Litcius/Paper detail

Cascade N<sub>2</sub> Reduction Process with DBD Plasma Oxidation and Electrocatalytic Reduction for Continuous Ammonia Synthesis

Liang Wen, Xiaoming Zhang, Pan‐Wei Bai, Zhenyu Zhang, Jiahe Chen, Wei Liu, Zihan Sun, Yue Feng, Guidong Yang, Huimin Tong, Tao Xie

2023Environmental Science & Technology30 citationsDOI

Abstract

Due to the extremely high bond energy of N≡N (∼941 kJ/mol), the traditional Haber–Bosch process of ammonia synthesis is known as an energy-intensive and high CO 2 -emission industry. In this paper, a cascade N 2 reduction process with dielectric barrier discharge (DBD) plasma oxidation and electrocatalytic reduction as an alternative route is first proposed. N 2 is oxidized to be reactive nitrogen species (RNS) by nonthermal plasma, which would then be absorbed by KOH solution and electroreduced to NH 4 + . It is found that the production of NO x is a function of discharge length, discharge power, and gas flow rate. Afterward, the cobalt catalyst is used in the process of electrocatalytic reduction of ammonia, which shows high selectivity (Faradic efficiency (FE) above 90%) and high yield of ammonia (45.45 mg/h). Finally, the cascade plasma oxidation and electrocatalytic reduction for ammonia synthesis is performed. Also, the performance of the reaction system is evaluated. It is worth mentioning that a stable and sustainable ammonia production efficiency of 16.21 mg/h is achieved, and 22.16% of NO x obtained by air activation is converted into NH 4 + . This work provides a demonstration for further industrial application of ammonia production with DBD plasma oxidation and electrocatalytic reduction techniques.

Topics & Concepts

AmmoniaCascadeReduction (mathematics)Ammonia productionPlasmaChemistryOxidation reductionProcess (computing)Inorganic chemistryOrganic chemistryComputer scienceChromatographyPhysicsMathematicsGeometryQuantum mechanicsOperating systemBiochemistryAmmonia Synthesis and Nitrogen ReductionPlasma Applications and Diagnostics