Cationic defect-enriched hydroxides as anodic catalysts for efficient seawater electrolysis

• Published in: Inorganic chemistry frontiers Vol. 1; no. 8; pp. 2444 - 2456
• Main Authors: Wu, Yi-jin, Zheng, Jian-zhong, Zhou, Xiao, Tu, Teng-xiu, Liu, Yangyang, Zhang, Peng-fang, Tan, Liang, Zhao, Shenlong
• Format: Journal Article
• Language: English
• Published: London Royal Society of Chemistry 11.04.2023
• Subjects: Anodic cleaning; Cations; Charge transfer; Chloride ions; Chlorine; Defects; Density functional theory; Electrocatalysts; Electrochemical corrosion; Electrode materials; Electrolysis; Energy sources; Hydroxides; Inorganic chemistry; Intermetallic compounds; Iron; Iron compounds; Metal air batteries; Nickel compounds; Open circuit voltage; Oxygen evolution reactions; Rechargeable batteries; Seawater; Zinc-oxygen batteries
• ISSN: 2052-1553; 2052-1545; 2052-1553
• DOI: 10.1039/d3qi00026e

Seawater electrocatalysis driven by renewable energy resources has long been considered as a promising approach for producing clean hydrogen. However, anodic electrode materials suffer from severe issues such as large overpotential and electrochemical corrosion during seawater electrolysis due to the existence of abundant chloride ions. Herein, we report a cationic defect engineering approach to tailoring the structure of NiFe layered double hydroxide (NiFe LDH) for the oxygen evolution reaction (OER) in an alkaline seawater-like solution. Impressively, the obtained cation defect-enriched NiFe LDH array exhibits an extremely low overpotential of 232 mV at 100 mA cm −2 and excellent durability after 40 h electrolysis. The density functional theory (DFT) calculations show that CD-NiFe LDH-E facilitates charge transfer between metals (Ni/Fe) and oxygen (O), leading to inhibition of the competitive chlorine evolution reaction (CER). Moreover, homemade rechargeable Zn-air batteries with CD-NiFe LDH-E as the cathode are assembled, exhibiting high open circuit voltage (1.4 V) and excellent stability after 250 hours at a charging-discharging rate of 10 mA cm −2 . The strategy is expected to pave the way for the future development of high-performance electrocatalysts toward seawater splitting. A porous NiFe LDH with abundant cationic defects was synthesized to optimize interactions between active Ni species and adsorbates, exhibiting a highly efficient seawater electrolysis performance.