Nonlinear chemical reaction between Na_2S_2O_3 and Peroxide compound

Kinetics of reaction between Na2S2O3 and peroxide compound ( H2O2 or Na2S2O8) in a batch reactor and in a continuous stirring tank reactor (CSTR) were studied.Steady oscillations in uncatalyzed reactions in a CSTR were first discovered.In Na2S2O3-H2O2-H2SO4 reaction system,Pt potential and pH of higher and lower flow rutes beyond oscillation flow rates were in around the same extreme values.The reaction catalyeed by Cu2+ corsist of the catalyzed oscillation process and the uncatalyzed osciliation one.On the basis of experiment,a reaction mechanism consisting of three stages was put forward.The three stages are H positive-feedback reactions,proton negative-feedba k (uncatalyzed negative-feedback and catalyzed negative-feedback) reactions and transitional reactions.The mechanism is able to explain reasonably the nonlinear chemical phenomena appearing in the thiosulfatc oxidation reaction by peroxide-compounds.     

The reduction of methylene blue by sulfide ion in the absence and presence of oxygen: Simulation of the methylene blue-O2?HS?-CSTR oscillations

A mechanism is discussed which reproduces in simulations the oscillations during the methylene-blue catalyzed reduction of O₂ by HS^– in a continuous-flow, strirred tank reactor (CSTR). It contains 14 reactions and is based on experiments and simulations of simpler reactions including the reduction of MB⁺ by HS^– in the absence and presence of O₂ and the reactions of H₂O₂ and O₂ with HS^–. All experiments on component reactions as well as the CSTR oscillations can be simulated by the same set of reactions and rate constants. The major dynamic feature of the mechanism is the competition for MB^. by the oxidizing agents O₂ and H₂O₂ and the reducing agents HS^– and HS^.. The species MB^. is the radical intermediate between the colored (MB⁺) and colorless (MBH) forms of methylene blue.     

Cu(II) catalyzed reaction between phenyl hydrazine and toluidine blue—dual role of acid

The detailed kinetics of Cu(II) catalyzed reduction of toluidine blue (TB⁺) by phenyl hydrazine (Pz) in aqueous solution is studied. Toluidine white (TBH) and the diazonium ions are the main products of the reaction. The diazonium ion further decomposes to phenol (PhOH) and nitrogen. At low concentrations of acid, H⁺ ion autocatalyzes the uncatalyzed reaction and hampers the Cu(II) catalyzed reaction. At high concentrations, H⁺ hinders both the uncatalyzed and Cu(II) catalyzed reactions. Cu(II) catalyzed had stoichiometry similar to the uncatalyzed reaction, Pz+2 TB⁺+H₂O=PhOH+2 TBH+2 H⁺+N₂. Cu(II) catalyzed reaction occurs possibly through ternary complex formation between the unprotonated toluidine blue and phenyl hydrazine and catalyst. The rate coefficient for the Cu(II) catalyzed reaction is 2.1×10⁴ M⁻² s⁻¹. A detailed 13‐step mechanistic scheme for the Cu(II) catalyzed reaction is proposed, which is supported by simulations. © 1999 John Wiley & Sons, Inc., Int J Chem Kinet 31: 271–276, 1999     

Kinetics and mechanism of autocatalyzed reaction between Phenyl Hydrazine and Toluidine blue in aqueous solution

The kinetics and mechanism of reduction of aqueous toluidine blue (TB⁺) by phenyl hydrazine (Pz), which exhibits nonlinear behavior, is studied spectrophotometrically at 630 nm. Typical kinetic curves exhibited autocatalytic characteristics. The role of H⁺ as an autocatalyst is established. Rate constants for the uncatalyzed and acid catalyzed reactions are determined. The forward rate constants for the uncatalyzed and acid catalyzed reactions were 1.4 × 10⁻² M⁻¹ s⁻¹ and 60 M⁻¹ s⁻¹. Reaction products are toluidine white, phenol, and an azo dye. From the stoichiometric ratios, the major reaction is Pz + 2 TB⁺ + H₂O = PhOH + 2 TBH + 2 H⁺ + N₂. The rate expression and a detailed 12‐step reaction mechanism supported by simulations are proposed. ©1999 John Wiley & Sons, Inc. Int J Chem Kinet: 31: 83–88, 1999     

