Electron Sponge Effect by Dynamic-Regulated Electron Self-Flow toward Coupled Electrochemical Ammonia Synthesis
Jian-Jia Mu, Xuan‐Wen Gao, Zhiwei Zhao, Zhao-Meng Liu, Qinfen Gu, Wen Luo
Abstract
A dynamic-regulated Pd–Fe–N electrocatalyst was effectively constructed with electron-donating and back-donating effects, which serves as an efficient engineering strategy to optimize the electrocatalytic activity. The designed PdFe 3 /FeN features a comprehensive electrocatalytic performance toward the nitrogen reduction reaction (NRR, yield rate of 29.94 μg h –1 mg cat –1 and FE of 38.43% at −0.2 V vs RHE) and oxygen evolution reaction (OER, 308 mV at 100 mA cm –2 ). Combining in situ ATR-FTIR, XAS, and DFT results, the role of the interstitial-N-dopant-induced electron sponge effect has been significantly elucidated in strengthening the electrocatalytic NRR process. Specifically, the introduction of a N dopant, an electron acceptor, initiates the generation of robust Lewis-acidic Fe sites, facilitating free N 2 capture and bonding. Simultaneously, after NH 3 adsorption, the N dopant can back-donate electrons to Fe sites, strengthening the NH 3 deportation through weakening the Lewis acidity of Fe centers. Besides, the electron-deficient Fe sites contribute to the reconstruction of FeOOH, the real active species during the OER, which accelerates the four-electron reaction kinetics. This research offers a perspective on electrocatalyst design, potentially facilitating the evolution of advanced material engineering for efficient electrocatalytic synthesis and energy storage.