Effect of vibrationally excited N2(v) on atomic nitrogen generation using two consecutive pulse corona discharges under atmospheric pressure N2
- 19 September 2019
- journal article
- research article
- Published by IOP Publishing in Journal of Physics D: Applied Physics
- Vol. 52 (49), 494003
- https://doi.org/10.1088/1361-6463/ab3f83
Abstract
Herein, we report on experimental results showing that vibrationally excited N-2(v) plays an important role in producing nitrogen atoms in successive two-pulsed corona discharges. To investigate the effect of vibrationally excited N-2(v) on the generation of atomic nitrogen, two pulses were generated such that their pulse intervals could be varied in a controlled manner. The resulting nitrogen atoms were measured using TALIF under atmospheric pressure N-2 at different time points after each pulse. Firstly, the effect of pulse-to-pulse intervals (Delta t) on the streamer formation of the second pulse discharge was observed. The results suggest that a decrease of Delta t cause a reduction in the consumption of energy and inhibit streamer formation and propagation of a second pulse discharge. The energy efficiency of atomic nitrogen generation in the second pulse discharge near the anode tip was a maximum of approximately three times that of the first pulse. This efficiency decreases with increasing Delta t and eventually became approximately equivalent to the value of the first pulse within Delta t = 300 mu s. This behavior is correlated with the temporal profile of the vibrational temperature after pulse discharge, which indicates that vibrationally excited N-2(v) generated by the first pulse discharge plays a significant role in atomic nitrogen generation in the second pulse. The local densities of atomic nitrogen in the streamer channel for the first and second pulse discharges were estimated from their decay rate. The results suggest that the second pulse discharge generates atomic nitrogen while maintaining the local density of the first discharge pulse in the streamer channel, irrespective of Delta t. Moreover, it indicates that the main generation region of atomic nitrogen in the second pulse discharge is different from that of the first pulse, although the second pulse discharge uses vibrationally excited N-2(v) to generate atomic nitrogen.Funding Information
- JSPS Grant-in-Aid for Young Scientists (JP17H04864)
This publication has 35 references indexed in Scilit:
- Synthesis of ammonia directly from air and water at ambient temperature and pressureScientific Reports, 2013
- Measurement of minimum ignition energy in hydrogen-oxygen-nitrogen premixed gas by spark dischargeJournal of Physics: Conference Series, 2011
- Measurement of Atomic Nitrogen in N2Pulsed Positive Corona Discharge Using Two-Photon Absorption Laser-Induced FluorescenceJapanese Journal of Applied Physics, 2009
- Effect of humidity on gas temperature in the afterglow of pulsed positive corona dischargePlasma Sources Science and Technology, 2009
- Measurement of OH density and gas temperature in incipient spark-ignited hydrogen–air flameCombustion and Flame, 2008
- Formation of hydrogen peroxide and degradation of phenol in synergistic system of pulsed corona discharge combined with TiO2 photocatalysisJournal of Hazardous Materials, 2007
- Study of a non-equilibrium pulsed nanosecond discharge at atmospheric pressure using coherent anti-Stokes Raman scatteringProceedings of the Combustion Institute, 2007
- Plasma synthesis of ammonia with a microgap dielectric barrier discharge at ambient pressureIEEE Transactions on Plasma Science, 2003
- CARS study of the vibrational kinetics of nitrogen molecules in the burning and afterglow stages of a pulsed dischargeTechnical Physics, 1997
- Kinetic scheme of the non-equilibrium discharge in nitrogen-oxygen mixturesPlasma Sources Science and Technology, 1992