Microdetermination of nitroprusside by its inhibitory effect on the photolysis of the methylviologen-EDTA-acridine yellow system

A study of the photochemical reaction of the methylviologen (MV²⁺)-EDTA-Acridine Yellow system in the presence of nitroprusside (NP) is presented. The rate of photoreduction of methylviologen to the cation radical MV⁺ is dramatically retarded by small amounts of NP, which has an inhibitory effect on the excited state of Acridine Yellow, which is the activator of the process. Optimal conditions for the determination of NP in the range of concentrations between 2 × 10^–6 and 3 × 10^–5 M are described. The method proposed has been applied with excellent results to the determination of NP in pharmaceuticals and human serum, after protein elimination by perchloric acid.     

Light Induced Redox Reactions of Water Soluble Porphyrins,sensitization of hydrogen generation from water by zincporphyrin derivatives

The photoredox behaviour of two water soluble derivatives of zincporphyrin, 5,10,15,20-tetra-p-sulfonatophenyl ( 1 ) and 5,10,15,20-tetra-p-N-methylpyridiniochloride ( 2 ), was investigated using laser and continuous photolysis techniques. Photoexcitation produces triplet states whose lifetimes in aqueous solution exceeds 1 ms. These triplet states can be quenched reductively by donors such as EDTA and oxidatively by acceptors such as methylviologen (MV²⁺). Electron transfer to MV²⁺ is greatly influenced by the charge of the porphyrin, rate constants being 1.4 x 10¹⁰M^?1S^?1 and 2 × 10⁶M^?1S^?1 for 1 and 2 , respectively. In the presence of colloidal Pt catalyst, the cationic porphyrin sensitizes photoreduction of water to hydrogen with remarkable efficiency.     

ESR spectrometric characterization of the methyl viologen dosimeter in poly(vinyl alcohol) film

A dosimeter of poly(vinyl alcohol) (PVA) film containing methyl viologen dichloride (MV²⁺ (Cl^-)₂) was characterized by means of ESR and u.v. spectrometries. γ-irradiation of the MV²⁺-PVA dosimeter induced one-electron reduction of MV^2+· to thecation radical (MV⁺), thus giving rise to blue coloration. The resulting MV^+· showed an ESR signal with a g-factor of 2.0031. The yield of MV^+· at a given radiation dose was estimated from duplicate integral of the ESR first-derivative spectra by reference to 1,1'-diphenyl-2-picrylhydrazyl (DPPH). The yield of MV^+· thus estimated increased linearly with increasing the radiation dose up to about 1.4 Mrad. The ESR spectrometry of MV^+· showed a linear correlation with the u.v. spectrometric method reported previously.     

MECHANISM OF THE PHOTOSENSITIZED REDOX REACTIONS OF ACRIDINE ORANGE IN AQUEOUS SOLUTIONS-A SYSTEM OF INTEREST IN THE PHOTOCHEMICAL STORAGE OF SOLAR ENERGY†

