Magnetic Field Enhancing the Electrocatalytic Oxygen Evolution Reaction of FeMn-Based Spinel Oxides
Yuan Yuan, Zhiqiang Jiang, Minjie Li, Kun Peng
Abstract
For the widespread application of electrolytic water hydrogen production technology, it is crucial to prepare electrolytic water catalysts via inexpensive and abundant transition metals. Commercially, Mn 3 O 4 can be utilized extensively since it is cheap, abundant, and stable, but its electrocatalytic performance still needs to be enhanced. In this paper, we adopted the conventional hydrothermal method to introduce Fe atoms into Mn 3 O 4 to form spinel-structured FeMn oxides on Ni foam (marked as Fe x Mn 3– x O 4 ); then, an external magnetic field was applied to further improve its oxygen evolution reaction (OER) performance. The overpotential of FeMn 2 O 4 is 258 mV (current density at 20 mA·cm –2 ), and the Tafel slope is 28.7 mV·dec –1 when the magnetic field strength is 105 mT and the angle between the electric field and the magnetic field is 45°. The introduction of Fe and the synergistic effect of the mixed Mn and Fe promote the reaction kinetics and thus improve the OER performance of Mn 3 O 4 . The enhanced performance of Fe x Mn 3– x O 4 under the magnetic field may mainly originate from the magnetohydrodynamic (MHD) effect, charge transfer effect, and energy effect.