Study of the hydrazine and borohydride ions electro-oxidation reactions on nickel and cobalt based electrocatalysts in alkaline electrolyte

High hydrogen content compounds, such as hydrazine (N2H4) and borohydride ion (BH4-) exhibit high prospect as fuel for fuel cells or electrochemical reformers for hydrogen generation, since they present high energy density. Moreover, their electro-oxidation reactions can be catalyzed on non-noble electrocatalysts, such as Ni and Co, in alkaline electrolyte. In this way, this project aimed the synthesis and the investigation of the electro-catalytic activity of nickel, cobalt and nickel/platinum nanoparticles based electrocatalysts, named as NiO/C, Co3O4/C and NiO-Pt/C, for hydrazine and borohydride electro-oxidation reactions. Electrochemical results showed high electrocatalytic activity of Co3O4/C for both reactions, (hydrazine and borohydride electro-oxidation), however NiO/C showed more stability. For both NiO/C and or NiO-Pt/C, the experiments showed that under potentials slightly above the open-circuit potential, the electrocatalytic activity comes from the co-existence of Ni0, Pt0 and Ni-OH on the surface. The hydrazine electro-oxidation reaction is catalyzed by a bi-functional synergistic effect related to the Ni-H or Pt-H coupling generated from dissociative adsorption of hydrazine (or borohydride), and Ni-OH, produced by OH- discharge in low potentials. In high overpotentials, the faradaic currents increase significantly for both reactions. An electron-mediated mechanism is proposed for this condition, where the hydrazine or borohydride ions reduces chemically the nickel or cobalt oxide, producing the reaction products from these fuels and, this is followed by the metal electro-oxidation, induced by the high potential of the electrode, completing the mediation cycle. For all electrocatalysts (only hydrazine for NiO-Pt/C), online DEMS (Differential Electrochemical Mass Spectrometry) results showed that the faradaic currents keep up with by the generation of the main product, in low potentials (N2 for hydrazine and BO2- for borohydride, but this last one cannot be detected by DEMS). In high overpotentials, the main product signal is followed by the signals, with similar behavior, of H2 and NH3. This result evidences that the complete hydrazine and borohydride electro-oxidation reactions preferentially occur in low overpotentials, whereas, in high overpotentials, when the nickel or cobalt oxides are present, the reactions occurs preferentially by incomplete pathways, in an electron-mediated mechanism. (AU)