Recent Progress in Layered Double Hydroxide‐Based Electrocatalyst for Hydrogen Evolution Reaction

Abstract Hydrogen energy is considered as promising renewable resource and desirable alternative to fossil fuels for future energy supply. Hydrogen production from electrocatalytic water splitting is a green and key approach for hydrogen energy development and application, and the effective electrocatalysts for hydrogen evolution reaction (HER) with low cost is the focus of ongoing research. Currently, noble metals‐based materials are the most effective and durable electrocatalysts for HER, while the high cost and low reserves greatly hinder their commercial applications. Recently, layered double hydroxides (LDHs) with interesting properties, such as the tunability of metal cation and interlayer anions, the adjustability of the thickness and spacing for the layers, low cost, and memory effect, have emerged as excellent electrocatalysts to enhance HER performance. Herein, the principal mechanisms and some key parameters for HER are firstly briefly introduced. Afterwards, the structural features and characteristics of LDHs are provided, and the typical design strategies to improve the HER activity of binary and ternary LDHs‐based catalysts are analyzed and discussed. In addition, the relationship between the morphology, structure, composition and involved electronic effects are focused and emphasized. Finally, the challenges and prospects of LDHs‐based catalysts for enhanced HER performance are proposed.