Electronic Metal–Support Interaction Triggering Interfacial Charge Polarization over CuPd/N‐Doped‐C Nanohybrids Drives Selectively Electrocatalytic Conversion of Nitrate to Ammonia

Xu, You; Shi, Keke; Ren, Tianlun; Yu, Hongjie; Deng, Kai; Wang, Xin; Wang, Ziqiang; Wang, Hongjing; Wang, Liang

doi:10.1002/smll.202203335

Cited by 44 publications

(40 citation statements)

References 67 publications

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“…designed and synthesized metal–organic framework (MOF)‐derived bimetallic CuPd NPs/N‐doped carbon (CuPd/CN) hybrid nanoarrays (Figure 6e). 137,138 Cu and Pd possess modulated electronic structure and serve as dual active sites for catalyzing selectively EAS conversion, achieving FE NH3 of 96.16% and NH 3 selectivity of 92.08%. Moreover, Co‐doped Fe sites in the Fe 2 O 3 lattice (Co–Fe@Fe 2 O 3 ) form the single phase due to little structural change and transform the adsorption energy of intermediates and products, thus enhancing catalytic performance for the NO 3 RR 139 .…”

Section: Electrocatalytic Nitrate Reduction To Nh3mentioning

confidence: 99%

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

Gao

Liu

et al. 2023

Natural Sciences

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Nitric oxide (NO)/nitrate (NO 3 − ) exists as the most hazardous pollutions in the air/water that severely impacts human health. Conventional disposing methods are energy-consuming and uneconomic. Moreover, ammonia (NH 3 ) fertilizer resources acquire urgent, eco-friendly, and economical strategies that can remove NO/NO 3 − pollution and simultaneously convert nitrate species, maintaining nitrogen balance.Electrochemical nitrogen (N) reduction is attracting more attention, particularly electrocatalytic NO/NO 3 − reduction (ENR) to ammonia supply an approach to fixed nitrogen and generate ammonia. ENR is capable of achieving high NH 3 yield and Faradaic efficiency (FE), avoiding competitive hydrogen evolution reactions and easily overcoming strong N≡N triple bond (941 kJ mol −1 ). There are abundant research studies related to ENR for decreasing hazardous NO/NO 3 − and supplying profitable NH 3 . In this review, we discuss different electrocatalytic regulations for crystalline facet engineering, heteroatom doping, heterostructure, surface vacancy engineering, and single-atom structure, which bring various metal/nonmetal and their combined catalysts to the preferable performance, such as reactivity, selectivity, FE, and stability. Finally, we summarize the challenges and provide the perspectives to promote the industrial application of ENR.

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Section: Electrocatalytic Nitrate Reduction To Nh3mentioning

confidence: 99%

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

Gao

Liu

et al. 2023

Natural Sciences

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“…Consequently, there has been a dramatic growth in research efforts to study the ambient electrochemical reduction of NO 3 − to NH 3 . 15–17 However, the NO 3 − RR is an eight-electron reaction process and generates various by-products, such as NO 2 − , NO, N 2 O, N 2 , and NH 2 OH, resulting in low NH 3 selectivity, FE and yield rate. 18–20 Such electrocatalytic performance is mainly determined by the electrocatalysts; hence, the major challenge in large-scale production of NH 3 via the NO 3 − RR lies in finding a suitable catalyst.…”

Section: Introductionmentioning

confidence: 99%

“…[1][2][3] At present, the synthesis of NH 3 in industry mainly hinges on the traditional Haber-Bosch process (HBP). Such a reaction process is accomplished under tough operating con-ditions, including high temperature (400-550 °C) and high pressure (15)(16)(17)(18)(19)(20)(21)(22)(23)(24)(25)(26)(27)(28)(29)(30), which is extremely energy-consuming. 4,5 Taking the enormous requirements into consideration (∼170 Mt per year, over 80% of total content for fertilizers), the HBP consumes 1-2% of the world's energy supply and is accompanied by extensive CO 2 emissions.…”

Section: Introductionmentioning

confidence: 99%

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Recent progress and strategies on the design of catalysts for electrochemical ammonia synthesis from nitrate reduction

Song

Yue

Fan

et al. 2023

Inorg. Chem. Front.

