Jamie L. Cohen scite author profile

The oxidation pathways of methanol (MeOH) have been the subject of intense research due to its possible application as a liquid fuel in polyelectrolyte membrane (PEM) fuel cells. The design of improved catalysts for MeOH oxidation requires a deep understanding of these complex oxidation pathways. This paper will provide a discussion of the literature concerning the extensive research carried out in acidic and alkaline electrolytes. It will highlight techniques that have proven useful in the determination of product ratios, analysis of surface poisoning, anion adsorption, and oxide formation processes, in addition to the effects of temperature on the MeOH oxidation pathways at bulk polycrystalline platinum (Pt(poly)) electrodes. This discussion will provide a framework with which to begin the analysis of activation energy (E(a)) values. This kinetic parameter may prove useful in characterizing the rate-limiting step of the MeOH oxidation at an electrode surface. This paper will present a procedure for the determination of E(a) values for MeOH oxidation at a Pt(poly) electrode in acidic and alkaline media. Values from 24-76 kJ mol(-1) in acidic media and from 36-86 kJ mol(-1) in alkaline media were calculated and found to be a function of applied potential and direction of the potential sweep in a voltammetric experiment. Factors that influence the magnitude of the calculated E(a) include surface poisoning from MeOH oxidation intermediates, anion adsorption from the electrolyte, pH effects, and oxide formation processes. These factors are all potential, and temperature, dependent and must clearly be addressed when citing E(a) values in the literature. Comparison of E(a) values must be between systems of comparable electrochemical environment and at the same potential. E(a) values obtained on bulk Pt(poly), compared with other catalysts, may give insight into the superiority of other Pt-based catalysts for MeOH oxidation and lead to the development of new catalysts which lower the E(a) barrier at a given potential, thus driving MeOH oxidation to completion.

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Rotating Disk Electrode (RDE) Investigation of BH₄⁻ and BH₃OH⁻ Electro-oxidation at Pt and Au: Implications for BH₄⁻ Fuel Cells

Finkelstein

et al. 2009

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We present a thorough electrochemical study of the mechanism of borohydride oxidation on gold and platinum surfaces via cyclic voltammetry and rotating disk and ring-disk electrode voltammetry. We have paid particularly close attention to the number of electrons transferred (from a theoretical maximum of 8e -), values of the heterogeneous charge transfer rate constant (k b ), the presence of coupled chemical reactions, and adsorbed intermediates. We find that the nature of the electrode (Pt, Au) plays an important role in all of these processes and we present a detailed mechanistic analysis in light of the above-mentioned results. Our study suggests that Pt will significantly outperform Au for a direct borohydride fuel cell, providing similar electron recovery at much lower anode potentials.

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Fabrication and preliminary testing of a planar membraneless microchannel fuel cell

Cohen

Westly

Pechenik

et al. 2005

Journal of Power Sources

164

122

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A Dual Electrolyte H₂/O₂ Planar Membraneless Microchannel Fuel Cell System with Open Circuit Potentials in Excess of 1.4 V

et al. 2005

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A dual electrolyte H2/O2 fuel cell system employing a planar microfluidic membraneless fuel cell has been investigated and compared to single electrolyte H2/O2 systems under analogous conditions. The fuel is H2 dissolved in 0.1 M KOH (pH 13), and the oxidant is O2 dissolved in 0.1 M H2SO4 (pH 0.9), comprising a system with a calculated thermodynamic potential of 1.943 V (when 1 M H2 and O2 concentrations are assumed). This value is well above the calculated thermodynamic maximum of 1.229 V for an acid, or alkaline, single electrolyte H2/O2 fuel cell. Experimentally, open-circuit potentials in excess of 1.4 V have been achieved with the dual electrolyte system. This is a 500 mV increase in the open circuit potentials observed for single electrolyte H2/O2 systems also studied. The dual electrolyte fuel cell system shows power generation of 0.6 mW/cm2 from a single device, which is nearly 0.25 mW/cm2)greater than the values obtained for single electrolyte H2/O2 fuel cell systems studied. Microchannels of varying dimensions have been employed to study both the single and dual electrolyte H2/O2 systems. Channel thickness variation and the flow rate dependences of power generation are also addressed.

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Synthesis, Characterization, and Intervalence Charge Transfer Properties of a Series of Rhenium(I)−Iron(III) Mixed-Valence Compounds

et al. 1999

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A series of cyanide-bridged mixed-valence compounds of the form {[dmbReI(CO)3] n -FeIII(CN)6}3- n were synthesized, and their MM‘CT absorptions were modeled using Marcus−Hush theory. The hypsochromic shift of the MM‘CT bands with increasing n is due to the increase in the redox potential of the Fe(III) center as more Re(I) species are bridged to it. The single-crystal X-ray structure of the 3:1 (Re/Fe) species was also determined, and a solvent dependence was performed.

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Jamie L. Cohen

Electrochemical determination of activation energies for methanol oxidation on polycrystalline platinum in acidic and alkaline electrolytes

Rotating Disk Electrode (RDE) Investigation of BH₄⁻ and BH₃OH⁻ Electro-oxidation at Pt and Au: Implications for BH₄⁻ Fuel Cells

Fabrication and preliminary testing of a planar membraneless microchannel fuel cell

A Dual Electrolyte H₂/O₂ Planar Membraneless Microchannel Fuel Cell System with Open Circuit Potentials in Excess of 1.4 V

Synthesis, Characterization, and Intervalence Charge Transfer Properties of a Series of Rhenium(I)−Iron(III) Mixed-Valence Compounds

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Jamie L. Cohen

Electrochemical determination of activation energies for methanol oxidation on polycrystalline platinum in acidic and alkaline electrolytes

Rotating Disk Electrode (RDE) Investigation of BH4− and BH3OH− Electro-oxidation at Pt and Au: Implications for BH4− Fuel Cells

Fabrication and preliminary testing of a planar membraneless microchannel fuel cell

A Dual Electrolyte H2/O2 Planar Membraneless Microchannel Fuel Cell System with Open Circuit Potentials in Excess of 1.4 V

Synthesis, Characterization, and Intervalence Charge Transfer Properties of a Series of Rhenium(I)−Iron(III) Mixed-Valence Compounds

Contact Info

Product

Resources

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Rotating Disk Electrode (RDE) Investigation of BH₄⁻ and BH₃OH⁻ Electro-oxidation at Pt and Au: Implications for BH₄⁻ Fuel Cells

A Dual Electrolyte H₂/O₂ Planar Membraneless Microchannel Fuel Cell System with Open Circuit Potentials in Excess of 1.4 V