The development of a facile method to construct a high-performance electrode is of paramount importance to the application of alkaline water electrolysis. Here, we report that the activity of nickel foam (NF) toward...The development of a facile method to construct a high-performance electrode is of paramount importance to the application of alkaline water electrolysis. Here, we report that the activity of nickel foam (NF) towards the oxygen evolution reaction (OER) can be enhanced remarkably through simple immersion in a ferric nitrate (Fe(NOs)s) solution at room temperature. During this immersion process, the oxidation of the NF surface by NOs- ions increases the near-surface concentrations of OH- and Ni2+, which results in the in situ deposition of a highly active amorphous Ni-Fe hydroxide (a-NiFeOxHy) layer. Specifically the OER overpotential of the NF electrode decreases from 371 mV (bare NF) to 270 mV (@10 mA-cm-2 in 0.1 M KOH) after immersion in a 20 mM Fe(NOs)s solution for just I min. A longer immersion time results in further increased OER activity (196 mV@10 mA,cm-2 in 1 M KOH). The overall water splitting properties of the a-NiFeOxHy@NF electrode were evaluated using a two-electrode configuration. It is worth noting that the current density can reach 25 mA.cm-2 in 6 M KOH at an applied voltage of 1.5 V at room temperature.展开更多
文摘The development of a facile method to construct a high-performance electrode is of paramount importance to the application of alkaline water electrolysis. Here, we report that the activity of nickel foam (NF) towards the oxygen evolution reaction (OER) can be enhanced remarkably through simple immersion in a ferric nitrate (Fe(NOs)s) solution at room temperature. During this immersion process, the oxidation of the NF surface by NOs- ions increases the near-surface concentrations of OH- and Ni2+, which results in the in situ deposition of a highly active amorphous Ni-Fe hydroxide (a-NiFeOxHy) layer. Specifically the OER overpotential of the NF electrode decreases from 371 mV (bare NF) to 270 mV (@10 mA-cm-2 in 0.1 M KOH) after immersion in a 20 mM Fe(NOs)s solution for just I min. A longer immersion time results in further increased OER activity (196 mV@10 mA,cm-2 in 1 M KOH). The overall water splitting properties of the a-NiFeOxHy@NF electrode were evaluated using a two-electrode configuration. It is worth noting that the current density can reach 25 mA.cm-2 in 6 M KOH at an applied voltage of 1.5 V at room temperature.