100

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“…To improve the intrinsic activity of Cu, researchers have developed various strategies to optimize its electronic state, such as by (i) engineering Cu into nanoscale or a single reaction site; , (ii) doping Cu with other elements (Pd, P, Ni and etc. ) − or decorating it with a surface ligand; (iii) depositing Cu on a metal oxide support. , Among these strategies, depositing Cu on metal oxides is the most preferable one owing to the simplicity of synthesis and the considerable benefit from the strong metal–support interactions . It has been documented that metal–support interactions give rise to electron-deficient Cu species (Cu δ+ ). ,, These Cu δ+ species are more active than Cu 0 in adsorbing and activating intermediate N-species, affording a relatively low energy barrier for NO3RR. ,− With its excellent chemical stability and surface acidity, TiO 2 has become a well-known support for use in metal-based catalysis in various reaction systems (CO oxidation, Fischer–Tropsch process, and water–gas shift reaction); − however, only a few TiO 2 –Cu catalysts have been reported for NO3RR. , On the other hand, Deng et al recently reported a considerably enhanced hydrogen evolution reaction on Pt when it was deposited on TiO 2 .…”

Section: Introductionmentioning

confidence: 99%

Electronic Structure Optimization and Proton-Transfer Enhancement on Titanium Oxide-Supported Copper Nanoparticles for Enhanced Nitrogen Recycling from Nitrate-Contaminated Water

Liu

Shen

Shi

et al. 2023

Environ. Sci. Technol.

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Electrocatalytic reduction of nitrate to NH 3 (NO3RR) on Cu offers sustainable NH 3 production and nitrogen recycling from nitrate-contaminated water. However, Cu affords limited NO3RR activity owing to its unfavorable electronic state and the slow proton transfer on its surface, especially in neutral/alkaline media. Furthermore, although a synchronous "NO3RR and NH 3 collection" system has been developed for nitrogen recycling from nitrate-laden water, no system is designed for natural water that generally contains low-concentration nitrate. Herein, we demonstrate that depositing Cu nanoparticles on a TiO 2 support enables the formation of electron-deficient Cu δ+ species (0 < δ ≤ 2), which are more active than Cu 0 in NO3RR. Furthermore, TiO 2 −Cu coupling induces local electric-field enhancement that intensifies water adsorption/ dissociation at the interface, accelerating proton transfer for NO3RR on Cu. With the dual enhancements, TiO 2 −Cu delivers an NH 3 -N selectivity of 90.5%, mass activity of 41.4 mg-N h g Cu −1 , specific activity of 377.8 mg-N h −1 m −2 , and minimal Cu leaching (<25.4 μg L −1 ) when treating 22.5 mg L −1 of NO 3 − -N at −0.40 V, outperforming most of the reported Cu-based catalysts. A sequential NO3RR and NH 3 collection system based on TiO 2 −Cu was then proposed, which could recycle nitrogen from nitratecontaminated water under a wide concentration window of 22.5−112.5 mg L −1 at a rate of 209−630 mg N m −2 h −1 . We also demonstrated this system could collect 83.9% of nitrogen from NO 3 − -N (19.3 mg L −1 ) in natural lake water.

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Electronic Metal–Support Interaction Triggering Interfacial Charge Polarization over CuPd/N‐Doped‐C Nanohybrids Drives Selectively Electrocatalytic Conversion of Nitrate to Ammonia

Abstract: The data that support the findings of this study are available in the supplementary material of this article.

Cited by 44 publications

References 67 publications

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

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

Recent progress and strategies on the design of catalysts for electrochemical ammonia synthesis from nitrate reduction

Electronic Structure Optimization and Proton-Transfer Enhancement on Titanium Oxide-Supported Copper Nanoparticles for Enhanced Nitrogen Recycling from Nitrate-Contaminated Water

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Electronic Metal–Support Interaction Triggering Interfacial Charge Polarization over CuPd/N‐Doped‐C Nanohybrids Drives Selectively Electrocatalytic Conversion of Nitrate to Ammonia

Abstract: The data that support the findings of this study are available in the supplementary material of this article.

Cited by 44 publications

References 67 publications

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

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

Recent progress and strategies on the design of catalysts for electrochemical ammonia synthesis from nitrate reduction

Electronic Structure Optimization and Proton-Transfer Enhancement on Titanium Oxide-Supported Copper Nanoparticles for Enhanced Nitrogen Recycling from Nitrate-Contaminated Water

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

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