Electrodimerization of the pyridiniumcarboxylic acids homarine and trigonelline

Homarine (1-methyl-2-carboxypyridinium ion) and trigonelline (1-methyl-3-carboxy-pyridinium ion) are reduced at mercury electrodes in alkaline solutions by a one-electron transfer to the pyridinium ring. Analysis of polarographic wave shapes using deviation-pattern recognition, peak widths of cyclic voltammograms, analysis of the products of bulk electrolyses and dependences of E_1/2 and E_p on scan rate, pH and concentration indicated that these reductions proceed by an EC² mechanism, where the second-order chemical reaction is a homogeneous dimerization. The zwitterionic form of the pyridiniumcarboxylic acid, which predominates in alkaline solutions, undergoes reduction to form a pyridinyl anion radical. Two radicals then couple to yield a dimer dianion which is subject to protonation. The dimer can be oxidized at mercury electrodes.     

Electrolytic reduction of 3-carbethoxyquinoline

Two well-defined one-electron waves are observed on the polarograms for the reduction of 3-carbethoxyquinoline in 95% aqueous ethanol containing 1 M ammonium acetate. During macroscate electrolysis at a potential on the plateau of either wave, the ratio of the heights of the waves remains equal to one. Polarographic and voltammetric evidence is presented that the first wave represents a reversible one-electron reduction to a radical which rapidly dimerizes; and the second wave represents an irreversible one-electron reduction of the initially formed radical. The reduction mechanism suggested by the electrochemical evidence is verified by the isolation of dimeric products from controlled-potential electrolysis at the top of the first wave and the isolation of 1,4-dihydro-3-carbethoxyquinoline at the top of the second wave. The chemical characteristics of the dimeric products are discussed.     

Significant enhancement of electron transfer reduction of NAD(+) analogues by complexation with scandium ion and the detection of the radical intermediate-scandium ion complex

4-Acetyl-N,N-diisopropyl-1-benzylnicotinamidinium ion (ABNA(+)) and 1-benzyl-4-phenylnicotinamidinium ion (PhBNA(+)) were newly synthesized as NAD(+) analogues to examine the electron-transfer reactivity and the effects of metal ions on the reactivity in comparison with those of 1-benzylnicotinamidinium ion (BNA(+)) and 1-methyl-4-phenylpyridinium ion (MPP(+)) which has no amide or acetyl group. A remarkable positive shift in the one-electron reduction potential of ABNA(+) was observed in the presence of Sc(3+) which forms a 1:1 complex with ABNA(+) through both acetyl and amide groups, whereas no such shift in the presence of Sc(3+) was observed for the one-electron reduction of MPP(+) which has no acetyl or amide group. Similar but less positive shifts in the one-electron reduction potentials were observed in the presence of Sc(3+) for the one-electron reduction of BNA(+) and PhBNA(+) both of which have only one amide group. The rate of electron-transfer reduction of ABNA(+) is enhanced significantly by the complexation with Sc(3+) to produce stable ABNA(*)-Sc(3+) complex which has been successfully detected by ESR. The electron self-exchange rates of the MPP(*)/MPP(+) system have been determined from the ESR line width variation and are compared with those of the ABNA(*)/ABNA(+) system.     

Electrochemical behavior of decyl mercuric halides at mercury cathodes in dimethylformamide

Polarograms for decyl mercuric halides in dimethylformamide containing tetraalkylammonium perchlorates exhibit two waves. When large-scale electrolyses of decyl mercuric halides are performed at potentials corresponding to the first polarographic wave, the couldometric n value is unity and didecylmercury is obtained in quantitative yield; electrolyses carried out at potentials on the plateau of the second polarographic wave afford only decane and the n value is essentially 2. Double-potential-step chronocoulometry and staircase voltammetry indicate that, at potentials corresponding to the first polarographic wave, the decyl mercuric halide (which is itself adsorbed onto mercury to the extent of less than a monolayer) undergoes reversible one-electron reduction to adsorbed decyl mercury radicals and to adsorbed decyl mercury radical “polymer”; the adsorbed radicals have a lifetime of approximately 10^?3s and disproportionate into didecylmercury and elemental mercury. In the presence of electrolytically released halide ion, the adsorbed radicals are reoxidized to the decyl mercuric halide; alternately, the adsorbed species are reoxidized to decyl mercury cations at a potential approximately 600 mV more positive than that required for reoxidation to the decyl mercuric halide. At potentials corresponding to the second polarographic wave, reduction of decyl mercuric halides is an irreversible process producing decyl carbanions which are protonated by traces of water in the solvent to give decane.     

