Deciphering Electrolyte Selection for Electrochemical Reduction of Carbon Dioxide and Nitrogen to High‐Value‐Added Chemicals

Ni, Jiajie; Cheng, Qiyang; Liu, Sisi; Wang, Mengfan; He, Yanzheng; Qian, Tao; Yan, Chenglin; Lu, Jianmei

doi:10.1002/adfm.202212483

Cited by 48 publications

(32 citation statements)

References 178 publications

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“…[20,21] On the other hand, the concentration of proton source should be controlled to be neither too high to avoid electron stealing for HER, nor too low since NRR still pertains to proton-coupled electron transfer reaction. [22,23] Considering NRR primarily occurs at the multiphase interface among gaseous nitrogen, solid electrocatalyst, and liquid electrolyte, it is better to propose the optimization strategy based on the three-phase reaction interface. [24] Mimicking key aspects of enzymatic catalysis and building microenvironments over solid catalyst surfaces may play a critical advantage in inducing the confinement effect and controlling the transport of the reactants.…”

Section: Introductionmentioning

confidence: 99%

Molecular Imprinting Technology Enables Proactive Capture of Nitrogen for Boosted Ammonia Synthesis under Ambient Conditions

Liu

Wang

et al. 2023

Advanced Materials

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Electrochemical nitrogen reduction reaction (NRR) is a burgeoning field for green and sustainable ammonia production, in which numerous potential catalysts emerge in endless. However, satisfactory performances are still not realized under practical applications due to the limited solubility and sluggish diffusion of nitrogen at the interface. Herein, molecularly imprinting technology is adopted to construct an adlayer with abundant nitrogen imprints on the electrocatalyst, which is capable to selectively recognize and proactively aggregate high‐concentrated nitrogen at the interface while hindering the access of overwhelming water simultaneously. With this favourable microenvironment, nitrogen could preferentially occupy the active surface, and the NRR equilibrium could be positively shifted to facilitate the reaction kinetics. Approximately threefold improvements in both ammonia production rate (185.7 µg h−1 mg−1) and Faradaic efficiency (72.9%) are achieved by a metal‐free catalyst compared with the bare one. We believe that the molecularly imprinting strategy should be a general method to find further applicability in numerous catalysts or even other reactions facing similar challenges.This article is protected by copyright. All rights reserved

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Section: Introductionmentioning

confidence: 99%

Molecular Imprinting Technology Enables Proactive Capture of Nitrogen for Boosted Ammonia Synthesis under Ambient Conditions

Liu

Wang

et al. 2023

Advanced Materials

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“…Nitrogen electrofixaton (N 2 + 6H + + 6e → 2NH 3 ) is a viable method that can upgrade earth-abundant N 2 into useful ammonia in an aqueous electrolyte under ambient temperature and pressure, − which offers the advantages of a low carbon footprint and high energy efficiency. In comparison to those alkaline/neutral systems, the acidic nitrogen electrofixation has presented a number of remarkable features: (i) It can provide an abundant proton source directly available for participating in the reactions, without involving an additional water dissociation step (H 2 O → 2H + + OH – ), and consequently, is more energy-efficient than other counterparts. − (ii) The extremely low solubility of N 2 in aqueous solutions (0.02, at 283 K and 101 kPa) is the bottleneck of nitrogen electrofixation, which can be improved by 0.06 (pH 3) in acidic solutions (pH < 7) , because of proton–N 2 interactions. , (iii) Acidic nitrogen electrofixation can be easily integrated into a well-established proton-exchange membrane (PEM) configuration for large-scale applications. − …”

