Plasma-catalyst hybrid methanol-steam reforming for hydrogen production

Plasma-catalytic methanol-steam reforming was investigated in the present study. A tubular quartz reactor with annular-shaped electrodes was used, in which Cu/ZnO catalysts supported on Al2O3 pellets were packed. Non-thermal plasma on the catalyst was generated by an electric discharge. The effect of the temperature, feeding rate, voltage, frequency, and waveform on methanol conversion was investigated. The methanol conversion under the electric discharge increased as the discharge voltage and frequency increased. Square waveform was more effective in methanol conversion than the sine waveform. The electric discharge provided the sufficient energy to break chemical bonds of methanol and steam. Moreover, the strong electric field increased absorption intensities of reactants on the active sites of the catalyst surface.