Catalytic oxidation of hydrogen on platinum

Using the thermochemical approach to interpret the kinetics of heterogeneous reactions and the mechanism of congruent dissociative decomposition of solids developed in the 1980s and (re)analyzing the experimental data available in the literature over the last 90 years, a novel mechanism for the catalytic oxidation of H₂ by PtO₂ is proposed. In place of the conventional Langmuir–Hinshelwood and Eley–Rideal adsorption reaction mechanisms, our model is based on the reactions: PtO₂(s) + 2H₂ ? Pt(g) + 2H₂O and Pt(g) + O₂ ? PtO₂(g) → PtO₂(s). The first reaction determines the kinetics of H₂ oxidation and the second determines the kinetics of restoration of the PtO₂ layer. Thermochemical consideration of kinetic features of this model enables (for first time in the history of this reaction) the enthalpy and equilibrium constants for H₂ oxidation on platinum to be calculated. The results are in good agreement with experimental data. In addition, the proposed mechanism explains the origin of the surface-retexturing effect, the impact of autocatalysis, the influence of H₂O vapor on oxidation rate, and the three-fold variation of the Arrhenius E parameter with temperature. This all convincingly demonstrates the value of the thermochemical approach in interpreting heterogeneous reactions.     

Correction to: Catalytic oxidation of hydrogen on platinum

Journal of Thermal Analysis and Calorimetry - Due to a fault (oversight) of the authors, L’vov BV, Galwey AK, in Fig 1 of the article: ‘Catalytic oxidation of hydrogen on...     

Low-temperature oxidation of polyethylene

To increase the surface energy of polyethylene (PE), the surface is subjected to oxidative treatment, such as chemical oxidation or Bunsen flame treatment. It is shown that oxidation of the polymer surface below 100° leads to increase in the contents of double bonds and of hydroxyl, carbonyl and carboxyl groups and also to branching of the molecules. Increase in the concentration of the polar groups causes increase in the surface free energy.     

Effect of cerium oxide on the activity of platinum catalysts of hydrogen and CO oxidation

Effective catalytic systems based on Pt/CeO₂-C were prepared. The use of a cerium oxide addition in the substrate stabilized the platinum catalysts against their poisoning with carbon monoxide at room temperature.     

Electrochemical absorption and oxidation of hydrogen on palladium alloys with platinum, gold and rhodium

Thin layers of Pd and its alloys with Pt, Au and Rh were prepared by electrodeposition on a Au substrate. Hydrogen electrosorption by the obtained electrodes was studied in 0.5 M H(2)SO(4) solution using cyclic voltammetry and chronoamperometry. The influence of the alloying process on selected thermodynamic (the amount of absorbed hydrogen, the stability of the β-phase, the extent of the absorption/desorption hysteresis) and kinetic aspects (the rate of hydrogen absorption and absorbed hydrogen oxidation) of hydrogen absorption and desorption was examined. It was found that the addition of the non-absorbing elements to Pd results in faster kinetics of the hydrogen electrosorption process and a smaller absorption/desorption hysteresis.     

Low-temperature adsorption of oxygen over platinum monocrystals

Adsorption of O₂ over Pt(111), (110) and (100) at 80 K has been studied by thermodesorption mass-spectrometry. The results indicate the formation of chemisorbed molecular oxygen species and the influence of the surface structure of platinum on the low-temperature adsorption of oxygen.

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- O₂ 80 Pt(111), (110), (100). . .

     

Catalytic oxidation of CO on platinum

Using concepts recently developed in thermal decompositions of solids and reduction of bulk oxides by gases and (re)analysis of experimental literature data, a novel mechanism for the catalytic oxidation of CO by PtO₂ is proposed. Instead of the conventional Mars–van Krevelen scheme, the reactions proposed are: PtO₂(s) + 2CO ? Pt(g) + 2CO₂ and Pt(g) + O₂ ? PtO₂(g) → PtO₂(s). The first reaction determines the kinetics of CO oxidation and the second determines the kinetics of restoration of the PtO₂ layer. Thermochemical consideration of the kinetic features of this model, based on Langmuir’s quasi-equilibrium equations for evaporation of simple substances, allowed calculation of the reaction enthalpy and the absolute rate of CO oxidation. These results are in good agreement with experimental data. The proposed mechanism explains the origin of the surface-retexturing effect, the limited loss of Pt metal from the catalyst, the mechanism of PtO₂ regeneration by oxygen, the strong effect of CO₂ in reducing the CO oxidation rate and the three-fold variation of the Arrhenius E parameter with temperature.     

Dispersed platinum supported by hydrogen molybdenum bronze-modified carbon as electrocatalyst for methanol oxidation

A new electrocatalyst, Pt/H_xMoO₃-C, for methanol oxidation, was prepared by dispersing platinum nano-particles on Vulcan XC-72 modified by hydrogen molybdenum bronze (H_xMoO₃, 0 ≤ x ≤ 2). The modification of Vulcan XC-72 with H_xMoO₃ on was accomplished by reducing the adsorbed molybdic acid and the platinum nano-particles were dispersed on the modified carbon by reducing chloroplatinic acid, with formaldehyde as the reductant. The prepared Pt/H_xMoO₃-C was characterized by X-ray diffraction (XRD), scanning electron microscopy (SEM), energy-dispersion spectrometer, cyclic voltammetry (CV), chronoamperometry (CA), and single-cell test, with a comparison of the electrocatalyst, carbon-supported platinum (Pt/C) prepared under the same condition but without the modification. The results obtained from XRD and SEM showed that the modification of Vulcan XC-72 with H_xMoO₃ reduced the platinum particle size and improved distribution uniformity of platinum on carbon. The results, obtained from CV, CA, and the single-cell test, showed that Pt/H_xMoO₃-C exhibited better electrocatalytic activity toward methanol oxidation than Pt/C.     

