Reaction Selectivity Improvement for Reduction of Nitrobenzene in a Packed-Bed Electrode Reactor under Periodic-Current Control

Rectangular wave current control of the electrochemical reduction of nitrobenzene im-proves the selectivity for p-aminophenol(PAP) compared to direct current(d.c.) control at thesame average current density in a flow-by packed-bed reactor.Optimal increase in PAP selectivitycan be obtained at about a frequency of 50Hz and a duty cycle of 0.2.A mathematical model isset up to incorporate the effects of mass transfer,hydrogen evolution and double layer charging,and is solved using the Duhamel's superposition principle and the modified Crank-Nicolson methodwith the upwind scheme.The conventional d.c.control cases are also calculated for comparison.Calculations can be applied to predict the reaction results under periodic current and d.c.control,but both display the same trends compared to experimental data.

Reaction Selectivity Improvement for Reduction of Nitrobenzene in a Packed-Bed Electrode Reactor under Periodic-Current Control

Rectangular wave current control of the electrochemical reduction of nitrobenzene improves the selectivity for p-aminophenol (PAP) compared to direct current (d.c.) control at the same average current density in a flow-by packed-bed reactor. Optimal increase in PAP selectivity can be obtained at about a frequency of 50 Hz and a duty cycle of 0.2. A mathematical model is set up to incorporate the effects of mass transfer, hydrogen evolution and double layer charging, and is solved using the Duhamel's superposition principle and the modified Crank-Nicolson method with the upwind scheme. The conventional d.c. control cases are also calculated for comparison. Calculations can be applied to predict the reaction results under periodic current and d.c. control, but both display the same trends compared to experimental data.