Plasma plume and plasma jet
Since fully dielectric, interference-free and ultra compact electric-field probes allow the measurement of strong electric field, both continuous wave (CW) and transient, KAPTEOS solution meets the needs of electric field measurement in plama jet, in plasma plume including when they are generated by extremely intense lasers (PW).
KAPTEOS has conducted many studies and manufactured numerous systems on behalf of its clients: electric-field mapping within plasma jets, single-shot measurement of the electromagnetic pulse (EMP) generated by a laser / plasma interaction, attenuation measurement inside biological tissues of the electric field generated by a plasma jet.
Discover KAPTEOS technology on video
Find here a video of KAPTEOS technology allowing the measurement of dielectric barrier discharge.
Case studies
by L. DUVILLARET
by L. DUVILLARET
They use KAPTEOS technology for their R&D
List of publications
"Demonstration of the high efficiency of an air plasma jet combining electric field and RONS in the treatment of chronic wounds", O. D. Cortazar et al., IEEE Transactions on Radiation and Plasma Medical Sciences vol. 9, 680-688 (2025),
"Transferred plasma catheter for endotherapeutic applications: A parametric study of guided streamers dynamics", M. Soulier et al., Physics of Plasma vol. 32, 043506—1-11 (2025),
"Potentialities and limitations of an electro-optic probe for electric field diagnostics of cold atmospheric pressure plasma jets", F. Aljammal et al., The European Physical Journal D vol. 77, 199 (2023), DOI: https://doi.org/10.1140/epjd/s10053-023-00781-8
"An Overview of Subnanosecond Pulsed Electric Field Biological Effects: Toward Contactless Technologies for Cancer Treatment", N. Ibrahimi et al., Bioelectricity vol. 5, 0031 (2023),
"Cold Atmospheric Pressure Plasma Jet Operated in Ar and He: From Basic Plasma Properties to Vacuum Ultraviolet, Electric Field and Safety Thresholds Measurements in Plasma Medicine", A. V. Nastuta et al., Applied Science vol. 12, 644 (2022),
"Atmospheric Air Plasma Streamers Deliver Nanosecond Pulses for Focused Electroporation", S. Xiao et al., Bioelectricity vol. 4 (2022), DOI: https://doi.org/10.1089/bioe.2022.0025
"Accurate spectra for high energy ions by advanced time of flight diamond detector schemes in experiments with high energy and intensity lasers", M. Salvadori et al., Scientific Reports vol. 11, 3396 (2021), https://www.nature.com/articles/s41598-021-82655-w
"Laser produced electromagnetic pulses: generation, detection and mitigation", F. Consoli et al., High Power Laser Science and Engineering vol. 8, e2 (2020),
"Sources and space–time distribution of the electromagnetic pulses in experiments on inertial confinement fusion and laser–plasma acceleration", F. Consoli et al., Philosophical Transactions of the Royal Society A vol. 379 (2020), DOI: https://doi.org/10.1098/rsta.2020.0022
"Acceleration of Plasma Bullets by Grooved Dielectric Rod", F. Sohbatzadeh, IEEE Transactions on Plasma Science vol. 48, p. 2977 – 2986 (2020),
"Mapping the electric field vector of guided ionization waves at atmospheric pressure", S. Iseni et al., Plasma Research Express vol. 2, 025014 (2020), DOI: https://doi.org/10.1088/2516-1067/ab9b69
"Electromagnetic Compatibility of a Railgun Implemented on a Warship", F. Bieth et al., IEEE Transactions on Plasma Science vol. 47, p. 2987 – 2994 (2019),
"Penetration of Ar and He RF-driven plasma jets into micrometer-sized capillary tubes", A. Brahme et al., Journal of Physics D vol. 51, 414002 (2018),
"The kINPen—a review on physics and chemistry of the atmospheric pressure plasma jet and its applications", S. Reuters et al., Journal of Physics D vol. 51, 233001 (2018),
"Plasma farming: Non-thermal dielectric barrier discharge plasma technology for improving the growth of soybean sprouts and chickens", J. J. Zhang et al., Plasma vol. 1, p. 285-296 (2018), DOI: https://doi.org/10.3390/plasma1020025
"Analysis of conductive target influence in plasma jet experiments through helium metastable and electric field measurements", T. Darny et al., Plasma Sources Science and Technology vol. 26, 045008 (2017), DOI: https://doi.org/10.1088/1361-6595/aa5b15
"Electric field measurement in the dielectric tube of helium atmospheric pressure plasma jet", G. B. Sretenovic et al., Journal of Applied Physics vol. 121, 123304 (2017),
"State of the art in medical applications using non-thermal atmospheric pressure plasma", H. Tanaka et al., Reviews of Modern Plasma Physics vol. 1, 3 (2017),
"DC superimposed AC high voltage: A new strategy for transferring stable he atmospheric pressure cold plasma bullets through long dielectric tubes", S. N. Siadati et al., Physics of Plasmas vol. 24, 063521 (2017), DOI: https://doi.org/10.1063/1.4989713
"Numerical and experimental study of the dynamics of a s helium plasma gun discharge with various amounts of N2 Admixture", A. Bourdon et al., Plasma Sources Science and Technology vol. 25, 035002 (2016), DOI: https://doi.org/10.1088/0963-0252/25/3/035002
"Time-resolved absolute measurements by electro-optic effect of giant electromagnetic pulses due to laser-plasma interaction in nanosecond regime", F. Consoli et al., Scientific Reports vol. 6, 27889 (2016), DOI: https://doi.org/10.1038/srep27889
"New insights on the propagation of pulsed atmospheric plasma streams: From single jet to multi jet arrays", S. Iseni et al., Physics of Plasma vol. 22, 122007 (2015),
"Single Shot and Vectorial Characterization of Intense Electric Field in Various Environments With Pigtailed Electrooptic Probe", G. Gaborit et al., IEEE Transactions on Plasma Science vol. 42, p. 1265 – 1273 (2014), DOI: https://doi.org/10.1109/TPS.2014.2301023
A Non perturbative Electrooptic Sensor for In Situ Electric Discharge Characterization", G. Gaborit et al., IEEE Transactions on Plasma Science vol. 41, p. 2851 – 2857 (2013)