Section: Introductionmentioning

confidence: 99%

Acid-Stable Ebonex for Continuous-Flow Nitrogen Electrofixation

Li,

Ding,

Zhang

et al. 2023

Energy Fuels

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Acidic nitrogen electrofixation offers the benefits of abundant proton sources and improved solubility of N 2 that can facilitate the reaction kinetics at three-phase interfaces. However, excessive protons would simultaneously boost competitive hydrogen evolution that consume electrons otherwise for nitrogen electrofixation, leading to low selectivity to ammonia. In this paper, we report an acid-stable ebonex (Ti 4 O 7 ) characteristic of excellent catalytic performances in a 0.1 M HCl electrolyte (pH 1). With the incorporation into continuous-flow cells, the catalyst demonstrates an optimal faradaic efficiency of 23.57% and a large ammonia yield rate of 45.52 μg h −1 cm −2 , which is 2 orders of magnitude higher than that in traditional H-type cells. A further mechanism study has been conducted using density functional theory (DFT) calculations and X-ray absorption near-edge structure (XANES), which indicate the structural advantages of ebonex,such as intrinsic electrical conductivity and low oxidation valence of Ti and Jahn−Teller-type structural distortion. Consequently, the ebonex catalyst can suppress hydrogen evolution, leading to a favorable associative alternating nitrogen electrofixation pathway with the rate-limiting step of N 2 * → NNH*.

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“…[4,5] As an alternative sustainable approach, electrocatalytic nitrogen (N 2 ) reduction reaction (NRR) is becoming more and more attractive due to its mild conditions and the utilization of renewable energy sources. [6,7] Up to now, excessive attention has been focused on kinetic research, aiming to reduce the electrochemical barrier of NRR by appropriate modification of the catalyst itself, such as heteroatom doping, defect engineering, and hybrid engineering. [8][9][10] Unfortunately, the reported NRR performance still falls short of expectations, even for novel materials with low reaction barriers.…”

Section: Introductionmentioning

confidence: 99%

“…Nowadays, ammonia is predominantly synthesized by conventional Haber‐Bosch process under harsh conditions, which accounts for 1 % of the worldwide energy consumption and 1–3 % of the global CO 2 emissions [4,5] . As an alternative sustainable approach, electrocatalytic nitrogen (N 2 ) reduction reaction (NRR) is becoming more and more attractive due to its mild conditions and the utilization of renewable energy sources [6,7] . Up to now, excessive attention has been focused on kinetic research, aiming to reduce the electrochemical barrier of NRR by appropriate modification of the catalyst itself, such as heteroatom doping, defect engineering, and hybrid engineering [8–10] .…”

Section: Introductionmentioning

confidence: 99%

Eliminating Concentration Polarization with Cationic Covalent Organic Polymer to Promote Effective Overpotential of Nitrogen Fixation

et al. 2023

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Electrocatalytic nitrogen reduction reaction offers a sustainable alternative to the conventional Haber‐Bosch process. However, it is currently restricted by low effective overpotential due to the concentration polarization, which arises from accumulated products, ammonium, at the reaction interface. Here, a novel covalent organic polymer with ordered periodic cationic sites is proposed to tackle this challenge. The whole network exhibits strong positive charge and effectively repels the positively charged ammonium, enabling an ultra‐low interfacial product concentration, and successfully driving the reaction equilibrium to the forward direction. With the given potential unchanged, the suppressed overpotential can be much liberated, ultimately leading to a continuous high‐level reaction rate. As expected, when this tailored microenvironment is coupled with a transition metal‐based catalyst, a 24‐fold improvement is generated in the Faradaic efficiency (73.74 %) as compared with the bare one. The proposed strategy underscores the importance of optimizing dynamic processes as a means of improving overall performance in electrochemical syntheses.

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Deciphering Electrolyte Selection for Electrochemical Reduction of Carbon Dioxide and Nitrogen to High‐Value‐Added Chemicals

Cited by 48 publications

References 178 publications

Molecular Imprinting Technology Enables Proactive Capture of Nitrogen for Boosted Ammonia Synthesis under Ambient Conditions

Molecular Imprinting Technology Enables Proactive Capture of Nitrogen for Boosted Ammonia Synthesis under Ambient Conditions

Acid-Stable Ebonex for Continuous-Flow Nitrogen Electrofixation

Eliminating Concentration Polarization with Cationic Covalent Organic Polymer to Promote Effective Overpotential of Nitrogen Fixation

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