-We have carried out a very detailed study, using fluorescence and optical flash photolysis techniques, of the photoreduction of methyl viologen (MV²⁺) by the electron donor ethylene diamine tetraacetic acid (EDTA) in aqueous solution sensitized by the dye acridine orange (AOH⁺). A complete mechanism has been proposed which accounts for virtually all of the known observations on this reaction. This reaction is novel in that both the triplet and the singlet state of AOH⁺ appear to be active photochemically. We have shown that mechanisms previously proposed for this reaction are probably incorrect due to an artifact. At pH 7 the fluorescence quantum yield φ_s of AOH⁺ is 0.26 ± 0.02 and the fluorescence lifetime is 1.8 ± 0.2 ns. φ_s is pH dependent and reaches a maximum of 0.56 at pH 4. The fluorescence of AOH⁺ is quenched by MV²⁺ at concentrations above 1 mM and the quenching obeys Stern-Volmer kinetics with a quenching rate constant of (1.0 ± 0.1) × 10¹⁰M^?1 s^?1. The quenching of the AOH⁺ excited singlet state by MV²⁺ almost certainly returns the AOH⁺ to its ground state with no photochemistry occurring. EDTA also quenches the fluorescence of AOH· with Stern-Volmer kinetics but with a smaller rate constant (6.4 ± 0.5) × 10⁸M^?1s^?1 at pH 7. In this case the quenching is reactive resulting in the formation of semireduced AOH. In the presence of MV²⁺, flash irradiation of AOH⁺ does result in the reversible formation of the semireduced MV? which absorbs at 603 nm. We attribute this to a photochemical reaction of the triplet state of AOH⁺ with MV²⁺. The initial quantum yield for formation of MV? (φ_MV:)₀ was found to be constant at 0.10 ± 0.05 for [MV²⁺] from 5 × 10^?5 to 1.0 × 10^?3 with [AOH⁺] = 8 × 10^?6M. Previous workers had found that (φ_MV:)₀ appears to decrease with decreasing [AOH⁺]; however, on careful investigation, we found this was most probably due to quenching of the triplet state of AOH⁺ by trace amounts of oxygen. When EDTA is added to a mixture of AOH ⁺ and MV²⁺ at pH 7, the photochemical formation of MV? becomes irreversible as the [EDTA] is increased. The quantum yield for the irreversible formation of MV? exceeds 0.10 becoming as large as 0.16 for [EDTA] = 0.014M. This fact requires that an alternative photochemical process must be operative and we present evidence that this is a reaction of EDTA with the excited singlet state of AOH⁺ to produce the semi-reduced AOH- which then reacts with MV²⁺ to produce MV?. The full kinetic scheme was tested by computer simulation and found to be totally consistent. This also enabled the processing of a full set of rate constants. When colloidal PtO₂ was added to the optimal mixture [EDTA] = 3.4 × 10^?2M; [MV²⁺] = 5 × 10^?4M; [AOH⁺] = 4 × 10^?5M; pH6 H₂ gas was produced at a rate of 0.2μmol H₂h^?1. Thus, acridine orange should serve as an effective sensitizer in reactions designed to use solar energy to photolyze water.     

Solar hydrogen production from cellulose biomass with enzymatic and artificial photosynthesis system

Bio-hydrogen gas production from renewable resources of timber waste, including cellulose, lignin, etc., is important in the environmental science and energy source development fields. A solar hydrogen production system by coupling waste paper including cellulose biomass with cellulase and glucose dehydrogenase (GDH), and hydrogen production with platinum nano-particle via the photoreduction of methylviologen (MV²⁺) using the visible light-harvesting function of Mg Chl-a, is developed.     

Efficient Photoredox Cycles to Control Perylenediimide Self-Assembly**

Photoreduction of perylenediimide (PDI) derivatives has been widely studied for use in photocatalysis, hydrogen evolution, photo-responsive gels, and organic semiconductors. Upon light irradiation, the radical anion (PDI⋅⁻) can readily be obtained, whereas further reduction to the dianion (PDI²⁻) is rare. Here we show that full 2-electron photoreduction can be achieved using UVC light: 1) in anaerobic conditions by ‘direct photoreduction’ of PDI aggregates, or 2) by ‘indirect photoreduction’ in aerobic conditions due to acetone ketyl radicals. The latter strategy is also efficient for other dyes, such as naphthalenediimide (NDI) and methylviologen (MV²⁺). Efficient photoreduction on the minute time-scale using simple LED light in aerobic conditions is attractive for use in dissipative light-driven systems and materials.     

