Electrocatalytic C–N Coupling for Urea Synthesis

Chen, Chen; He, Nihan; Wang, Shuangyin

doi:10.1002/smsc.202100070

Cited by 102 publications

(70 citation statements)

References 40 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…The electrosynthesis of urea has been proposed as a simple and onsite production method. We strongly advise the readers to read Kornienko's review on C-N construction by electrocatalysis [460] and Wang's review on C-N coupling for urea electrosynthesis [461]. Wang et al recently reported a breakthrough strategy for fixing N2/CO2 simultaneously for mild urea generation by electrocatalytically coupling two gaseous molecules, namely, N2 and CO2, into urea [462].…”

Section: C-n Coupling Reaction To Amide Urea and Amine (Methylamine)mentioning

confidence: 99%

Recent advances in nanostructured heterogeneous catalysts for N-cycle electrocatalysis

Sun

Liang

Liu

et al. 2022

Nano Research Energy

305

218

View full text Add to dashboard Cite

To restore the natural nitrogen cycle (N-cycle), artificial N-cycle electrocatalysis with flexibility, sustainability, and compatibility can convert intermittent renewable energy (e.g., wind) to harmful or value-added chemicals with minimal carbon emissions. The background of such N-cycles, such as nitrogen fixation, ammonia oxidation, and nitrate reduction, is briefly introduced here. The discussion of emerging nanostructures in various conversion reactions is focused on the architecture/compositional design, electrochemical performances, reaction mechanisms, and instructive tests. Energy device advancements for achieving more functions as well as in situ/operando characterizations toward understanding key steps are also highlighted. Furthermore, some recently proposed reactions as well as less discussed C-N coupling reactions are also summarized. We classify inorganic nitrogen sources that convert to each other under an applied voltage into three types, namely, abundant nitrogen, toxic nitrate (nitrite), and nitrogen oxides, and useful compounds such as ammonia, hydrazine, and hydroxylamine, with the goal of providing more critical insights into strategies to facilitate the development of our circular nitrogen economy.

show abstract

Section: C-n Coupling Reaction To Amide Urea and Amine (Methylamine)mentioning

confidence: 99%

Recent advances in nanostructured heterogeneous catalysts for N-cycle electrocatalysis

Sun

Liang

Liu

et al. 2022

Nano Research Energy

305

218

View full text Add to dashboard Cite

show abstract

“…Electrocatalysis, which can be driven by renewable electricity to obtain value-added products under ambient conditions, is a technically viable and zero-carbon-emission route. − Researchers have recently demonstrated the electrochemical synthesis of urea through the direct coupling of N 2 with CO 2 in water under ambient conditions. For instance, Wang et al reported the electrocatalytic synthesis of urea using PdCu–TiO 2 catalysts, where the electrocatalytic C–N coupling mechanism was studied systematically .…”

mentioning

confidence: 99%

A Defect Engineered Electrocatalyst that Promotes High-Efficiency Urea Synthesis under Ambient Conditions

et al. 2022

View full text Add to dashboard Cite

Synthesizing urea from nitrate and carbon dioxide through an electrocatalysis approach under ambient conditions is extraordinarily sustainable. However, this approach still lacks electrocatalysts developed with high catalytic efficiencies, which is a key challenge. Here, we report the high-efficiency electrocatalytic synthesis of urea using indium oxyhydroxide with oxygen vacancy defects, which enables selective C–N coupling toward standout electrocatalytic urea synthesis activity. Analysis by operando synchrotron radiation–Fourier transform infrared spectroscopy showcases that *CO2NH2 protonation is the potential-determining step for the overall urea formation process. As such, defect engineering is employed to lower the energy barrier for the protonation of the *CO2NH2 intermediate to accelerate urea synthesis. Consequently, the defect-engineered catalyst delivers a high Faradaic efficiency of 51.0%. In conjunction with an in-depth study on the catalytic mechanism, this design strategy may facilitate the exploration of advanced catalysts for electrochemical urea synthesis and other sustainable applications.

show abstract

“…In industry, urea is synthesized from liquid ammonia and carbon dioxide under the conditions of high pressure and elevated temperature 3,4 . However, the current urea synthetic protocol suffers from high energy input and the consumption of value-added ammonia, far away from meeting the demands for sustainable development 5 . Consequently, the electrocatalytic urea synthesis has emerged as one of the promising alternatives for the traditional urea manufacture to realize the urea production under milder conditions [6][7][8][9][10][11] .…”

mentioning

confidence: 99%

“…Consequently, the electrocatalytic urea synthesis has emerged as one of the promising alternatives for the traditional urea manufacture to realize the urea production under milder conditions [6][7][8][9][10][11] . Compared with the indirect method of initial ammonia production with subsequent urea synthesis, the direct urea synthesis from co-activation and coupling of carbon dioxide (CO 2 ) and nitrate (NO 3 − ) waste plays the crucial role in the development of urea synthetic processes, to close the global carbon footprint, maintain nitrogen balance and reform the urea industry simultaneously 5,12,13 .…”

mentioning

confidence: 99%

Identifying and tailoring C–N coupling site for efficient urea synthesis over diatomic Fe–Ni catalyst

et al. 2022

Self Cite

View full text Add to dashboard Cite

Electrocatalytic urea synthesis emerged as the promising alternative of Haber–Bosch process and industrial urea synthetic protocol. Here, we report that a diatomic catalyst with bonded Fe–Ni pairs can significantly improve the efficiency of electrochemical urea synthesis. Compared with isolated diatomic and single-atom catalysts, the bonded Fe–Ni pairs act as the efficient sites for coordinated adsorption and activation of multiple reactants, enhancing the crucial C–N coupling thermodynamically and kinetically. The performance for urea synthesis up to an order of magnitude higher than those of single-atom and isolated diatomic electrocatalysts, a high urea yield rate of 20.2 mmol h−1 g−1 with corresponding Faradaic efficiency of 17.8% has been successfully achieved. A total Faradaic efficiency of about 100% for the formation of value-added urea, CO, and NH3 was realized. This work presents an insight into synergistic catalysis towards sustainable urea synthesis via identifying and tailoring the atomic site configurations.

show abstract

Electrocatalytic C–N Coupling for Urea Synthesis

Cited by 102 publications

References 40 publications

Recent advances in nanostructured heterogeneous catalysts for N-cycle electrocatalysis

Recent advances in nanostructured heterogeneous catalysts for N-cycle electrocatalysis

A Defect Engineered Electrocatalyst that Promotes High-Efficiency Urea Synthesis under Ambient Conditions

Identifying and tailoring C–N coupling site for efficient urea synthesis over diatomic Fe–Ni catalyst

Contact Info

Product

Resources

About