Publications

Selected publication  

Janda, M., Stancampiano, A., Di Natale, F., Machala, Z.: Short Review on Plasma–Aerosol Interactions, Plasma Processes & Polymers, 22: e2400275. https://doi.org/10.1002/ppap.202400275 (2025).
citations: 5  

Abstract

Systems where cold atmospheric plasma interacts with liquid aerosols provide information on unexplored physico‐chemical phenomena and yield multiple advantages. Plasma‐activated aerosols show high chemical reactivity within small liquid micro-droplet volumes, making them suitable for various applications and industrial processes. Plasma–aerosol interactions present complex interdisciplinary challenges that demand detailed investigations of the underlying physical, chemical, and transport mechanisms. This short review focuses on the key challenges in understanding plasma–aerosol interactions and the diagnostic hurdles in elucidating the physical and chemical mechanisms governing microdroplet interactions with plasma discharges. The scalability of plasma–aerosol systems, including high‐throughput charged water flows, are analyzed. Some“niche” applications of plasma–aerosols are identified, especially in decontamination, nitrogen fixation, and agriculture. The controversies in the field are also introduced and critically discussed. The review concludes with a proposed path and outlook for the development of plasma–aerosol technology.

Citations

1.)Reuter, S., Hamdan, A., 2025. Special Issue: Plasma and Liquids—Fundamentals and Applications. Plasma Processes and Polymers. https://doi.org/10.1002/ppap.202400278
(2025)
2.)Li, C., Liang, T., Wang, Z., Wang, P., Zhang, M., Yang, Y., Yu, K., Pan, Y., Li, D., 2025. Plasma jets effectively promoting cloud condensation nuclei formation and aerosol activation in artificial weather modification. Physics of Fluids 37, 032004. https://doi.org/10.1063/5.0252091
(2025)
3.)Čech, J., Sťahel, P., Prokeš, L., Trunec, D., Horňák, R., Rudolf, P., Maršálek, B., Maršálková, E., Lukeš, P., 2025. Glow discharge in water cavitation cloud with improved efficiency for hydrogen peroxide production. Plasma Sources Science and Technology 34. https://doi.org/10.1088/1361-6595/addf79
(2025)
4.)González-Llorente, L., Andrés-Gasco, M., Gil Aranda, M.A., Rabadán-Ros, R., Zapata-Pérez, R., Núñez-Delicado, E., Menéndez-Coto, N., García-González, C., Baena-Huerta, F.J., Coto-Montes, A., Caso-Peláez, E., 2025. The Hormetic Adaptative Capacity and Resilience to Oxidative Stress Is Strengthened by Exposome Enrichment with Air Cold Atmospheric Plasma: A Metabolome Targeted Follow-Up Approach. Biomedicines 13. https://doi.org/10.3390/biomedicines13040949
(2025)
5.)Horňák, R., Čech, J., St’ahel, P., Prokeš, L., Trunec, D., Rudolf, P., Maršálek, B., 2025. Spatial Mapping of OH Radicals Produced by Electric Discharge in Hydrodynamic Cavitation Cloud. Journal of Physical Chemistry Letters 16, 6279–6285. https://doi.org/10.1021/acs.jpclett.5c00979
(2025)