Photoelectrochemical and characterization of intercalation compound of KTiNbO5 with methylviologen

Methylviologen (1,1′-dimethyl-4,4′dipyridinium ion, MV²⁺) has been intercalated into the interlayer space of layered potassium titanoniobate (KTiNbO₅) by a method involving the displacement of guest molecules using a n-hexylammonium titanoniobate (HeNH₃⁺-TiNbO₅) intercalation compound. The methylviologen titanoniobate (MV²⁺-TiNbO₅) intercalation compound was characterized using SEM, TEM, XRD, IR and elemental analysis. The photochemical and electrochemical behaviors of the MV²⁺-TiNbO₅ hybrid thin film were investigated. The photo excitation of oxygen-present MV²⁺-TiNbO₅ thin film with UV light indicated the electron transfer from the titanoniobate layer to MV²⁺ to form MV⁺ radical cation. The cyclic voltammogram of the MV²⁺-TiNbO₅ hybrid thin film exhibited two consecutive electron-transfer steps.     

Transient Raman detection of excited state electron,transfer to methyl viologen from photoexcited molecular reagents in fluid solution and anchored to SiO2

The lowest electronic excited state of the complexes [Ru(2,2′-bipyridine)₃]²⁺, fac-[ClRe (CO)₃(2,2′-bipyridine)], and fac-[(pyridine) Re (CO)₃(2,2′-bipyridine)]⁺ can be quenched by methyl viologen, MV²⁺, N,N′-dimethyl-4,4′-bipyridinium, in fluid solutions. The quenching obeys Stern—Volmer kinetics as deduced from plots of relative luminescence quantum yield vs [MV²⁺], and the data are consistent with a quenching process that is essentially diffusion controlled. Pulsed laser excitation (18 ns, 354.7 nm frequency tripled Nd: YAG) of the metal complexes in the presence of MV²⁺ shows that a detectable fraction of the quenching results in net electron transfer to form MV⁺. The MV⁺ is detectable by resonance Raman scattering from the trailing portion of the excitation pulse. Excited state electron transfer to MV²⁺ from a photo-excited complex anchored to SiO₂ has also been detected by transient Raman spectroscopy. High surface area SiO₂ was functionalized by reaction with 4-[2-(trimethoxysilyl)ethyl]pyridine to give [SiO₂]-SiEtpyr. Reaction of [SiO₂]-SiEtpyr with [(CH₃CN)Re(CO)₃(2,2′-bipyridine)]⁺ then yields [SiO₂]-[(SiEtpyr) Re (CO)₃ (2,2′-bipyridine)]⁺. Electron transfer quenching of the photo-excited immobilized Re complex occurs when suspended in CH₃CN solutions of MV²⁺ to yield MV⁺ as detected by resonance Raman scattering and by lifetime attenuation in the presence of MV²⁺.     

Transport and kinetics at microheterogeneous electrodes: Part V. The methylviologen/platinum system

Results are reported for the reaction of methylviologen radical cation, MV⁺ with platinum colloidal particles, studied by stopped flow spectrophotometry. The rate of the reaction depends on the gaseous pretreatment of the particles. For particles reduced by hydrogen, the kinetics are usually first order with respect to MV⁺. The reaction is also first order in the concentration of platinum, and is inhibited in a first order manner by the product MV²⁺. This inhibition suggests that MV²⁺ is adsorbed on the particle surfaces, and this has been confirmed by ac, ring—disc electrode studies on macroscopic platinum electrodes. At high concentrations of MV⁺ some deviation from first order kinetics is observed. These results are all explained by a kinetic model in which either the desorption of MV²⁺ or the adsorption of MV⁺ is the rate limiting process. The rate of consumption of MV⁺ on an oxidised surface is an order of magnitude faster than that on the reduced surface. Ring—disc studies show that this is because the MV⁺ is not producing H₂ but is reducing the surface oxide. The results are shown to fit a simple model which takes into account this titration of the oxide layer. The model also explains why the rate on partially oxidised surfaces will appear to have an order greater than one in [Pt].     

