Study the Effect of Dielectric Barrier Discharge (DBD) Plasma on the Decomposition of Volatile Organic Compounds

Main Article Content

Hiba Qassim Farag
Saba J. Kadhem

Abstract

Recently, research has focused on non-thermal plasma (NTP) technologies as a way to remove volatile organic compounds from the air stream, due to its distinctive qualities, which include a quick reaction at room temperature. In this work, the properties of the plasma generated by the dielectric barrier discharge (DBD) system and by a glass insulator were studied. Plasma was generated at different voltages (3, 4, 6, 7, 8 kV ) with a fixed distance between the electrodes of 5 mm, and a constant argon gas flow rate of (2.5) I/min. DBD plasma emission spectra were recorded for each voltage. The Boltzmann plot method was used to calculate the electron temperature in the plasma ( ), and the Stark expansion method was used to calculate the electron density ( ). The decomposition of organic compounds (cyclohexane) was also studied using DBD plasma. The results showed that the potential difference between the two electrodes has a clear effect on the plasma parameters, as the temperature of the electrons  and the density of electrons  increase with the increase in the potential difference between the two electrodes. The DBD plasma system proved to be a good way to decompose volatile organic compounds, as the results proved the emission of hydrogen gas as one of the dissociation products of cyclohexane.

Article Details

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Articles

Author Biographies

Hiba Qassim Farag, Department of Physics/College of Science/University of Baghdad/Baghdad/Iraq

 

 

Saba J. Kadhem, Department of Physics/College of Science/University of Baghdad/Baghdad/Iraq

 

 

How to Cite

1.
Qassim Farag H, Saba J. Kadhem. Study the Effect of Dielectric Barrier Discharge (DBD) Plasma on the Decomposition of Volatile Organic Compounds. IJP [Internet]. 2022 Dec. 1 [cited 2024 Dec. 23];20(4):45-53. Available from: https://ijp.uobaghdad.edu.iq/index.php/physics/article/view/1056

References

Kadhim M.M., Abbas Q.A., and Abdulameer M.R., Study of some plasma characteristics in dielectric barrier discharge (DBD) system. Iraqi Journal of Science, 2022. 63(5): pp.2048-2056.

Subedi D.P., Joshi U.M., and Wong C.S., Dielectric barrier discharge (DBD) plasmas and their applications, in Plasma Science and Technology for Emerging Economies. 2017, Springer. pp.693-737.

Ivankov A., Capela T., Rueda V., Bru E., Piquet H., Schitz D., Florez D., and Diez R., Experimental study of a nonthermal DBD-driven plasma jet system using different supply methods. Plasma, 2022. 5(1): pp.75-97.

Amri D., Nawawi Z., and Jambak M.I. The comparison between types of electrodes in dielectric barrier discharge (DBD) plasma for obtaining potable water: a review. in IOP Conference Series: Materials Science and Engineering. 2019. IOP Publishing.

Vandenbroucke A.M., Morent R., De Geyter N., and Leys C., Non-thermal plasmas for non-catalytic and catalytic VOC abatement. Journal of Hazardous Materials, 2011. 195: pp.30-54.

Rösch C., Kohajda T., Röder S., von Bergen M., and Schlink U., Relationship between sources and patterns of VOCs in indoor air. Atmospheric Pollution Research, 2014. 5(1): pp.129-137.

De Gennaro G., de Gennaro L., Mazzone A., Porcelli F., and Tutino M., Indoor air quality in hair salons: screening of volatile organic compounds and indicators based on health risk assessment. Atmospheric Environment, 2014. 83: pp.119-126.

Moreno Ramírez D., Ramírez-Andreotta M.D., Vea L., Estrella-Sánchez R., Wolf A.M.A., Kilungo A., Spitz A.H., and Betterton E.A., Pollution prevention through peer education: a community health worker and small and home-based business initiative on the arizona-sonora border. International Journal of Environmental Research Public Health, 2015. 12(9): pp.11209-11226.

Jo W.-K. and Kim S.-H., Worker exposure to aromatic volatile organic compounds in dry cleaning stores. AIHAJ-American Industrial Hygiene Association, 2001. 62(4): pp.466-471.

Oks E., Effect of thermal collective modes on the Stark broadening of hydrogen spectral lines in strongly coupled plasmas. Journal of Physics B: Atomic, Molecular Optical Physics, 2016. 49(6): pp.065701.

Choudhury B., Portugal S., Roy S., Mastro E., and Johnson J.A., Smart dielectric barrier discharge plasma decontamination: spatially targeted decontamination with actuated ozone distribution. Frontiers in Physics, 2022. 10: pp.834030.

Jabur Y.K., Hammed M.G., and Khalaf M.K., DC glow discharge plasma characteristics in Ar/O2 gas mixture. Iraqi Journal of Science, 2021. 62(2): pp.475-482.

Cheng W., Yu J., Jiang L., Miao Q., Zhang L., and Zhao B., Experimental Study on the working characteristics of a pre-combustion AC plasma jet igniter. Frontiers in Energy Research, 2022. 10: pp.879534.

Kadhem S.J., Studying of plasma-polymerized Pyrrole at variable gas flow rates via plasma jet. Iraqi Journal of Physics, 2021. 19(48): pp.44-51.

Hussein N.K. and Kadhem S., Spectroscopic diagnosis of Arc Carbon and Magnesium plasma. Iraqi Journal of Science, 2022. 63(6): pp.2492-2501.

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