Piotr J. Barczuk

Enhancement of the Electrocatalytic Oxidation of Methanol at Pt ∕ Ru Nanoparticles Immobilized in Different WO3 Matrices

The importance of morphology and electrochemical characteristics of tungsten oxide as a support for the catalytic platinum/ ruthenium nanoparticles during electro-oxidation of methanol in acid medium is addressed here. Bimetallic Pt/Ru nanoparticles were immobilized at the same loadings in three different WO 3 matrices. Application of high voltages (up to 40 V at 1 V s -1 ) to tungsten foil in H 2 SO 4 solution containing a small amount of NaF (0.15 wt %) resulted in the formation of highly ordered nanoporous WO 3 . Compact tungsten oxide was produced by application of high voltages to tungsten foil in the absence of NaF. Parallel measurements were done with conventional thin films of microporous tungsten oxide electrodeposited on a glassy carbon substrate from the colloidal Na 2 WO 4 solution in H 2 SO 4 . While redox reactions of the structures generated by high voltage anodization were characteristic of poorly hydrated WO 3 (that could be reduced partially to substoichiometric oxides, WO 3-v ), the conventionally electrodeposited microporous structures behaved more like hydrated WO 3 (that could be reduced to nonstoichiometric hydrogen bronzes, H x WO 3 ). Contrary to compact structures (that were blocking Pt/Ru reactivity), both ordered nanoporous and electrodeposited microporous WO 3 matrices, that were more open and characterized by high surface areas, significantly enhanced the electrocatalytic (chronoamperometric, voltammetric) currents for methanol oxidation. Among important advantages of the system produced by assembling Pt/Ru in nanoporous WO 3 are its rigidity, long-term stability, and the ability to oxidize methanol at less positive potentials.

Visible Light-Driven Photoelectrochemical Conversion of the By-Products of the Ethanol Fuel Cell into Hydrogen

Because of its low chemical conversion efficiency, the direct ethanol fuel cell forms about 90% of partial oxidation by-products, acetic acid and acetaldehyde. Here, we describe a method allowing one to use these environmentally undesirable species to produce hydrogen. The described visible light-driven photoelectrochemical device employs a mesoporous tungsten trioxide, WO 3 , photoanode able to efficiently oxidize CH 3 COOH and CH 3 CHO, and a hydrogen-producing metal cathode. With its bandgap energy of 2.5 eV, the WO 3 film photoanode absorbs blue-green portions of the electromagnetic spectrum up to 500 nm.

Development of Multifunctional Catalysts for Electrooxidation of Organic Fuels

This article reports on comprehensive studies of electrooxidation of methyl formate at different catalysts. The influence of the nanostructured palladium on the catalytic properties of platinum and platinum-ruthenium commercial nanoparticles towards electrooxidation of methyl formate is studied. All results are related to the electrooxidation process of formic acid and methanol at the same catalysts.