Use of ring-disc electrodes and viologens for the titration of cytochrome C and oxygen and for the study of their reduction kinetics

The use of ring-disc electrodes enable the electrogeneration of viologen cation radicals V⁺ when the disc potential is controlled in the range ?0.3 to ?0.65 and ?0.2 to ?0.45 V/NHE respectively in MV²⁺ and BV²⁺ solutions. We confirmed the occurrence of very fast reactions between V^.+ and horse-heart cytochrome c or oxygen and of slow or no reaction between V^.+ and β-nicotinamide adenine dinucleotide with xanthine oxidase, riboflavine and ferricyanide. Ring current versus dise current curves enable the titration of cytochrome c and oxygen and the estimation of the reaction rate between cytochrome c and MV^.+ [(6.2±2)10⁵M^?1 s^?1].     

Methylviologen cation radiacal,its dimer and complex in various media

Chemical, photochemical and radiolytic reduction of methylviologen, MV²⁺ (1,1'-dimethyl-4,4' -dipiridinum) leads to the formation of methylviologen cation radical, MV ^+.. It is stable in aprotic solvents, dry polymer foils and frozen aqueous solutions. In the presence of water at ambient temperatures MV^+. can undergo oxidation or conversion into dimer (MV^+.)₂ and/or complex MV^+. (MV²⁺). Upon freezing or addition of neutral salt, MV^+. forms dimers in diluted MV²⁺ solutions (below 0.01 mol dm^-3) while in concentrated ones (exceeding 0.05 mol dm^-3) the formation of the complex prevails. Spectral and E.S.R. characteristics of MV^+., its dimer and complex are given.     

Microdetermination of riboflavin and riboflavin 5′-phosphate by a catalytic photokinetic method

The method is based on the rate of photoreduction of both compounds by EDTA, which is a linear function of the concentration of riboflavin and riboflavin 5'-phosphate at low concentrations. The rate is monitored spectrophotometrically by the formation of ferroin, which is generated after reduction of iron(III) by the 1,5-dihydro form of the riboflavins in the presence of 1,10-phenanthroline. Linear calibration graphs are obtained between 3 × 10^?8 and 9.6 × 10^?7 M. The method is successfully applied to the determination of vitamin B₂ in pharmaceuticals, foods and rat tissues.     

AMPHIPHILIC COPOLYMERS AS MEDIA FOR LIGHT-INDUCED ELECTRON TRANSFER–I. ELECTROSTATIC EFFECT ON THE FORWARD REACTION AS STUDIED BY FLUORESCENCE QUENCHING

Abstract— Fluorescence quenching of amphiphilic copolymers, poly(9-vinylphenanthrene-co-sodium 2-acrylamido-2-methylpropanesulfonate) (APh) and poly(9-vinylphenanthrene-co-3-methacrylamidopropyltrimethylammonium methyl sulfate) (QPh), in aqueous solution, was studied using methyl viologen (MV²⁺) or 4,4'-bipyridinium-1, 1'-bis(trimethylenesulfonate) (SPV) as oxidative quenchers. The fluorescence of the excited phenanthrene groups in APh was found to be efficiently quenched by MV²⁺. The apparent second-order rate constant for the quenching, k_q, ranged in the magnitude of 10¹¹ -10¹²M^-1 s^-1, which are well beyond the diffusion-controlled limit. This is presumably due to an increase of the effective concentration of MV²⁺ around the fluorophore in the copolymer resulting from electrostatic attraction between MV²⁺ and anionic segments of APh. This strong electrostatic interaction also favors the formation of ground-state EDA (electron donor acceptor) complex between the phenanthrene residue and MV²⁺. Such striking behaviors were not observed with the related model compound. Unexpectedly, the quenching with SPV, a zwitterionic quencher, was also enhanced in the polymer system (k_q= 2–6 × 10¹⁰M^-1 s^-1), suggesting the presence of some attractive interaction between APh and SPV. Contrary to the APh system, the fluorescence quenching of the corresponding cationic polymer (QPh) with MV²⁺ was strongly diminished (k_q= 5 × 10⁸M^-1 s^-1). This indicates that the polycation of QPh effectively prevents the access of MV²⁺ to the polymer.     

