Tyrosinase is a copper monooxygenase that catalyzes oxygenation of phenols to catechols (phenolase activity) and the subsequent two-electron oxidation of catechols to the corresponding o-quinones (catecholase activity). 1 Chemical and spectroscopic studies have indicated that the enzyme has a dinuclear copper active site nearly identical to that found in hemocyanin, 1,2 where a side-on type (µ-η 2 :η 2 ) peroxo species 3 is generated by the reaction of the reduced dicopper(I) form and O 2 . 1 As a pioneering work by Karlin and co-workers in Cu/O 2 chemistry, aromatic ligand hydroxylation in a dinuclear Cu(I) complex by O 2 was first reported in early 1980s. 4 The mechanistic studies have indicated that the aromatic ligand hydroxylation reaction involves an electrophilic attack on the arene ring by a (µ-η 2 :η 2 -peroxo)-dicopper(II) intermediate. 5 After their finding, several examples of the aromatic ligand hydroxylation have been reported using similar type of m-xylyl dinucleating ligands. 6 With respect to the intermolecular reactions between phenols and the peroxo intermediate, however, most of the reactions so far reported afford a C-C coupling dimer as a major product. 7 Casella and co-workers have recently reported the first synthetic (µ-η 2 :η 2 -peroxo)dicopper-(II) complex which can react with an exogenous phenolate to yield the corresponding catechol. 8,9 Unfortunately, the low yield of the product (20% based on the dicopper complex) has precluded the kinetic and mechanistic investigation on the reaction between the peroxo intermediate and the phenolate. 8 As such, the mechanism for the catechol formation via intermolecular reactions between the peroxo intermediate and phenol derivatives has yet to be clarified. 10 We report herein that efficient conversion of phenol derivatives to the corresponding catechols is achieved for the first time by intermolecular reactions of a (µ-η 2 :η 2 -peroxo)dicopper(II) complex, supported by tridentate ligand L Py2Bz (N,N-bis[2-(2-pyridyl)-ethyl]-R,R-dideuteriobenzylamine), 11 with lithium salts of phenols. The mechanistic studies on the catechol formation have been performed to provide valuable mechanistic insight into the phenolase activity of the enzyme.Treatment of the copper(I) complex, [Cu I (L Py2Bz )](PF 6 ), with dioxygen in anhydrous acetone at -94°C afforded a brown color solution which exhibited a strong absorption band at 364 nm ( ) 26400 M -1 cm -1 ) together with a small one at 530 nm (1500 M -1 cm -1 ) and a resonance Raman band at 737 cm -1 that shifted to 697 cm -1 upon 18 O-substitution. 12,13 The frozen acetone solution of the intermediate was ESR silent at 77 K, and a Cu:O 2 ) 2:1 stoichiometry was obtained for formation of the intermediate by manometry. These results unambiguously indicate that the oxygenated intermediate is a (µ-η 2 :η 2 -peroxo)dicopper(II) complex as suggested previously by Karlin et al. 11 This compound is quite stable (no self-decomposition) at the low-temperature enabling us to examine the reaction with external subst...
Phenolate and phenoxyl radical complexes of a series of alkaline earth metal ions as well as monovalent cations such as Na+ and K+ have been prepared by using 2,4-di-tert-butyl-6-(1,4,7,10-tetraoxa-13-aza-cyclopentadec-13-ylmethyl)phenol (L1H) and 2,4-di-tert-butyl-6-(1,4,7,10,13-pentaoxa-16-aza-cyclooctadec-16-ylmethyl)phenol (L2H) to examine the effects of the cations on the structure, physicochemical properties and redox reactivity of the phenolate and phenoxyl radical complexes. Crystal structures of the Mg2+- and Ca2+-complexes of L1- as well as the Ca2+- and Sr2+-complexes of L2- were determined by X-ray crystallographic analysis, showing that the crown ether rings in the Ca2+-complexes are significantly distorted from planarity, whereas those in the Mg2+- and Sr2+-complexes are fairly flat. The spectral features (UV-vis) as well as the redox potentials of the phenolate complexes are also influenced by the metal ions, depending on the Lewis acidity of the metal ions. The phenoxyl radical complexes are successfully generated in situ by the oxidation of the phenolate complexes with (NH4)(2)[Ce4+(NO3)6] (CAN). They exhibited strong absorption bands around 400 nm together with a broad one around 600-900 nm, the latter of which is also affected by the metal ions. The phenoxyl radical-metal complexes are characterized by resonance Raman, ESI-MS, and ESR spectra, and the metal ion effects on those spectroscopic features are also discussed. Stability and reactivity of the phenoxyl radical-metal complexes are significantly different, depending on the type of metal ions. The disproportionation of the phenoxyl radicals is significantly retarded by the electronic repulsion between the metal cation and a generated organic cation (Ln+), leading to stabilization of the radicals. On the other hand, divalent cations decelerate the rate of hydrogen atom abstraction from 10-methyl-9,10-dihydroacridine (AcrH2) and its 9-substituted derivatives (AcrHR) by the phenoxyl radicals. On the basis of primary kinetic deuterium isotope effects and energetic consideration of the electron-transfer step from AcrH2 to the phenoxyl radical-metal complexes, we propose that the hydrogen atom abstraction by the phenoxyl radical-alkaline earth metal complexes proceeds via electron transfer followed by proton transfer.
Physicochemical properties of the Cu(II)− and Zn(II)−phenoxyl radical complexes of ligand 1H and its 2,4-di-tert-butyl derivative 2H have been examined as models for the active form of galactose oxidase to shed light on the role of the thioether group in the novel organic cofactor.
The mechanical reliability of the membrane electrode assembly (MEA) in polymer electrolyte fuel cells (PEFCs) is a major concern with respect to fuel cell vehicles. When PEFCs generate power, water is generated. The proton exchange membrane (PEM) swells in wet conditions and shrinks in dry conditions. These cyclic conditions induce mechanical stress in the MEA, and cracks are formed. Failure of the MEA can result in leaking of fuel gases and reduced output power. Therefore, it is necessary to determine the mechanical reliability of the MEA under various mechanical and environmental conditions. The purpose of the present paper is to observe the deformation behavior of the MEA under humidity cycles. We have developed a device in which the constrained condition of the GDL is modeled by carbon bars of 100 to 500 μm in diameter. The carbon bars are placed side by side and are pressed against the MEA. The device was placed in a temperature and humidity controlled chamber, and humidity cycles were applied to the specimen. During the tests, cross sections of the specimen were observed by microscope, and the strain was calculated based on the curvature of the specimen. The temperature in the test chamber was varied from 25 to 80 °C, and the relative humidity was varied from 50 to 100%RH, and the wet condition was also investigated. The results revealed that the MEA deformed significantly by swelling and residual deformation was observed under the dry condition, even for one humidity cycle. The crack formation criteria for one humidity cycle corresponded approximately with those of the static tensile tests. The results of the humidity cycle tests followed Coffin–Manson law, and the number of cycles until crack formation corresponded approximately with the results of the mechanical fatigue tests. These results will be valuable in the critical design of durable PEFCs.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.