Combination of ICCD fast imaging and image processing techniques to probe species–specific propagation due to guided ionization waves

Athanasopoulos, D.; Svarnas, P.; Liapis, C. M.; Papadopoulos, Polycarpos K.; Giotis, Konstantinos; Vafeas, Panayiotis; Vafakos, Georgios P.; Giannakakis, Vasileios; Gerakis, Alexandros

doi:10.1088/1402-4896/acc906

Cited by 4 publications

(1 citation statement)

References 59 publications

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“…In the volume discharge case, any physical path between the two conductive electrodes necessarily includes both the dielectric barrier and the gas medium. The associated discharge regimes and ionization waves have been investigated extensively for systems like plasma jets [6][7][8][9][10][11], packed beds [12][13][14], etc [15,16]. In the surface discharge case, there is at least one path along which the two electrodes may be reached through the dielectric barrier only.…”

Section: Introductionmentioning

confidence: 99%

Ionization wave propagation and cathode sheath formation due to surface dielectric-barrier discharge sustained in pulsed mode

Giotis

Svarnas

Amanatides

et al. 2023

Plasma Sci. Technol.

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This work deals with the experimental study of a surface dielectric-barrier discharge (DBD), as a part of the ongoing interest in the control of plasma induced electro-fluid dynamic effects (e.g., plasma actuators). The discharge is generated using a plasma reactor consisting of a fused silica plate which is sandwiched between two printed circuit boards where the electrodes are developed. The reactor is driven by narrow high voltage square pulses of asymmetric rising (25 ns) and falling (2.5 μs) parts, while the discharge evolution is con-sidered in a temporarily and spatially resolved manner over these pulses. That is, conventional electrical and optical emission analyses are combined with high resolution optical emission spectroscopy and ns-resolved imaging, unveiling main characteristics of the discharge with a special focus on its propagation along the dielectric-barrier surface. The voltage rising part leads to cathode-directed ionization waves, which propagate with a speed up to 105 m s−1. The voltage falling part leads to cathode sheath formation on the driven electrode. Τhe polarization of the dielectric barrier appears critical for the discharge dynamics.

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Section: Introductionmentioning

confidence: 99%

Ionization wave propagation and cathode sheath formation due to surface dielectric-barrier discharge sustained in pulsed mode

Giotis

Svarnas

Amanatides

et al. 2023

Plasma Sci. Technol.

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Frequency-locked measurement of floating potential fluctuations in cold micro-plasma jets: Interactive surface feedback effects on reactive species generation

Behmani,

Keidar,

Bhattacharjee

2024

Physics of Plasmas

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Frequency-locked measurements of floating potential fluctuations are carried out in a cold atmospheric pressure micro-plasma jet interacting with substrates of varying electrical permittivity (εr). The range of fluctuation frequencies (∼ 0.5–9 kHz) is compared with that determined from the time series of floating potential fluctuations and its fast Fourier transform. Results of these independent methods to determine the fluctuation frequencies are found to agree reasonably well, thereby affirming their existence in the micro-plasma jet. Substrate feedback effects dictated by εr are found to influence the amplitude of fluctuations and threshold breakdown voltage. The spectral emission line intensity corresponding to the reactive oxygen and nitrogen species, which is critical for biomedical applications, decrease drastically in the presence of stronger levels of fluctuations, indicating a bearing on their generation.

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Machine learning assisted optical diagnostics on a cylindrical surface dielectric barrier discharge

Stefas,

Giotis,

Invernizzi

et al. 2024

J. Phys. D: Appl. Phys.

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The present study explores combining machine learning (ML) algorithms with standard optical diagnostics (such as time–integrated emission spectroscopy and imaging) to accurately predict operating conditions and assess the emission uniformity of a cylindrical surface Dielectric Barrier Discharge (SDBD). It is demonstrated that these optical diagnostics can provide the input data for ML which identifies peculiarities associated with the discharge emission pattern at different high voltage waveforms (AC and pulsed) and amplitudes. By employing unsupervised (Principal Component Analysis (PCA)) and supervised (Multilayer Perceptron (MLP) neural networks) algorithms, the applied voltage waveform and amplitude are categorised and predicted based on correlations/differences identified within large amounts of corresponding data. PCA allowed us to effectively visualise patterns related to the voltage waveforms and amplitudes applied to the SDBD through a transformation of the spectroscopic/imaging data into principal components (PCs) and their projection to a two-dimensional PCs vector space. Furthermore, an accurate prediction of the voltage amplitude is achieved using the MLP which is trained with PCs. A particularly interesting aspect of this concept involves examining the uniformity of the emission pattern of the discharge. This was achieved by analysing spectroscopic data recorded at four different regions around the SDBD surface using the two ML algorithms. These discoveries are instrumental in enhancing plasma–induced processes. They open up new avenues for real–time control, monitoring, and optimization of plasma–based applications across diverse fields such as flow control for the present SDBD.

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Combination of ICCD fast imaging and image processing techniques to probe species–specific propagation due to guided ionization waves

Cited by 4 publications

References 59 publications

Ionization wave propagation and cathode sheath formation due to surface dielectric-barrier discharge sustained in pulsed mode

Ionization wave propagation and cathode sheath formation due to surface dielectric-barrier discharge sustained in pulsed mode

Frequency-locked measurement of floating potential fluctuations in cold micro-plasma jets: Interactive surface feedback effects on reactive species generation

Machine learning assisted optical diagnostics on a cylindrical surface dielectric barrier discharge

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