Determination of diquat and paraquat in water by liquid chromatography-(electrospray ionization) mass spectrometry

A method for the determination of the herbicides diquat and paraquat in water was developed using liquid chromatography-(electrospray ionization) mass spectrometry [LC-(ESI)MS]. The analytes were isolated on an ENVI-8 DSK solid phase extraction (SPE) disk and eluted with 5-M trifluoroacetic acid (TFA). The eluate was evaporated to dryness and the analytes were redissolved in the mobile phase (7% methanol/93% water/25-mM TFA). The extract was analyzed by liquid chromatography (C1 column) with postcolumn addition of propionic acid/methanol followed by (ESI)MS. Diquat was detected using the [M²⁺ ? H⁺] ion (M²⁺ = dication) at m/z 183, whereas paraquat was detected using the mono-trifluoroacetate ion pair [M²⁺/^?OOCCF₃] at m/z 299. Quantitation was done by isotope dilution mass spectrometry using d ₄-diquat and d ₈-paraquat and the corresponding ions [M²⁺ ? D⁺] and [M²⁺/^?OOCCF₃] at m/z 186 and m/z 307, respectively. Detection limits of 0. 1 and 0. 2 µg/L, respectively (based on the dications), were adequate to meet the Ontario Drinking Water Objectives of 70 and 10 µg/L, respectively, and the Ontario Provincial Water Quality Objective for diquat of 0. 5 µg/L. Precision and accuracy were 14% and 6% for diquat and 12% and 3% for paraquat.     

Specific electron transfer mechanism from the photoexcited tetrasulfonated Zn(II)-tetraphenylporphyrin to methylviologen via self-assembled ionic complex

Electron transfer from photoexcited tetrasulfonated Zn(II)-tetraphenylporphyrin (ZnTSTPP) to methyviologen (MV²⁺) was studied. From the investigation of relative fluorescence intensity and emission lifetime against the MV²⁺ concentration, it was concluded that the electron transfer takes place by a static mechanism. Based on the analysis of the quenching behavior, it was concluded that the static reaction did not follow an ordinary Perrin model, but interaction of the donor (photoexcited Zn-TSTPP) and the acceptor (MV²⁺) molecules, ionic interaction in the present case, is responsible. The analysis of the quenching gave the equilibrium constant for the interaction to be K = 6.5 × 10⁴ M⁻¹. A two-dimensional selfassembled macromolecular ionic complex between ZnTSTPP and MV²⁺ is proposed.     

Carbon Paste Electrode Modified with Biochar for Sensitive Electrochemical Determination of Paraquat

The present work reports for the first time the determination of paraquat (PQ²⁺) by Differential Pulse Adsorptive Stripping Voltammetry (DPAdSV) using a carbon paste electrode modified (CPME) with biochar obtained from castor oil cake at different temperatures (200–600 °C). The best voltammetric response was verified using biochar yielded at 400 °C (CPME‐BC400). Linear dynamic range (LDR) for PQ²⁺ concentrations between 3.0×10^?8 and 1.0×10^?6 mol L^?1 and a limit of detection (LOD) of 7.5×10^?9 mol L^?1 were verified. The method was successfully applied for PQ²⁺ quantification in spiked samples of natural water and coconut water.     

Excited state electron transfer from photoexcited fac-CIRe(CO)3(2,2′-bipyridine) to N,N′-dimethyl-4,4′-bipyridinium detected by transient

Pulsed laser excitation of fac-CIRe(CO)₃(bpy) in CH₃CN containing N,N′-dimethyl-4,4′-bipyridinium, MV²⁺, results in excited state electron transfer to form MV⁺ that can be detected by the Raman scattering from the trailing portion of the 18 ns 354.7 nm pulse from the frequency-tripled Nd : YAG laser excitation source. Essentially the same results are found for the pulsed excitation of Ru(bpy)₃²⁺ in H₂O containing MV²⁺.     