Preparation of monocrystalline Pt microelectrodes and electrochemical study of the plane surfaces cut in the direction of the {111} and {110} planes

2-Cyano-1-methylpyridinium ion, I, exhibits three well-defined polarographic waves in Britton-Robinson buffer at pH 5 to 8. Electrolysis at the plateau potential of the most positive wave, involving a one-electron uptake, leads to the formation of a pyridinyl radical which probably dimerizes to a 2,4′-linked structure, VIII. Electrolysis at the plateau potential of the second wave, involving a number of electrons variable between nearly 4 (at pH≈5) and ≈3 (at pH≈8), leads to the formation of a mixture of 2-aminomethyl-1-methylpyridinium ion and 1-methylpyridinium ion. At the third wave potentials the second wave products are further reduced to give basic species with catalytic activity.     

CHLOROPHYLL-PHOTOSENSITIZED OXIDATION OF HYDROQUINONE AND p-PHENYLENEDIAMINE DERIVATIVES

Abstract— ESR and photovoltaic studies on light-induced one-electron transfer between chlorophyll a and electron donors in the absence of oxygen show (1) the possible conversion of photo-reduced chlorophyll a and p-benzosemiquinone ion radicals to their non-ionic radicals in methanol solutions of low pH, (2) the production of ESR absorption of tetrachloro-p-benzosemi-quinone even in benzene, enhanced by the addition of triethylamine or methanol, and (3) the transfer of one electron from tetramethyl-p-phenylenediamine to either excited chlorophyll a or pheophytin a in methanol at pH above 3.6 but not to pheophytin a at pH below 1 0 where its radical cation appears to accept an electron from excited pheophytin a . Bacteteriochloro-phyll is also shown to be capable of photooxidizing hydroquinones and tetramethyl-p-phenyl-enediamine.
The presence of oxygen enhances chlorophyll a -photosensitized oxidation of hydroquinone and tetrachloro-hydroquinone by one-electron transfer to oxygen and of trimethylhydro-quinone probably by two-electron trnasfer to oxygen. A free radical from excited chlorophyll a-oxygen interaction is formed in these reactions, but rapidly quenched in the case of trimethyl-hydroquinone. This, kind of free radical is not formed in pheophytin a . Tetramethyl- p -phenyl-enediamine readily undergoes chlorophyll a-photosensitized oxidation by oxygen in any pH region.     

Free radical products in X-irradiated Rochelle salt: low temperature ENDOR and DFT studies

Single crystals of Rochelle salt, [⁻OOC-CHOH-CHOH-COO⁻, Na⁺, K⁺]·4H₂O, X-irradiated at 10 K, have been examined using EPR, ENDOR and EIE spectroscopic techniques to characterize the radiation induced radicals stable at that temperature and their reactions upon warming. The one-electron gain product was observed and from the hyperfine interaction with a β-proton it was unambiguously centered at the C₄ position of the tartrate moiety. An additional nearly isotropic hyperfine structure of about 21 MHz was tentatively assigned to interaction with a sodium ion exhibiting a close contact to O₃ in the crystal. Evidence was obtained that the one-electron reduced radical had become protonated at one of the C₄ bonded carboxyl oxygens, most probably O₄. No evidence for the corresponding C₁-centered reduction product was found. Two resonance lines (R2, A1) were shown by EIE to belong to a species formed by decarboxylation at C₃, a secondary oxidation product. Two other resonance lines (K1, K2) were assigned to two varieties of another decarboxylation radical, centered at C₂, distinguished by differences in the potassium ion coordination. Furthermore, one other resonance line (A2) was tentatively ascribed to a third decarboxylation radical, centered at the opposite end of the tartrate moiety. The precursor of these products, that is, the one-electron loss product, was not observed after X-irradiation at 10 K. Thermally induced free radical reactions followed by EPR in the temperature range of 12-119 K indicate that a water molecule or a hydroxyl ion is eliminated from the one-electron reduction product radical and that a C₃-centered radical is formed. The reduction and oxidation reaction pathways of hydroxy acid derivatives are discussed.     

