Saving the Energy Loss in Lithium‐Mediated Nitrogen Fixation by Using a Highly Reactive Li<sub>3</sub>N Intermediate for C−N Coupling Reactions

The aqueous electrocatalytic reduction of NO 3À into NH 3 (NitrRR) presents a sustainable route applicable to NH 3 production and potentially energy storage. However, the NitrRR involves a directly eightelectron transfer process generally required a large overpotential (< À 0.2 V versus reversible hydrogen electrode (vs. RHE)) to reach optimal efficiency. Here, inspired by biological nitrate respiration, the NitrRR was separated into two stages along a [2+6]-electron pathway to alleviate the kinetic barrier. The system employed a Cu nanowire catalyst produces NO 2 À and NH 3 with current efficiencies of 91.5 % and 100 %, respectively at lower overpotentials (> +0.1 vs. RHE). The high efficiency for such a reduction process was further explored in a zinc-nitrate battery. This battery could be specified by a high output voltage of 0.70 V, an average energy density of 566.7 Wh L À 1 at 10 mA cm À 2 and a power density of 14.1 mW cm À 2 , which is well beyond all previously reported similar concepts. Ammonia (NH 3 ), has been technically synthesized by the traditional Haber-Bosch process over the past century and is extensively used in fertilizers production; ammonia is also regarded as an emerging carbon-free liquid fuel. [1] Currently, [

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Enabled Efficient Ammonia Synthesis and Energy Supply in a Zinc–Nitrate Battery System by Separating Nitrate Reduction Process into Two Stages

Jiang

Zeng

Savateev

et al. 2023

Angewandte Chemie

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Enabled Efficient Ammonia Synthesis and Energy Supply in a Zinc–Nitrate Battery System by Separating Nitrate Reduction Process into Two Stages

et al. 2023

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Cascade electrosynthesis of LiTFSI and N-containing analogues via a looped Li–N2 battery

Zhang,

Xiong,

Wang

et al. 2024

Nat Catal

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Saving the Energy Loss in Lithium‐Mediated Nitrogen Fixation by Using a Highly Reactive Li₃N Intermediate for C−N Coupling Reactions

Cited by 3 publications

References 42 publications

Enabled Efficient Ammonia Synthesis and Energy Supply in a Zinc–Nitrate Battery System by Separating Nitrate Reduction Process into Two Stages

Enabled Efficient Ammonia Synthesis and Energy Supply in a Zinc–Nitrate Battery System by Separating Nitrate Reduction Process into Two Stages

Enabled Efficient Ammonia Synthesis and Energy Supply in a Zinc–Nitrate Battery System by Separating Nitrate Reduction Process into Two Stages

Cascade electrosynthesis of LiTFSI and N-containing analogues via a looped Li–N2 battery

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Saving the Energy Loss in Lithium‐Mediated Nitrogen Fixation by Using a Highly Reactive Li3N Intermediate for C−N Coupling Reactions

Cited by 3 publications

References 42 publications

Enabled Efficient Ammonia Synthesis and Energy Supply in a Zinc–Nitrate Battery System by Separating Nitrate Reduction Process into Two Stages

Enabled Efficient Ammonia Synthesis and Energy Supply in a Zinc–Nitrate Battery System by Separating Nitrate Reduction Process into Two Stages

Enabled Efficient Ammonia Synthesis and Energy Supply in a Zinc–Nitrate Battery System by Separating Nitrate Reduction Process into Two Stages

Cascade electrosynthesis of LiTFSI and N-containing analogues via a looped Li–N2 battery

Contact Info

Product

Resources

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Saving the Energy Loss in Lithium‐Mediated Nitrogen Fixation by Using a Highly Reactive Li₃N Intermediate for C−N Coupling Reactions