Catalyst-free urea synthesis via plasma-driven direct coupling of CO2 and N2 under ambient conditions

Dingwei Gan; Jingwen Huang; Longfei Hong; Haoxuan Jiang; Xiaoran Wang; Rusen Zhou; Jing Sun; Renwu Zhou

doi:10.1039/d5gc02193f

Catalyst-free urea synthesis via plasma-driven direct coupling of CO₂ and N₂ under ambient conditions

Dingwei Gan
, Jingwen Huang
, Longfei Hong
, Haoxuan Jiang
, Xiaoran Wang
, Rusen Zhou
, Jing Sun
, Renwu Zhou

School of Electrical Engineering

Xi'an Jiaotong University

Research output: Contribution to journal › Article › peer-review

1 Scopus citations

Abstract

This work demonstrates a new catalyst-free pathway of urea synthesis via direct CO₂/N₂ coupling in spatially separated dual plasma reactors. The design isolates reactive species generation, suppressing oxidative side reactions (e.g., O and OH-induced NH₃ loss) and facilitating C-N coupling. Mechanistic studies indicate CO (from CO₂ dissociation) as the key intermediate, reacting with NH_x to form urea, while minimizing NO_x byproducts. By decoupling plasma zones, the system achieves selective nitrogen fixation under ambient conditions, advancing green urea synthesis without catalysts or extreme energy inputs. This strategy provides mechanistic insights and a scalable platform for sustainable carbon/nitrogen co-utilization.

Original language	English
Pages (from-to)	8811-8817
Number of pages	7
Journal	Green Chemistry
Volume	27
Issue number	29
DOIs	https://doi.org/10.1039/d5gc02193f
State	Published - 21 Jul 2025

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title = "Catalyst-free urea synthesis via plasma-driven direct coupling of CO2 and N2 under ambient conditions",

abstract = "This work demonstrates a new catalyst-free pathway of urea synthesis via direct CO2/N2 coupling in spatially separated dual plasma reactors. The design isolates reactive species generation, suppressing oxidative side reactions (e.g., O and OH-induced NH3 loss) and facilitating C-N coupling. Mechanistic studies indicate CO (from CO2 dissociation) as the key intermediate, reacting with NHx to form urea, while minimizing NOx byproducts. By decoupling plasma zones, the system achieves selective nitrogen fixation under ambient conditions, advancing green urea synthesis without catalysts or extreme energy inputs. This strategy provides mechanistic insights and a scalable platform for sustainable carbon/nitrogen co-utilization.",

author = "Dingwei Gan and Jingwen Huang and Longfei Hong and Haoxuan Jiang and Xiaoran Wang and Rusen Zhou and Jing Sun and Renwu Zhou",

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T1 - Catalyst-free urea synthesis via plasma-driven direct coupling of CO2 and N2 under ambient conditions

AU - Gan, Dingwei

AU - Huang, Jingwen

AU - Hong, Longfei

AU - Jiang, Haoxuan

AU - Wang, Xiaoran

AU - Zhou, Rusen

AU - Sun, Jing

AU - Zhou, Renwu

PY - 2025/7/21

Y1 - 2025/7/21

N2 - This work demonstrates a new catalyst-free pathway of urea synthesis via direct CO2/N2 coupling in spatially separated dual plasma reactors. The design isolates reactive species generation, suppressing oxidative side reactions (e.g., O and OH-induced NH3 loss) and facilitating C-N coupling. Mechanistic studies indicate CO (from CO2 dissociation) as the key intermediate, reacting with NHx to form urea, while minimizing NOx byproducts. By decoupling plasma zones, the system achieves selective nitrogen fixation under ambient conditions, advancing green urea synthesis without catalysts or extreme energy inputs. This strategy provides mechanistic insights and a scalable platform for sustainable carbon/nitrogen co-utilization.

AB - This work demonstrates a new catalyst-free pathway of urea synthesis via direct CO2/N2 coupling in spatially separated dual plasma reactors. The design isolates reactive species generation, suppressing oxidative side reactions (e.g., O and OH-induced NH3 loss) and facilitating C-N coupling. Mechanistic studies indicate CO (from CO2 dissociation) as the key intermediate, reacting with NHx to form urea, while minimizing NOx byproducts. By decoupling plasma zones, the system achieves selective nitrogen fixation under ambient conditions, advancing green urea synthesis without catalysts or extreme energy inputs. This strategy provides mechanistic insights and a scalable platform for sustainable carbon/nitrogen co-utilization.

UR - https://www.scopus.com/pages/publications/105010295273

U2 - 10.1039/d5gc02193f

DO - 10.1039/d5gc02193f

M3 - 文章

AN - SCOPUS:105010295273

SN - 1463-9262

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SP - 8811

EP - 8817

JO - Green Chemistry

JF - Green Chemistry

IS - 29

ER -

Catalyst-free urea synthesis via plasma-driven direct coupling of CO₂ and N₂ under ambient conditions

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