Primary processes in the photosensitized redox reaction of dimers of thiacarbocyanine dyes

The kinetics and the mechanism of the reaction of donor (ascorbic acid) oxidation by electron acceptors (methylviologen and p-nitroacetophenone) photosensitized by dimers of sulfoalkyl-9-ethylthiacarbocyanine dyes (Dye1, Dye2, and Dye3) were studied in aqueous solutions. Dimers of the dyes (dianions) are capable of transition to the triplet state that is mainly quenched by acceptors to form radical anions of dimers, which are unstable and dissociate within 10–12 μs into the monomer (anion) and its radical (the limiting reaction stage). The presence of a donor in the dye-acceptor mixture leads to one-electron reduction of the monomer radical to its anion followed by the dimerization reaction. The results of the analysis of the experimental data obtained by the laser photolysis technique are in good agreement with the calculated kinetic curves for the formation and the decay of the dimer radical anions.     

Behavior of electrogenerated bases in room-temperature ionic liquids

The reductive electrochemistry of substituted benzophenones in the aprotic room-temperature ionic liquid (RTIL) 1-butyl-1-methylpyrrolidinium bistriflimide occurs via two consecutive one-electron processes leading to the radical anion and dianion, respectively. The radical anion exhibited electrochemical reversibility at all time-scales whereas the dianion exhibited reversibility at potential sweep rates of >or=10 V s(-1), collectively indicating the absence of strong ion-paring with the RTIL cation. In contrast, reduction in 1-butyl-3-methylimidazolium bistriflimide is complicated by proton-transfer from the [Bmim] cation. At low potential sweep rates, reduction involves a single two-electron process characteristic of either an electrochemical, chemical, electrochemical (ECE) or disproportion-type (DISP1) mechanism. The rate of radical anion protonation in [Bmim] is governed by basicity and conforms to the Hammett free-energy relation. At higher potential sweep rates in [Bmim][NTf2], reduction occurs via two consecutive one-electron processes, giving rise to the partially reversible generation of the radical anion and the irreversible generation of the dianion, respectively. Also, the redox potentials for the reversible parent/radical anion couples were found to be a linear function of Hammett substituent constants in both RTIL media and exhibited effectively equivalent solvent-dependent reaction constants, which are similar to those for reduction in polar molecular solvents such as acetonitrile or alcohols.     

The standard redox potential of the phenyl radical/anion couple

The voltammogram of aryldiazonium tetrafluoroborates in acetonitrile (ACN), at low concentration, shows a first one-electron wave followed at a more negative potential by a small second wave; this last one corresponds to the reduction of the radical formed at the level of the first wave. Simulation of the voltammogram permits one to determine the standard redox potential of the radical/anion couple Eo(Ph./Ph-) = 0.05 V/SCE and the reduction mechanism of the diazonium cation. An electron transfer concerted with the cleavage of the C-N bond furnishes the aryl radical; this radical undergoes two competitive reactions: reduction at the electrode and H-atom transfer.     

Electrochemical reduction of uracil in dimethyl sulfoxide: Autoprotonation of the anion radical

The electrochemical reduction of uracil in dimethyl sulfoxide was investigated, using d.c.and a.c. polarography, cyclic voltammetry, and controlled potential electrolysis. Uracil is reduced in a one-electron step (E_1/2=?2.3 V); the apparent number of electrons transferred (n) decreases from one at infinite dilution to one-half at concentrations above 1mM. The concentration dependent n-value is due to proton transfer by the parent compound to the radical anion formed on reduction. Such a proton transfer, which has been observed for 2-hydroxypyrimidine, deactivates part of the uracil, which would otherwise be available for reduction, by formation of the more difficultly reducible conjugate base. The uracil anion forms insoluble mercury salts, producing two oxidation waves (E_1/2 of ?0.1 and ?0.3 V); the latter wave is due to formation of a passivating film on the electrode. Digital simulations indicate that the protonation rate exceeds 10⁵M^?1 s^?1 and that, at low uracil concentration, some of the free radical formed on protonation is further reduced. At concentrations exceeding 1 mM, all of the free radical dimerizes. The effect of added acids and base on the electrochemical behavior is described.     