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     

Study of solvent extraction of <Superscript>114m</Superscript>In(III) using quinaldic acid into isoamyl alcohol

A complementary study of hydroxyl radical formation in the depleted uranium (DU)-hydrogen peroxide (H₂O₂) system and the effect of biosubstances on the system were examined using the spin-trapping method. Hydroxyl radical was formed in the uranyl ion (UO₂ ²⁺), 5,5-dimethyl-1-pyrroline-N-oxide (DMPO), and hydrogen peroxide (H₂O₂) mixture solution. The pseudo first order rate constants of DMPO-OH formation were estimated to be 0.033 s⁻¹ for UO₂ ²⁺-H₂O₂-DMPO solution and 0.153 s⁻¹ for UO₂₊-H₂O₂-DMPO solution. The obtained results indicated that the hydroxyl radical formation in the UO₂ ²⁺-H₂O₂ solution could be described as a stepwise reaction process including the reduction of UO₂ ²⁺ to UO₂ ²⁺ by H₂O₂ and the Fenton-type reaction of UO₂ ⁺ with H₂O₂. Biosubstances, such as proteins, amino acids and saccharides, decreased the DMPO-OH formation, which was caused by the direct hydroxyl radical scavenging and the suppression of hydroxyl radical formation by coupling with uranyl ion.     

Etude analytique par thermogravimetrie et analyse thermique differentielle du peroxyde de sodium hydrate et du peroxyde de sodium commercial

Thermogravimetry and differential thermal analysis were used to study hydrated sodium peroxide and the so-called anhydrous commercial product. Prolonged dehydration of the octahydrate under vacuum led to the partial formation of Na₂O₂-H₂O₂ compounds as well as the dihydrate and monohydrate The DTA curves for commercial sodium peroxide heated in air or other gases, showed the partial formation of Na₂O₂·2H₂O₂·nH₂O and of NaHCO₄·H₂O by the action of the gases on the NaO₂ contained in the Na₂O₂.     

Investigation of peroxyhydrates and hydrates of rubidium and cesium carbonates Communication 2. Physicochemical study of the ternary system Rb2CO2-H2O2-H2O

Conclusions A physicochemical investigation of the system Rb₂CO₃-H₂O₂-H₂O in the region of high hydrogen peroxide concentrations at low temperatures revealed for the first time the formation of a peroxyhydrate with a high hydrogen peroxide content, of the composition Rb₂CO₃ · 6H₂O₂.     

Copper(II) catalyzed cross-dehydrogenative coupling of cyclic benzylic ethers with simple carbonyl compounds by Na2S2O8

Copper(II) catalyzed cross-dehydrogenative coupling of cyclic benzylic ethers with a variety of simple carbonyl compounds mediated by Na₂S₂O₈ is developed. The scope of carbonyl components is broad, including simple aldehydes as well as ketones. The use of Na₂S₂O₈ as the oxidant for the CDC reaction is attractive based on economical and environmental factors.     

Fast Oxygen Reduction Catalyzed by a Copper(II) Tris(2‐pyridylmethyl)amine Complex through a Stepwise Mechanism

Catalytic pathways for the reduction of dioxygen can either lead to the formation of water or peroxide as the reaction product. We demonstrate that the electrocatalytic reduction of O₂ by the pyridylalkylamine copper complex [Cu(tmpa)(L)]²⁺ in a neutral aqueous solution follows a stepwise 4 e^?/4 H⁺ pathway, in which H₂O₂ is formed as a detectable intermediate and subsequently reduced to H₂O in two separate catalytic reactions. These homogeneous catalytic reactions are shown to be first order in catalyst. Coordination of O₂ to Cu^I was found to be the rate‐determining step in the formation of the peroxide intermediate. Furthermore, electrochemical studies of the reaction kinetics revealed a high turnover frequency of 1.5×10⁵ s^?1, the highest reported for any molecular copper catalyst.     

