Titanium Nitride Nanorods Array‐Decorated Graphite Felt as Highly Efficient Negative Electrode for Iron–Chromium Redox Flow Battery

Abstract

AbstractIron‐chromium redox flow batteries have attracted widespread attention because of their low cost. However, the performance of these batteries is still lower than that of vanadium redox flow batteries due to the poor electrochemical activity of Cr3+/Cr2+ redox couples on graphite felt electrodes. Herein, binder‐free TiN nanorods array—decorated 3D graphite felt composite electrode—is demonstrated. The dendrite‐like TiN nanorods array increases the specific surface area of the electrode. The nitrogen and oxygen elements on the surface provide more adsorption sites and electrochemically active sites for Cr3+/Cr2+. The contact resistance of the composite electrode is effectively reduced and its homogeneity and stability are improved by avoiding the use of a binder and mixing process. A battery prepared using the TiN nanorods array‐decorated 3D graphite felt electrode has enabled the maximum power density to be 427 mW·cm‐2, which is 74.0% higher than a battery assembled with TiN nanoparticles bonded to graphite felt. At a current density of 80 mA·cm‐2, the TiN nanorods battery exhibits the highest coulombic efficiency of 93.0%, voltage efficiency of 90.4%, and energy efficiency of 84.1%. Moreover, the battery efficiency and composite electrode structure remains stable during a redox flow battery cycle test.