Magnetic field improves ozone production in an atmospheric pressure surface dielectric barrier discharge: understanding the physico-chemical mechanism behind low energy consumption

Abstract: Revealing the physico-chemical mechanism of magnetic field coupled with parameters to save energy and reduce consumption to improve O3 generation.

“…The gas temperature affects the rate of chain chemical reactions between the precursors. Nevertheless, the chemical reaction system in an atmospheric-pressure discharge plasma is exceptionally complicated [38,39], and experimentally measuring and analyzing the variation in different chemical reactions and their effects on RNS when the discharge voltage changes is unrealistic. Additionally, the energy density and gas temperature jointly determine the components and concentration of RNS during the discharge process; however, the individual effects of these two factors cannot be distinguished merely from experimental data.…”

Dynamics of NO, N₂O, and ONOOH in atmospheric-pressure air dielectric barrier discharge: decoupling energy density and gas temperature effects varying with discharge voltage

“…The gas temperature affects the rate of chain chemical reactions between the precursors. Nevertheless, the chemical reaction system in an atmospheric-pressure discharge plasma is exceptionally complicated [38,39], and experimentally measuring and analyzing the variation in different chemical reactions and their effects on RNS when the discharge voltage changes is unrealistic. Additionally, the energy density and gas temperature jointly determine the components and concentration of RNS during the discharge process; however, the individual effects of these two factors cannot be distinguished merely from experimental data.…”

Dynamics of NO, N₂O, and ONOOH in atmospheric-pressure air dielectric barrier discharge: decoupling energy density and gas temperature effects varying with discharge voltage