Phase Equilibria in the Systems Na+, K+||Cl--H2O and Na+, K+||Cl-, H2PO- 4-H2O at Temperatures of 0-100°C

Binary and ternary parameters of the Pitzer equation and also the thermodynamic potentials of solid phases and the solubility diagrams of ternary aqueous-salt systems Na⁺, K⁺||Cl^--H₂O and Na⁺, K⁺||Cl^-, H₂PO^- ₄-H₂O in the temperature range 0-100°C, which corresponds to the technological conditions of brine formation, were calculated.     

Kinetics of Hydrogen Peroxide Decomposition in Guaiacol Solution, Catalyzed by Hexacyanoferrate(II)

The kinetics of hydrogen peroxide decomposition in a guaiacol solution, catalyzed by potassium hexacyanoferrate(II), were studied. The reaction mainly follows the pathway of guaiacol hydroxylation. The reaction order is 1 with respect to H₂O₂, 0.5 with respect to hexacyanoferrate, and from 0.4 to 0 with respect to guaiacol (the latter parameter decreases with increasing guaiacol concentration). The apparent activation energy is 105 kJ mol^{- 1}. A kinetic scheme of the process was proposed. An expression consistent with the experiment was obtained for the rate of hydrogen peroxide decomposition in the presence of guaiacol, catalyzed by hexacyanoferrate(II).     

ChemInform Abstract: Cross Sections and Product Kinetic Energy Analysis of H2O+-H2O Collisions at Suprathermal Energies.

The H₂O⁺-H₂O reaction is studied at center-of-mass collision energies in the range 0.5-25 eV.     

Superoxide Anion Disproportionation Induced by Li+ and H+: Pathways to 1O2 Release in Li−O2 Batteries

We explore the disproportionation reaction of superoxide anions in the presence of H⁺ and Li⁺ cations with high quality multiconfigurational ab-initio methods. This reaction is of paramount importance in Li−O₂ battery chemistry as it represents the source of a major degrading impurity, singlet molecular oxygen. For the first time, the thermodynamic and kinetic data of the reaction are drawn from an accurate theoretical model where the electronic structure of the reactant and products is treated at the necessary level of theory. Overall, the H⁺ catalyzed O₂⁻+O₂⁻ disproportionation follows a very efficient thermodynamic and kinetic reaction path leading to neutral ³O₂, ¹O₂ and peroxide anions. On the contrary, we have found that the Li⁺ catalysis promotes only the release of ³O₂ whereas the ¹O₂ formation is energetically unfeasible at room temperature.     

Induced reaction within the peroxy-compounds

Summary The induced reaction occurring in the H₂O₂-H₂S₂O₈- KMnO₄ [and Ce(SO₄)₂, resp.,] system was studied in detail and established that it strongly depends on the experimental conditions such as rate of stirring, speed of titration, dilution of the solution, temperature, concentrations of partners of the reaction, acid concentration etc. It was found further that the induced disappearence of peroxydisulphate as well as of hydrogen peroxide is caused by HO₂ radicals formed during the primary reaction between hydrogen peroxide and 1-equivalent oxidants. The effect of foreign ions on the induced reaction was also interpreted.

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Zusammenfassung Die induzierte Reaktion im System H₂O₂-H₂S₂O₈-KMnO₄ bzw. Ce(SO₄)₂ wurde eingehend untersucht und gefunden, daß sie weitgehend von den Versuchsbedingungen abhängig ist (Rühr- und Titrier-geschwindigkeit, Verdünnungsgrad, Temperatur, Konzentration der Reaktionspartner, Säurekonzentration u. a.). Das Verschwinden von Peroxydisulfat und Wasserstoffperoxid bei der induzierten Reaktion wird durch HO₂-Radikale verursacht, die während der induzierenden Reaktion zwischen Wasserstoffperoxid und 1-äquivalenten Oxydations mitteln gebildet werden. Die Wirkung von Fremdionen auf die induzierte Reaktion wird ebenfalls erläutert.