Electrocatalysis of oxygen reduction and hydrogen oxidation in platinum dispersed on tungsten carbide in acid medium

Tungsten carbide dispersed on a high surface area carbon (W₂C/C) prepared by a sonochemical method was used as the support of a Pt-based electrocatalyst (Pt-W₂C/C). The resulting materials were tested for two important reactions with practical interest in fuel cells, that is, the oxygen reduction and hydrogen oxidation reactions, in acid medium. The electrochemical techniques considered were cyclic voltammetry, linear sweep voltammetry, and steady-state polarization curves, obtained utilizing an ultrathin catalyst layer in a rotating ring–disk electrode. The results showed that the Pt-W₂C/C catalyst led to a remarkable enhancement of the oxygen reduction in acid medium, when compared to the standard Pt/C, both following a four-electron mechanism. The hydrogen oxidation reaction showed similar kinetics on Pt-W₂C/C and Pt/C following the direct discharge mechanism on both catalysts. The W₂C/C support presented remarkable activity for the hydrogen oxidation reaction, most probably after the Heyrovsky–Volmer mechanism at low overpotential and the direct discharge irreversible mechanism at high overpotentials. This paper is dedicated to Prof. Francisco Nart, in memoriam.     

Direct comparison of the electrocatalytic oxidation of hydrogen by an enzyme and a platinum catalyst

It is shown that for molecules of Allochromatium vinosum [NiFe]-hydrogenase adsorbed on a pyrolytic graphite electrode the nickel-iron active site catalyzes hydrogen oxidation at a diffusion-controlled rate matching that achieved by platinum.     

Low-temperature CO oxidation on iron oxide supported palladium

For small Pd particles on hematite support, specific catalytic activity in the reaction of low-temperature CO oxidation was found to be greatly enhanced indicating strong synergism. Possible reasons for this pnenomena such as CO and oxygen spillover and stabilization of the oxidized Pd forms due to support effect are considered.     

Kinetic model and mechanism of the selective oxidation of CO in the presence of hydrogen on platinum catalysts

The reaction kinetics of the selective oxidation of carbon monoxide in the presence of hydrogen on a Pt/carbon support catalyst was studied. It was found that this catalyst exhibited high activity and decreased the concentration of CO in a hydrogen-containing gas from 0.6–1.0 vol % to less than 10 ppm at the inlet concentration ratio O₂/CO = 1.0–1.5. A kinetic model of the reaction was proposed to describe quantitatively the experimental results.     

Low-temperature catalytic decomposition of N2O on platinum and bismuth-modified platinum: identification of active sites

Classification of the active surface sites of platinum catalysts responsible for low temperature N2O decomposition, in terms of steps, kinks and terraces, has been achieved by controlled addition of bismuth to as-received platinum/graphite catalysts.     

Temperature hysteresis in oxidation reactions on platinum

An interpretation of the temperature hysteresis observed in catalytic oxidation of various substances in the presence of platinum is suggested. This phenomenon and a heterogeneous mechanism are accounted for by the formation and decomposition of two-dimensional surface oxides of Pt.

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Influence of chemisorbed carbon monoxide on the oxidation of molecular hydrogen at smooth platinum in sulfuric acid solution

Potentiostatic current—potential curves of hydrogen oxidation were measured at 0.5 mV s^?1 on two smooth platinum electrodes of different shape in the presence of various coverages with chemisorbed carbon monoxide in 0.5 M H₂SO₄, stirred with molecular hydrogen at 1 cm³ s^?1. Carbon monoxide coverages up to 0.6 have a small influence. The hydrogen oxidation remains controlled by convective diffusion of molecular hydrogen. Above coverages of 0.6, a kinetic step becomes increasingly predominant. The effect of chemisorbed carbon monoxide on the H₂ oxidation is similar to that on hydrogen adsorption, studied previously. The correlation between the rate of the kinetic step and the free energy of hydrogen adsorption in the Temkin model of the surface is established and discussed.     

Kinetics of the homogeneous oxidation of hydrogen by platinum(II) and platinum(IV) chloro complexes in aqueous solution

The kinetics of the homogeneous oxidation of hydrogen in the Pt(II)–Pt(IV)–Cl^––H₂O system has been studied for the first time in conditions permitting to avoid the formation of Pt-black. It is shown that platinum (II) [Pt(II)Cl_i(H₂O)_4-i, where i=1, 2, 2], is active in the reaction, whereas the PtCl ₄ ^2– complex and platinum(IV) do not react with hydrogen.

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, Pt-, H₂ Pt^II–Pt^IV–Cl^––H₂O. (II) (Pt^IICl_i(H₂O)_4-i, i=1, 2, 3); PtCl ₄ ^2– (IV) .

     

Multi-electron oxidation of formaldehyde on a platinum electrode

The time evolution of a self-sustained potential oscillation under constant current oxidation of formaldehyde was observed on the rotating ring disk electrode assemble. Under the condition when the potential was controlled, the laser deflection voltammogram as well as the conventional cyclic voltammogram were measured. The mechanism of the multi-electron oxidationof formaldhyde on a platinum electode is discussed.     

Low-temperature oxidative chlorination of methane over supported platinum chloride catalyst

The Pt^II (catalyst)+Pt^IV (oxidant) system with a deficiency of Cl ligands is active in the oxidative chlorination of alkanes not only in aqueous solutions but also in the SiO₂-supported state. In heterogeneous as well as in homogeneous conditions, the reaction proceeds at 100°C through platinum-alkyl intermediates.

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: Pt^II- Pt^IV- Cl-, , SiO₂. , , 100° - .