Electrogenerated chemiluminescence: Part XXVII. E.C.L. and electrochemical studies of selected laser dyes

The electrogenerated chemiluminescence (e.c.l.) and electrochemistry of the laser dyes, coumarin-2, coumarin-30, rhodamine-6G (perchlorate), rhodamine-B (perchlorate), oxazine-1 (perchlorate), and Nile Blue (perchlorate) were studied in acetonitrile using 0.1 M tetra-n-butylammonium perchlorate (TBAP) as a supporting electrolyte. Rather low intensity e.c.l. was obtained for all dyes except Nile Blue. A study of the electrochemical oxidation and reduction of coumarin-30, oxazine-1 and rhodamine-6G using cyclic voltammetry and controlled potential coulometry demonstrated that chemical side reactions of the electrogenerated reactants are responsible for the low e.c.l. efficiency. In several cases the one-electron transfer reaction at the electrode is followed by a dimerization reaction. The neutral free radical formed on reduction of oxazine-1 was investigated by electron spin resonance spectroscopy and coupling constants for it are reported. Some experiments in which the e.c.l. of mixtures of the dyes with rubrene or 9,10-diphenylanthracene were determined are also described.     

Efficient visible light photocatalysis of [2+2] enone cycloadditions

We report that Ru(bipy)3Cl2 can serve as a visible light photocatalyst for [2+2] enone cycloadditions. A variety of aryl enones participate readily in the reaction, and the diastereoselectivity in the formation of the cyclobutane products is excellent. We propose a mechanism in which a photogenerated Ru(bipy)3+ complex promotes one-electron reduction of the enone substrate, which undergoes subsequent radical anion cycloaddition. The efficiency of this process is extremely high, which allows rapid, high-yielding [2+2] cyclizations to be conducted using incident sunlight as the only source of irradiation.     

Distannane mediated reaction of N-acyliminium ion pools with alkyl halides. A chain mechanism involving radical addition followed by electron transfer

Hexabutyldistannane was found to be an effective mediator allowing the reaction of N-acyliminium ion pools with alkyl halides. A chain mechanism involving the addition of an alkyl radical generated from an alkyl halide to an N-acyliminium ion followed by the one-electron reduction of the resulting radical-cation by distannane was proposed.     

The redox behavior of gem-dihalo compounds: 9,9-dibromofluorene, 9,9-dichlorofluorene and dichlorodiphenylmethane

The redox behavior of several gem-dihalo compounds has been examined at platinum and vitreous carbon electrodes in dimethylformamide. The reduction of 9,9-dichlorofluorene is initially an overall two-electron process which involves cleavage of chloride ion and the formation of 9-chlorofluorenyl anion. The final products and their distribution are then dependent upon the relative rates of reduction of the parent compound, nucleophilic attack of 9-chlorofluorenyl anion on the parent compound, and proton availability. If reaction by substitution is permitted to predominate, 9,9′-dichlorobifluorenyl results. This species is electroactive at the applied potential and undergoes reductive dechlorination to give bifluorenylidene. In contrast, if either the rate of reduction of 9,9-dichlorofluorene of the rate of protonation of 9-chlorofluorenyl anion exceeds the rate of substitution, the predominant product becomes 9-chlorofluorene. Reduction of this species then gives a mixture of fluorene and bifluorenyl when electrolysis is effected in an aprotic medium and fluorene when electrolysis is performed in the presence of diethyl malonate, a weak proton donor. Dichlorodiphenylmethane and 9,9-dibromofluorene also undergo reductive dehalogenation to give monomeric and dimeric products by pathways analogous to those observed for dichlorofluorene. In the case of dibromofluorene, however, the product distribution is also potential dependent since the intermediate 9-bromofluorenyl radical may not be reduced at the applied potential. No evidence was obtained in these studies to support previous claims of carbenes and/or carbene radical anions in these reductions.     

