Design of material regulatory mechanism for electrocatalytic converting NO/NO3−to NH3progress

Lu, Guolong; Gao, Sanshuang; Liu, Qian; Zhang, Shusheng; Luo, Jun; Liu, Xijun

doi:10.1002/ntls.20220047

Cited by 17 publications

(4 citation statements)

References 222 publications

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“…22 Matching the rates of adsorption and activation of NO and CO 2 on the active site is the key to catalysts with NO as the N source. 23 These small nitrogenous molecules (NO 3 − , NO 2 − , NO) are typically regarded as N-containing contamination in industry, but efficient strategies to remove and utilize them have not been explored. Utilizing these N sources directly can mitigate environmental pollution and promote the nitrogen neutrality cycle.…”

Section: Discussionmentioning

confidence: 99%

Catalysts for C–N coupling in urea electrosynthesis under ambient conditions from carbon dioxide and nitrogenous species

Yang,

Zhang

et al. 2024

Chem. Commun.

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Section: Discussionmentioning

confidence: 99%

Catalysts for C–N coupling in urea electrosynthesis under ambient conditions from carbon dioxide and nitrogenous species

Yang,

Zhang

et al. 2024

Chem. Commun.

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“…To date, various materials have been explored for the electrocatalytic NORR from both experimental and theoretical perspectives, such as noble metals, alloys, metal oxides and single-atom catalysts (SACs) . Among these materials, SACs have been recognized as promising candidates, spanning beyond NORR to encompass a wide range of electrocatalytic reactions such as ORR, OER, and CO 2 RR .…”

Section: Introductionmentioning

confidence: 99%

Theoretical Insights into the Selective Electrocatalytic Reduction of NO to NH₃ on a Two-Dimensional Cu-Benzylthiol Metal–Organic Framework Nanostructure

Yin,

Gong,

Lyu

et al. 2024

ACS Appl. Nano Mater.

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The electrocatalytic NO reduction reaction (NORR) is recognized as an appealing approach for NO removal, concurrently offering NH 3 synthesis potential. To achieve the selective catalytic reduction of NO, the development of high-performance catalysts is crucial. In this study, we systematically investigate the reaction mechanism, product selectivity, and influence of solvent effect of electrocatalytic NORR using a 2D Cubenzylthiol (Cu-BHT) metal−organic framework monolayer nanostructure through density functional theory (DFT) calculations. The investigation reveals that the NORR prefers the Mixed-2 pathway on the Cu-BHT monolayer nanostructure surface, marked by its complete exothermicity and a low activation barrier of only 0.32 eV. In addition, the Cu-BHT monolayer nanostructure exhibits a remarkable selectivity for the NORR, favoring NH 3 production over N 2 , N 2 O, and H 2 . Comparative analysis with the existing literature solidifies the excellence of the Cu-BHT monolayer nanostructure as a superior NORR electrocatalyst. Additionally, a detailed examination of the charge redistribution highlights the influence of electron transfer on the hydrogenation site selectivity and, consequently, the entire reaction processes. This analysis also underscores the importance of catalyst composition to electrocatalytic NORR. Overall, by demonstrating the strategy to identify the optimal reaction pathway from both thermodynamic and kinetic perspectives, this study establishes TM-BHT, represented by Cu-BHT, as a promising platform for the development of more efficient electrocatalysts for NORR to NH 3 .

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“…As such, it is desired to synthesize NH 3 sustainably via fossil-free sources, and electrochemical synthesis provides an attractive option. Waste nitrates can be electrochemically reduced to NH 3 , and there has been considerable progress in the field. − Electrochemical synthesis of NH 3 by reducing N 2 in aqueous media is attractive as NH 3 can be synthesized from just air, water, and renewable electricity. However, the process is extremely challenging due to the low solubility of N 2 in water, the inert nature of N 2 , and the competing H 2 evolution reaction .…”

Section: Introductionmentioning

confidence: 99%

Pathway toward Scalable Energy-Efficient Li-Mediated Ammonia Synthesis

Kani,

Goyal,

Gauthier

et al. 2024

ACS Appl. Mater. Interfaces

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Lithium-mediated ammonia synthesis (LiMAS) is an emerging electrochemical method for NH3 production, featuring a meticulous three-step process involving Li+ electrodeposition, Li nitridation, and Li3N protolysis. The essence lies in the electrodeposition of Li+, a critical phase demanding current oscillations to fortify the solid-electrolyte interface (SEI) and ensure voltage stability. This distinctive operational cadence orchestrates Li nitridation and Li3N protolysis, profoundly influencing the NH3 selectivity. Increasing N2 pressure enhances the NH3 faradaic efficiency (FE) up to 20 bar, beyond which proton availability controls selectivity between Li nitridation and Li3N protolysis. The proton donor, typically alcohols, is a key factor, with 1-butanol observed to yield the highest NH3 FE. Counterion in the Li salt is also observed to be significant, with larger anions (e.g., exemplified by BF4 –) improving SEI stability, directly impacting LiMAS efficacy. Notably, we report a peak NH3 FE of ∼70% and an NH3 current density of ∼−100 mA/cm2 via a delicate balance of process conditions, encompassing N2 pressure, proton donor, Li salt, and their respective concentrations. In contrast to the recent literature, we find that the theoretical maximum energy efficiency of LiMAS hinges significantly on the proton source, with LiMAS utilizing H2O calculated to have a maximum achievable energy efficiency of 27.8%. Despite inherent challenges, a technoeconomic analysis suggests high-pressure LiMAS to be more feasible than both ambient LiMAS and a modified green Haber–Bosch process. Our analysis finds that, at a 100 mA/cm2 NH3 current density and a 6 V cell voltage, LiMAS delivers green NH3 at an all-inclusive cost of $456 per ton, significantly lower than conventional cost barriers. Our economic analysis underscores high-pressure LiMAS as a potentially transformative technology that may revolutionize large-scale NH3 production, paving the way for a sustainable future.

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Design of material regulatory mechanism for electrocatalytic converting NO/NO₃⁻to NH₃progress

Cited by 17 publications

References 222 publications

Catalysts for C–N coupling in urea electrosynthesis under ambient conditions from carbon dioxide and nitrogenous species

Catalysts for C–N coupling in urea electrosynthesis under ambient conditions from carbon dioxide and nitrogenous species

Theoretical Insights into the Selective Electrocatalytic Reduction of NO to NH₃ on a Two-Dimensional Cu-Benzylthiol Metal–Organic Framework Nanostructure

Pathway toward Scalable Energy-Efficient Li-Mediated Ammonia Synthesis

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Design of material regulatory mechanism for electrocatalytic converting NO/NO3−to NH3progress

Cited by 17 publications

References 222 publications

Catalysts for C–N coupling in urea electrosynthesis under ambient conditions from carbon dioxide and nitrogenous species

Catalysts for C–N coupling in urea electrosynthesis under ambient conditions from carbon dioxide and nitrogenous species

Theoretical Insights into the Selective Electrocatalytic Reduction of NO to NH3 on a Two-Dimensional Cu-Benzylthiol Metal–Organic Framework Nanostructure

Pathway toward Scalable Energy-Efficient Li-Mediated Ammonia Synthesis

Contact Info

Product

Resources

About

Design of material regulatory mechanism for electrocatalytic converting NO/NO₃⁻to NH₃progress

Theoretical Insights into the Selective Electrocatalytic Reduction of NO to NH₃ on a Two-Dimensional Cu-Benzylthiol Metal–Organic Framework Nanostructure