Projects / Programmes
Waterborne virus inactivation efficiency of a prototype device combining non-equilibrium plasma and hydrodynamic cavitation
Code |
Science |
Field |
Subfield |
1.02.00 |
Natural sciences and mathematics |
Physics |
|
2.20.00 |
Engineering sciences and technologies |
Hydrology |
|
Code |
Science |
Field |
1.03 |
Natural Sciences |
Physical sciences |
2.07 |
Engineering and Technology |
Environmental engineering
|
waterborne virus, cavitation, plasma, virus inactivation, water disinfection
Data for the last 5 years (citations for the last 10 years) on
April 24, 2024;
A3 for period
2018-2022
Data for ARIS tenders (
04.04.2019 – Programme tender,
archive
)
Database |
Linked records |
Citations |
Pure citations |
Average pure citations |
WoS |
963 |
24,321 |
19,890 |
20.65 |
Scopus |
988 |
27,044 |
22,399 |
22.67 |
Researchers (28)
Organisations (5)
Abstract
Scientific aspects of innovative technology for the treatment of waters contaminated with plant viruses will be elaborated. The viricidal properties of gaseous plasma sustained in a super-cavitation bubble will be studied. First, a device useful for sustaining a rather stable low-pressure bubble using hydrodynamic cavitation will be constructed. The device will enable the insertion of electrodes for ignition and sustaining a gaseous discharge in the cavitation bubble, as well as probes for characterization of the discharge and plasma parameters. RT-PCR of three long fragments will assess the gaseous plasma treatment effect on the viral RNA integrity spanned almost the whole virus genome. RT-ddPCR will be used for estimation of the virus concentrations of the plasma-cavitation treated waters, while the decay in the infectivity will be estimated by assessing the infection of the model plants. The degradation of viruses upon the treatment will be visualized by TEM. The gaseous discharge versus cavitation parameters' properties will be measured with an oscilloscope, while the plasma parameters by VUV, UV and visible spectroscopies, electrical probes, and catalytic probes. The correlations between the plasma and discharge/cavitation parameters will be elaborated and published as separate papers. The most useful cavitation/discharge parameters in terms of production of viricidal UV and VUV radiation, as well as OH radicals, will be used for studying the viricidal activities. Separate papers will be published on destruction kinetics for a few plant viruses versus the plasma parameters. The project team will consist of hydrodynamic cavitation and plasma physicists and virologists.