     

Enzyme-catalyzed reaction of voltammetric enzyme-linked immunoassay system based on OAP as substrate

The o-aminophenol (OAP)-H_2O_2-horseradish peroxidase (HRP) voltammetric enzyme-linked immunoassay new system has extremely high sensitivity. HRP can be measured with a detection limit of 6.0×10~-(10) g/L and a linear range of 1.0×10~(-9)—4.0×10~(-6) g/L. The pure product of H_2O_2 oxidizing OAP catalyzed by HRP was prepared with chemical method. The enzyme-catalyzed reaction has been investigated with electroanalytical chemistry, UV/Vis spectrum, IR spectrum, ~(13)C NMR, ~1H NMR, mass spectrum, elemental analysis, etc. Under the selected enzyme-catalyzed reaction conditions, the oxidation product of OAP with H_2_O2 catalyzed by HRP is 2-aminophe-noxazine-3-one. The processes of the enzyme-catalyzed reaction and the electroreduction of the product of the enzymecatalyzed reaction have been described.     

Na5P3O10-Ca(OH)2-CO2-H2O体系纳米CaCO3的成核与生长

通过化学分析、SEM显微分析技术,结合Rosin-Ramiler概率统计理论,从介观层次研究Na5P3O10-Ca(OH)2-CO2-H2O体系纳米CaCO3的合成反应及其成核和生长过程。结果表明,Na5P3O10对Ca(OH)2的碳化反应具有抑制作用。随着[Na5P3O10]的增加,体系中CaCO3的成核速率B^0逐渐增大。在[Na5P3O10]＝0ppm时,CaCO3结晶的生长由长程扩散和凝聚生长控制;[Na5P3O10]=380.4,760.9ppm时,前期受短程扩散和界面反应控制、后期受长程扩散控制。Na5P3O10的存在,抑制了纳米CaCO3的晶体生长。     

PEG-400-H2O as a green and recyclable medium for asymmetric hydrogenations of aromatic ketones catalyzed by RuCl2(TPPTS)2-(S,S)-DPENDS

PEG-400-H₂O was found to be a green and recyclable reaction medium for asymmetric hydrogenations of aromatic ketones catalyzed by a ruthenium achiral monophosphine complex RuCl₂(TPPTS)₂ [TPPTS: P(m-C₆H₄SO₃Na)₃] modified by (S,S)-DPENDS [disodium salt of sulfonated (S,S)-1,2-diphenyl-1,2-ethylene-diamine]. The acetophenone product was obtained with 86.3% ee under the optimized conditions. The resulting products can be easily separated from the catalyst by extraction with n-hexane. The catalyst immobilized in PEG-400-H₂O not only exhibits excellent activity and enantioselectivity, but also can be recycled and reused several times without a loss of activity or enantioselectivity.     

Hot Electrons at Solid–Liquid Interfaces: A Large Chemoelectric Effect during the Catalytic Decomposition of Hydrogen Peroxide

The study of energy and charge transfer during chemical reactions on metals is of great importance for understanding the phenomena involved in heterogeneous catalysis. Despite extensive studies, very little is known about the nature of hot electrons generated at solid–liquid interfaces. Herein, we report remarkable results showing the detection of hot electrons as a chemicurrent generated at the solid–liquid interface during decomposition of hydrogen peroxide (H₂O₂) catalyzed on Schottky nanodiodes. The chemicurrent reflects the activity of the catalytic reaction and the state of the catalyst in real time. We show that the chemicurrent yield can reach values up to 10^?1 electrons/O₂ molecule, which is notably higher than that for solid–gas reactions on similar nanodiodes.     

Accelerated chemical degradation of polyacrylamide

The chemical degradation of polyacrylamide(PAM) at low temperature in aqueous medium was initiated by peroxides. The degradation degree of the polymer rose with the reaction time. The degradation degree of PAM depended not only on peroxide characteristic but also on the concentration of polyacrylamide and potassium persulfate, degradation temperature and original molecular weight of PAM. The results showed that the order of degradation degree of PAM in three peroxides is K₂S₂O₈ > K₂S₂O₈ — Na₂S₂O₃ > H₂O₂. The degradation degree of PAM grew as reaction temperature, molecular weight of PAM, concentration of potassium persulfate and PAM increased.