Mechanistic study of colchicine's reduction behavior

Electrochemistry/mass spectrometry (EC/MS) using two different types of electrolytic cells was employed for the systematic mechanistic study of colchicine's reduction, both in aqueous and non-aqueous media. In aqueous media, at around − 1 V vs. Ag/AgCl, colchicine suffers a single-electron reduction to a transient anion radical, which after a follow-up protonation leads to a neutral free radical (E_rC_i mechanism). Depending on the experimental conditions, the latter undergoes some dimerization. At more negative potentials (− 1.4 V vs. Ag/AgCl) and pH < 7, the free radical is undergoing another single-electron reduction and a subsequent protonation. In the absence of protons (aprotic media), the one-electron reduction gives the anion radical. This process becomes fully reversible at high scan rates (≥ 10 V/s).     

On the question of one-electron transfer in the mechanism of reduction by nadh-models

The fluorescence of 1-benzyl-1,4-dihydronicotinamide (BNAH) is quenched by a variety of electron acceptors. The dependence of the rate constant of the quenching process on the electrochemical reduction potentials of the quenchers corresponds with that expected for quenching by an electron transfer mechanism in which BNAH acts as an electron donor with a one electron oxidation potential of 0.76 ± 0.02 V (in acetonitrile relative to the saturated calomel electrode).From this oxidation potential, and the reduction potentials of a number of substrates reported to be reduced by BNAH, the rates of thermal one-electron transfer from BNAH to these substrates were estimated via the Rehm-Weller relation for outersphere one-electron transfer. These calculated rates are many orders of magnitude lower than experimental rates reported for the overall reduction processes. This seems to exclude outersphere one-electron transfer as an intermediate step in such reductions.     

竹红菌甲素敏化氧化还原型谷胱甘肽中的类型Ⅰ和类型Ⅱ反应

本文研究了竹红菌甲素和还原型谷胱甘肽(GluSH)间的光诱导氧化还原作用。甲素是3,10-二羟基-4,10-苝醌衍生物。在GluSH作为电子给体时,甲素经受可见光诱导的单电子还原,生成年醌自由基或二氢甲素,取决于pH值,同时GluSH被氧化。甲素的单电子还原量子效率随pH值增加而增加。在充氧溶液中甲素敏化氧化GluSH的反应通过类型Ⅰ和Ⅱ的混合机制进行。用ESR检测到了通过Fenton反应产生的羟基自由基。在脂质体包裹的甲素溶液中用动力学测定方法证明了甲素敏化GluSH的氧化是通过类型Ⅱ机制进行的。     

Electrochemical behaviour of tris (2,2′-bipyridine) osmium(II) complex in dimethylformamide

The electrochemical behaviour of Os(bpy)₃²⁺ (bpy=2,2′-bipyridine) has been investigated in N,N-dimethylformamide by utilizing predominantly the techniques of polarography and cyclic voltammetry. The study has been carried out at different temperatures in the range ?20 to +30° C. The number of reduction waves observed depends markedly on temperature. For intermediate temperatures, the complex exhibits six reduction waves, the maximum number of waves observed as a function of temperature.The first three reduction processes, corresponding to the first three reduction waves, are one-electron, diffusion-controlled reversible processes in all conditions. Conversely, process four is consistent with one-electron reversible transfer only at the lowest temperature. In fact, for higher temperatures the liberation of bpy, preferentially as a radical anion rather than a neutral molecule, occurs. In the latter case, the liberated neutral bpy molecule can be reduced by one-electron transfer. Process five is due to the reduction of species formed by chemical reaction in the preceding electrode process, i.e. the bpy radical anion and Os(bpy)₂^1?. Process six is consistent with the addition of five electrons to the starting complex, followed by the liberation and successive reduction of the bpy radical anion.