Metal‐Organic Frameworks‐Derived Nickel–Iron Oxyhydroxide with Highly Active Edge Sites for Electrochemical Oxygen Evolution

Lan, Bi‐Liu; Lei, Lei; Yang, Fu-Jie; Pang, Wei; Guo, Zeping; Meng, Ting; Zhang, Zhong; Huang, Jin

doi:10.1002/sstr.202200085

Cited by 4 publications

(1 citation statement)

References 67 publications

(85 reference statements)

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“…Even with the high priority given to environmental issues, the HB process is still running and has long been considered for a century due to the irreplaceable role of ammonia . However, electrification of the chemical industry is the future trend of carbon emission reduction with the development of renewable energy. − …”

Section: Introductionmentioning

confidence: 99%

Li–N₂ Battery for Ammonia Synthesis and Computational Insight

Zhou

et al. 2023

ACS Appl. Mater. Interfaces

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Electrochemical synthesis of ammonia is deemed as an alternative to the fossil-fuel-driven Haber–Bosch (HB) process, in which Li-mediated nitrogen reduction (LiNR) is the most promising scheme. Continuous lithium-mediated nitrogen reduction for ammonia synthesis (C-LiNR) has recently been reported in high-level journals with many foggy internal reactions. Synthesizing ammonia in a separate way may be profitable for understanding the mechanism of LiNR. Herein, an intermittent lithium-mediated nitrogen reduction for ammonia synthesis (I-LiNR) was proposed, three steps required for I-LiNR were achieved in the cathode chamber of a Li–N2 battery. Discharge, stand, and charge in the Li–N2 battery correspond to N2 lithification, protonation, and lithium regeneration, respectively. It can also realize the quasi-continuous process with practical significance because it could be carried out through identical batteries. Products such as Li3N, LiOH, and NH3 are detected experimentally, which demonstrate a definite reaction pathway. The mechanism of the Li–N2 battery, the Li-mediated synthesis of ammonia, and LiOH decomposition are explored through density functional theory calculations. The role of Li in dinitrogen activation is highlighted. It expands the range of LiOH-based Li–air batteries and may guide the study from Li–air to Li–N2; attention has been given to the reaction mechanism of Li-mediated nitrogen reduction. The challenges and opportunities of the procedure are discussed in the end.

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Section: Introductionmentioning

confidence: 99%

Li–N₂ Battery for Ammonia Synthesis and Computational Insight

Zhou

et al. 2023

ACS Appl. Mater. Interfaces

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Mechanistic Analysis of Urea Electrooxidation Pathways: Key to Rational Catalyst Design

Medvedev,

Delva,

Klinkova

2024

ChemPlusChem

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Urea electrolysis is an emerging approach to treating urea‐enriched wastewater and an attractive alternative anodic process to the oxygen evolution reaction (OER) in electrochemical clean energy conversion and storage technologies (e.g., hydrogen production and CO2 electroreduction). While the thermodynamic potential for urea oxidation to dinitrogen is quite low compared to that of the OER, the catalysts reported to date require high overpotentials that far exceed those for the OER. Consequently, there is much room for improvement and rational catalyst design for the urea oxidation reaction (UOR). At the same time, due to the urea molecule having a more complex structure than water, UOR can lead to the formation of various products beyond the commonly assumed N2 and CO2. This concept article will critically assess recent efforts of the research community to decipher the formation mechanisms of UOR products focusing on the systematic analysis of the reaction selectivity. This work aims to analyze the current state of the art and identify existing gaps, providing an outlook for the future design of UOR catalysts with superior activity and selectivity by applying the knowledge of the molecular transformation mechanisms.

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Confined growth of Ultrathin, nanometer-sized FeOOH/CoP heterojunction nanosheet arrays as efficient self-supported electrode for oxygen evolution reaction

Lu,

Li,

Bao

et al. 2024

Journal of Colloid and Interface Science

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Metal‐Organic Frameworks‐Derived Nickel–Iron Oxyhydroxide with Highly Active Edge Sites for Electrochemical Oxygen Evolution

Cited by 4 publications

References 67 publications

Li–N₂ Battery for Ammonia Synthesis and Computational Insight

Li–N₂ Battery for Ammonia Synthesis and Computational Insight

Mechanistic Analysis of Urea Electrooxidation Pathways: Key to Rational Catalyst Design

Confined growth of Ultrathin, nanometer-sized FeOOH/CoP heterojunction nanosheet arrays as efficient self-supported electrode for oxygen evolution reaction

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Metal‐Organic Frameworks‐Derived Nickel–Iron Oxyhydroxide with Highly Active Edge Sites for Electrochemical Oxygen Evolution

Cited by 4 publications

References 67 publications

Li–N2 Battery for Ammonia Synthesis and Computational Insight

Li–N2 Battery for Ammonia Synthesis and Computational Insight

Mechanistic Analysis of Urea Electrooxidation Pathways: Key to Rational Catalyst Design

Confined growth of Ultrathin, nanometer-sized FeOOH/CoP heterojunction nanosheet arrays as efficient self-supported electrode for oxygen evolution reaction

Contact Info

Product

Resources

About

Li–N₂ Battery for Ammonia Synthesis and Computational Insight

Li–N₂ Battery for Ammonia Synthesis and Computational Insight