Arani Chanda scite author profile

Iron(V)-oxo species have been proposed as key reactive intermediates in the catalysis of oxygen-activating enzymes and synthetic catalysts. Here, we report the synthesis of [Fe(TAML)(O)]- in nearly quantitative yield, where TAML is a macrocyclic tetraamide ligand. Mass spectrometry, Mössbauer, electron paramagnetic resonance, and x-ray absorption spectroscopies, as well as reactivity studies and density functional theory calculations show that this long-lived (hours at -60 degrees C) intermediate is a spin S = 1/2 iron(V)-oxo complex. Iron-TAML systems have proven to be efficient catalysts in the decomposition of numerous pollutants by hydrogen peroxide, and the species we characterized is a likely reactive intermediate in these reactions.

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Catalase−Peroxidase Activity of Iron(III)−TAML Activators of Hydrogen Peroxide

Ghosh

et al. 2008

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Exceptionally high peroxidase-like and catalase-like activities of iron(III)-TAML activators of H 2O 2 ( 1: Tetra-Amidato-Macrocyclic-Ligand Fe (III) complexes [ F e{1,2-X 2C 6H 2-4,5-( NCOCMe 2 NCO) 2CR 2}(OH 2)] (-)) are reported from pH 6-12.4 and 25-45 degrees C. Oxidation of the cyclometalated 2-phenylpyridine organometallic complex, [Ru (II)( o-C 6H 4py)(phen) 2]PF 6 ( 2) or "ruthenium dye", occurs via the equation [ Ru II ] + 1/2 H 2 O 2 + H +-->(Fe III - TAML) [ Ru III ] + H 2 O, following a simple rate law rate = k obs (per)[ 1][H 2O 2], that is, the rate is independent of the concentration of 2 at all pHs and temperatures studied. The kinetics of the catalase-like activity (H 2 O 2 -->(Fe III - TAML) H 2 O + 1/2 O 2) obeys a similar rate law: rate = k obs (cat)[ 1][H 2O 2]). The rate constants, k obs (per) and k obs (cat), are strongly and similarly pH dependent, with a maximum around pH 10. Both bell-shaped pH profiles are quantitatively accounted for in terms of a common mechanism based on the known speciation of 1 and H 2O 2 in this pH range. Complexes 1 exist as axial diaqua species [FeL(H 2O) 2] (-) ( 1 aqua) which are deprotonated to afford [FeL(OH)(H 2O)] (2-) ( 1 OH) at pH 9-10. The pathways 1 aqua + H 2O 2 ( k 1), 1 OH + H 2O 2 ( k 2), and 1 OH + HO 2 (-) ( k 4) afford one or more oxidized Fe-TAML species that further rapidly oxidize the dye (peroxidase-like activity) or a second H 2O 2 molecule (catalase-like activity). This mechanism is supported by the observations that (i) the catalase-like activity of 1 is controllably retarded by addition of reducing agents into solution and (ii) second order kinetics in H 2O 2 has been observed when the rate of O 2 evolution was monitored in the presence of added reducing agents. The performances of the 1 complexes in catalyzing H 2O 2 oxidations are shown to compare favorably with the peroxidases further establishing Fe (III)-TAML activators as miniaturized enzyme replicas with the potential to greatly expand the technological utility of hydrogen peroxide.

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Fe^III–TAML-catalyzed green oxidative degradation of the azodyeOrange II by H₂O₂and organic peroxides: products, toxicity, kinetics, and mechanisms

et al. 2007

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Oxidation of Orange II ([4-[(2-hydroxynaphtyl)azo]benzenesulfonic acid], sodium salt) by hydrogen peroxide catalyzed by iron(III) complexed to tetra amido macrocyclic ligands (Fe III -TAML activators) in aqueous solutions at pH 9-11 leads to CO 2 , CO, phthalic acid and smaller aliphatic carboxylic acids as major mineralization products. The products are non-toxic according to the Daphnia magna test. Several organic intermediates have been identified by HPLC and GC-MS that allowed the detailed description of Orange II degradation. The catalytic oxidation can also be performed by organic oxidants such as benzoyl peroxide, tert-butyl and cumyl hydroperoxides. Kinetic studies of the catalyzed oxidation indicated that Fe III -TAML activators react first with ROOR9 to form an oxidized catalyst (k I ), which then oxidizes Orange II (k II ). Neglecting the reversibility of the first step, the rate equation is rate [Dye]); here Fe III and ROOR9 represent the catalyst and peroxide, respectively. The rate constant k I equals (74 ¡ 3) 6 10 3 , (1.4 ¡ 0.1) 6 10 3 , 24 ¡ 2, and 11 ¡ 1 M 21 s 21 for benzoyl peroxide, H 2 O 2 , t-BuOOH, and cumyl hydroperoxide at pH 9 and 25 uC, respectively. An average value of k II equals (3.1 ¡ 0.9) 6 10 4 M 21 s 21 under the same conditions. The unraveling of the kinetic mechanism allows the comprehension of the robust reactivity, and this is discussed in detail using the representative results of DFT calculations.

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Arani Chanda

Organic Synthesis “On Water”

Chemical and Spectroscopic Evidence for an Fe ^V -Oxo Complex

Catalase−Peroxidase Activity of Iron(III)−TAML Activators of Hydrogen Peroxide

Fe^III–TAML-catalyzed green oxidative degradation of the azodyeOrange II by H₂O₂and organic peroxides: products, toxicity, kinetics, and mechanisms

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Resources

About

Arani Chanda

Organic Synthesis “On Water”

Chemical and Spectroscopic Evidence for an Fe V -Oxo Complex

Catalase−Peroxidase Activity of Iron(III)−TAML Activators of Hydrogen Peroxide

FeIII–TAML-catalyzed green oxidative degradation of the azodyeOrange II by H2O2and organic peroxides: products, toxicity, kinetics, and mechanisms

Contact Info

Product

Resources

About

Chemical and Spectroscopic Evidence for an Fe ^V -Oxo Complex

Fe^III–TAML-catalyzed green oxidative degradation of the azodyeOrange II by H₂O₂and organic peroxides: products, toxicity, kinetics, and mechanisms