Electrochemical synthesis of metal nanoparticles using a polymeric mediator,whose reduced form is adsorbed (deposited) on an electrode

Efficient mediated electrosynthesis of nanocomposite Au@р(MVCA⁸⁺-co-St) (~6 nm), in which ultrasmall Au nanoparticles (Au-NP) were bound in nanocapsules of water-soluble nanoparticles of соpolymer р(MVCA⁸⁺-co-St) of tetraviologen calix[4]resorcinol (MVCA⁸⁺) with styrene (St), was accomplished by the reduction of Au^I in aqueous medium. The quanti- tative reduction of Au^I was carried out using the theoretically necessary amount of electricity and was not accompanied by the deposition of metal on the electrode. Radical cations of viologen units MV^?+ of the molecule р(MVCA^4?+-co-St) adsorbed on the electrode and π-dimers MV^?+···MV^?+ of π-polymers [р(MVCA^4?+-co-St)] _n deposited on the electrode act- ed as the reducing agents with respect to Au^I. During electrolysis, the nanoparticles agglo- merated to 37—50 nm. The nanocomposite particles dispersed in ethanol had sizes of 72±16 nm and also contained Au-NP with sizes of 51±8 and 19±3 nm. The catalytic activity of the nanocomposite in the reduction of p-nitrophenol with sodium borohydride was demon- strated. A similar reduction of AgCl nanoparticles (~250 nm) led to the formation of silver nanoparticles with crystallite sizes in the range of 7—11 nm, the process was inefficient, however, even when using 250% of electricity, an incomplete reduction of AgCl was still observed.     

Photoinduced reaction on quantized GaAs nanocrystals prepared by wet process

Gallium arsenide nanocrystals of 1.5 to 9.0 nm were prepared in triethylene glycol dimethylether (triglyme), and photoinduced reduction of methylviologen (MV²⁺) on the nanocrystals was investigated. The rate of MV+ production determined for an initial stage of photoinduced reduction of MV²⁺ was found to be low compared to that determined for bulk GaAs particles of 0.4 mm, if the rate was evaluated for unit surface area of the semiconductor particles. To account for this finding, the apparent association constant of MV²⁺ to GaAs was determined, which suggested that molecular species which worked as stabilizing agents for the GaAs nanocrystals retarded the adsorption of MV²⁺ onto the particle surfaces.     

Uncatalyzed and ruthenium(III)‐catalyzed reaction of acidic chlorite with methylene violet

The kinetics and mechanism of the uncatalyzed and Ru(III)‐catalyzed oxidation of methylene violet (3‐amino‐7‐diethylamino‐5‐phenyl phenazinium chloride) (MV⁺) by acidic chlorite is reported. With excess concentrations of other reactants, both uncatalyzed and catalyzed reactions had pseudo‐first‐order kinetics with respect to MV⁺. The uncatalyzed reaction had first‐order dependence on chlorite and H⁺ concentrations, but the catalyzed reaction had first‐order dependence on both chlorite and catalyst, and a fractional order with respect to [H⁺]. The rate coefficient of the uncatalyzed reaction is (5.72 ± 0.19) M^?2 s^?1, while the catalytic constant for the catalyzed reaction is (22.4 ± 0.3) × 10³ M^?1 s^?1. The basic stoichiometric equation is as follows: 2MV⁺ + 7ClO₂^? + 2H⁺ = 2P + CH₃COOH + 4ClO₂ + 3Cl^?, where P⁺ = 3‐amino‐7‐ethylamino‐5‐phenyl phenazinium‐10‐N‐oxide. Stoichiometry is dependent on the initial concentration of chlorite present. Consistent with the experimental results, pertinent mechanisms are proposed. The proposed 15‐step mechanism is simulated using literature; experimental and estimated rate coefficients and the simulated plots agreed well with the experimental curves. © 2003 Wiley Periodicals, Inc. Int J Chem Kinet 35: 294–303, 2003