Plasma-assisted ammonia synthesis in a packed-bed dielectric barrier discharge reactor: effect of argon addition

The effect of argon (Ar) addition on plasma-assisted ammonia (NH3) synthesis in a packed-bed dielectric barrier discharge (DBD) reactor is investigated in this work. Both higher normalized NH3 concentration and N-2 conversion are achieved by adding Ar to N-2-H-2 plasma. The 18.6% increment of normalized NH3 concentration and 15% increment of N-2 conversion are realized with 30 vol.% Ar addition compared with the case of N-2-H-2 plasma only, indicating that Ar addition would contribute to NH3 formation. The mechanisms of NH3 synthesis with Ar addition are proposed based on electrical characteristics and electron energy distribution function of the N-2-H-2-Ar plasma. The intensity of microdischarges, mean electron energy and quantity of energetic electrons increase upon Ar addition. Hence, the electron-impact reactions would be enhanced upon Ar addition. Meanwhile, the effective capacitance of the plasma reactor is improved, which suggests Ar addition contributes to achieve fully-bridged plasma discharge and transfer energy into chemical process in plasma. Moreover, the presence of Ar introduces Penning excitation and ionization reactions in N-2-H-2 plasma, which would benefit N2 conversion and then accelerate NH3 formation as well.

Automated summary

The addition of argon in plasma-assisted ammonia synthesis can increase the efficiency and yield of NH3 production. Argon enhances the electron activity in plasma, facilitating electron-impact reactions. Additionally, argon promotes plasma discharge and energy transfer into chemical processes.