Role of Pd in the Electrochemical Hydrogenation of Nitrobenzene Using CuPd Electrodes

Interest in the electrochemical reduction of organic compounds as an alternative to hydrogen electrosynthesis is driven, among other reasons, by the fact that the products obtained in this process may have more economic value than H-2. Furthermore, the technique, coupled with renewable sources of electricity, may open the door for large volume green chemical synthesis. In the present article, the electrochemical reduction and hydrogenation of nitrobenzene to aniline at neutral pH is focused upon, using copper electrodes with and without palladium decoration. Both electrodes present good activity, with a decrease in the overpotential for nitrobenzene reduction and the competing hydrogen evolution reaction when Pd is deposited in the surface of the Cu electrode. It is observed that the rate and selectivity of nitrobenzene reduction to aniline improves at high concentrations, obtaining yields close to 70% for 30 x 10(-3) M initial concentrations of nitrobenzene when using Pd decorated Cu electrodes. Impedance spectroscopy analysis reveals that the role of Pd in the decorated electrodes is to enhance the production of H* radicals, necessary for the nitrobenzene reduction process. This explains the increase in the selectivity toward aniline production by the incorporation of small amounts of Pd in the surface of the Cu electrode.

Automated summary

This article focuses on the electrochemical reduction and hydrogenation of nitrobenzene to aniline using Cu/Pd electrodes. The study found that the deposition of Pd on the surface of the Cu electrode can decrease the overpotential for nitrobenzene reduction and improve the rate and selectivity of aniline production. Impedance spectroscopy analysis indicates that Pd enhances the production of H* radicals, which are necessary for the nitrobenzene reduction process.