Mechanistic and Kinetic Aspects of Transition Metal Oxygen Chemistry

Bakač, Andreja

doi:10.1002/9780470166444.ch3

Cited by 34 publications

(27 citation statements)

References 383 publications

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“…The complex [Cr aq OO] 2 + has been characterized spectroscopically and chemically. [26][27][28] OO] 2 + by metal polypyridine complexes of ruthenium and iron, [29] and will now use these data as a baseline against which the redox behavior of [Cr aq NO] 2 + will be gauged. It is advantageous for our purpose that the ligand system is identical in the nitrosyl and superoxo complexes.…”

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confidence: 99%

Oxidative Homolysis of a Nitrosylchromium Complex

Song

Bakač

2008

Chemistry A European J

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Metal(III)-polypyridine complexes [M(NN)(3)](3+) (M = Ru or Fe; NN = bipyridine (bpy), phenanthroline (phen), or 4,7-dimethylphenanthroline (Me(2)-phen)) oxidize the nitrosylpentaaquachromium(III) ion, [Cr(aq)NO](2+), with an overall 4:1 stoichiometry, 4 [Ru(bpy)(3)](3+) + [Cr(aq)NO](2+) + 2 H(2)O --> 4 [Ru(bpy)(3)](2+) + [Cr(aq)](3+) + NO(3)(-) + 4 H(+). The kinetics follow a mixed second-order rate law, -d[[M(NN)(3)](3+)]/dt = nk[[M(NN)(3)](3+)][[Cr(aq)NO](2+)], in which k represents the rate constant for the initial one-electron transfer step, and n = 2-4 depending on reaction conditions and relative rates of the first and subsequent steps. With [Cr(aq)NO](2+) in excess, the values of nk are 283 M(-1) s(-1) ([Ru(bpy)(3)](3+)), 7.4 ([Ru(Me(2)-phen)(3)](3+)), and 5.8 ([Fe(phen)(3)](3+)). In the proposed mechanism, the one-electron oxidation of [Cr(aq)NO](2+) releases NO, which is further oxidized to nitrite, k = 1.04x10(6) M(-1) s(-1), 6.17x10(4), and 1.12x10(4) with the three respective oxidants. Further oxidation yields the observed nitrate. The kinetics of the first step show a strong correlation with thermodynamic driving force. Parallels were drawn with oxidative homolysis of a superoxochromium(III) ion, [Cr(aq)OO](2+), to gain insight into relative oxidizability of coordinated NO and O(2), and to address the question of the "oxidation state" of coordinated NO in [Cr(aq)NO](2+).

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Oxidative Homolysis of a Nitrosylchromium Complex

Song

Bakač

2008

Chemistry A European J

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“…14,21,31,32 Cobalt analogue of myoglobin, coboglobin, is a functional oxygen carrier. After the formation of the first bond, quite different consecutive steps can occur (Figure 4.6 illustrates possible pathways for iron complexes 17 ; other metals show analogous chemistry, although their exact oxidation states may differ).…”

Section: ð4:6þmentioning

confidence: 99%

“…The 2 : 1 stoichiometry of the Fe(TMC) 2 þ /O 2 reaction suggests a bimolecular mechanism with the intermediacy of diiron(III)-peroxo species, analogous to the mechanism of O-O bond cleavage by iron(II) porphyrins (see above). 14,15 For comparison, TiO 2 þ and VO 2 þ , which can be obtained from Ti(II) and V(II), respectively, do not display oxidizing properties; Mn IV ¼O and especially Mn V ¼O compounds are potent oxidants, but their plausible Mn(II) precursors are unreactive with O 2 (unless the metal is bound to strongly electrondonating ligands, such as corroles 64 ). Even though most other transition metals are not found in oxygen-activating enzymes, they can participate in similar reaction pathways and support similar intermediates in their reactions with dioxygen or oxygen atom donors.…”

Section: Formation Of Metal-oxo Complexesmentioning

confidence: 99%

“…The literature on oxygen activation is extensive, including books, [5][6][7][8][9] chapters, 2,10 journal special issues, [11][12][13] review articles, [14][15][16] and numerous primary publications; only a handful of representative references are cited above. A comprehensive review of this active area of research is nearly impossible, and definitely beyond the scope of this work.…”

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Mechanisms of Oxygen Binding and Activation at Transition Metal Centers

Rybak‐Akimova

2010

Physical Inorganic Chemistry

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“…Therefore, clean, inexpensive oxidants such as molecular oxygen or hydrogen peroxide have increasingly been adopted in alternative routes. However, the addition of dioxygen to hydrocarbons generally requires high activation energies due to the high energy needed to break the O-O double bond and the spin mismatch between the ground state of O 2 (triplet) and organic reductants (singlet) [3][4][5]. This greatly enhances the potential of hydrogen peroxide, especially at low concentrations as an oxidant.…”

Section: Introductionmentioning

confidence: 99%

Solvent-free oxidation of alcohols by hydrogen peroxide over chromium Schiff base complexes immobilized on MCM-41

Wang

Wei

et al. 2009

Transition Met Chem

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A series of chromium(III) Schiff base complexes immobilized on MCM-41 were prepared and characterized by various physicochemical and spectroscopic methods. The complexes were used for the selective oxidation of alcohols by 30% hydrogen peroxide without any organic solvent, phase transfer catalyst or additive. The immobilized complexes proved to be effective catalysts and generally exhibited much higher catalytic performance than their corresponding homogeneous analogs. The catalytic performance of the immobilized complexes was also found to be closely related to the Schiff base ligands used. Under the optimal reaction conditions, secondary alcohols, cyclic alcohols and benzyl alcohol were prevailingly oxidized to their corresponding ketones or aldehydes.

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Mechanistic and Kinetic Aspects of Transition Metal Oxygen Chemistry

Cited by 34 publications

References 383 publications

Oxidative Homolysis of a Nitrosylchromium Complex

Oxidative Homolysis of a Nitrosylchromium Complex

Mechanisms of Oxygen Binding and Activation at Transition Metal Centers

Solvent-free oxidation of alcohols by hydrogen peroxide over chromium Schiff base complexes immobilized on MCM-41

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