. Furthermore, in the presence of excess NO2, the latter undergoes oxidation to the stable nitrato analogue Fe(TPP)(NO3) (5). Owing to such reactivity of Fe(TPP)(NO2), flash photolysis and stopped-flow kinetics rather than static techniques were necessary for the accurate measurement of dissociation equilibria characteristic of Fe(TPP)(NO2)(NO) in 298 K toluene solution. Flash photolysis of 3 resulted in competitive NO2 and NO dissociation to give Fe(TPP)(NO) and Fe(TPP)(NO2), respectively. The rate constant for the reaction of 1 with N2O3 to generate Fe(TPP)(NO2)(NO) was determined to be 1.8 x 10(6) M(-1) s(-1), and that for the NO reaction with 4 was similarly determined to be 4.2 x 10(5) M(-1) s(-1). Stopped-flow rapid dilution techniques were used to determine the rate constant for NO dissociation from 3 as 2.6 s(-1). The rapid dilution experiments also demonstrated that Fe(TPP)(NO2) readily undergoes further oxidation to give Fe(TPP)(NO3). The mechanistic implications of these observations are discussed, and it is suggested that NO2 liberated spontaneously from Fe(P)(NO2) may play a role in an important oxidative process involving this elusive species.

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Outer-sphere electron-transfer reactions involving caged cobalt ions

Creaser¹,

Sargeson²,

Zanella³

1983

Inorg. Chem.

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Ground- and excited-state electron-transfer reactions: photoinduced redox reactions of poly(pyridine)ruthenium(II) complexes and cobalt(III) cage compounds

Mok¹,

Zanella²,

Creutz³

et al. 1984

Inorg. Chem.

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our study, only the very weak perchlorate ligand is available for coordination and products are relatively unstable. ConclusionsThe lability of mercury dithiocarbamate complexes exerts considerable influence in the mass spectrometry, NMR, and electrochemical experiments. In mass spectrometry and NMR spectrometry, rapid dimer formation appears to be responsible for the observation of exchange process. The lability of the mercury(II) complexes and their rapid interactions with elemental mercury and mercury(I) together with dimer formation also influences the nature of electrode process occurring at mercury electrodes.Acknowledgment. Financial assistance from the Australian Research Grants Scheme is gratefully acknowledged as is technical assistance in the area of mass spectrometry from G. R. Franklin and discussion on the electrochemistry with K.

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Andrew W. Zanella

Base hydrolysis of coordinated organonitriles. Reactons of ruthenium(III) and rhodium(III) complexes

Reactions of Nitrogen Oxides with Heme Models. Characterization of NO and NO₂ Dissociation from Fe(TPP)(NO₂)(NO) by Flash Photolysis and Rapid Dilution Techniques: Fe(TPP)(NO₂) as an Unstable Intermediate

Outer-sphere electron-transfer reactions involving caged cobalt ions

Ground- and excited-state electron-transfer reactions: photoinduced redox reactions of poly(pyridine)ruthenium(II) complexes and cobalt(III) cage compounds

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Andrew W. Zanella

Base hydrolysis of coordinated organonitriles. Reactons of ruthenium(III) and rhodium(III) complexes

Reactions of Nitrogen Oxides with Heme Models. Characterization of NO and NO2 Dissociation from Fe(TPP)(NO2)(NO) by Flash Photolysis and Rapid Dilution Techniques: Fe(TPP)(NO2) as an Unstable Intermediate

Outer-sphere electron-transfer reactions involving caged cobalt ions

Ground- and excited-state electron-transfer reactions: photoinduced redox reactions of poly(pyridine)ruthenium(II) complexes and cobalt(III) cage compounds

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Product

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Reactions of Nitrogen Oxides with Heme Models. Characterization of NO and NO₂ Dissociation from Fe(TPP)(NO₂)(NO) by Flash Photolysis and Rapid Dilution Techniques: Fe(TPP)(NO₂) as an Unstable Intermediate