Surface Entropy-Reduction Tailored Few-Atom Layer Metal on High-Entropy Alloy for Tandem Electrocatalytic Nitrate Reduction to Ammonia
Lixue Zhou, Daming Feng, Zhiqiang Li, Zengshuai Lv, Hui Li, Chunhua Ge, Xiangdong Zhang, Tianyi Ma
Abstract
To kill two birds in one stone, electrocatalytic reduction of nitrate (NO 3 – ) offers a mild and reliable approach for wastewater denitrification and a green pathway for ammonia (NH 3 ) production. Despite the complex proton-coupled electron transfer process in NO 3 – reduction, efficient NH 3 production has been challenging. In this study, high-entropy multivalent chalcogenides (HEMCs) were synthesized, exhibiting a synergistic catalytic effect for enhanced electrochemical performance. The highest Faraday efficiency of 92.3% and NH 3 yield rate of 5.67 mg h –1 cm –2 were achieved at −0.6 and −0.8 V versus reversible hydrogen electrode (V vs RHE) under the catalysis of HEMC with Fe, Cu, Co, Cr, Zr, Ni, and Bi (molar ratio 1:1:1:1:1:1:1), denoted as F3CZNB. Comparatively, senary and quinary HEMCs, namely, F3CZN and F3CZ, were also synthesized. Characterization and catalytic performance analyses revealed that Fe and Cu primarily contributed to the catalytic activity, while NH 3 selectivity and electrode stability were attributed to the stoichiometric composition of the metals. Ni further enhanced conversion of NO 3 – to NH 3 by its hydrophilicity, and Bi improved conductivity and durability with d-p interaction with transition metals. The NO 3 – reduction reaction pathway was confirmed by detecting intermediates (*NO 2, *NO, *NH 2 OH, *NH 2, and *NH) on the catalyst surface using in situ Fourier transform infrared spectroscopy (in situ FT-IR) and electrochemical differential mass spectrometry (DEMS). A Zn–NO 3 – battery assembled with F3CZNB demonstrated an energy density of 6.45 mW cm –2, highlighting the potential of F3CZNB for energy conversion devices. This study sheds light on a novel protocol for synthesizing multivalent chalcogenides with potent electrocatalytic activity.