Theoretical analysis of argon 2p states' density ratios for nanosecond plasma optical emission spectroscopy

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Authors

KUSÝN Lukáš JOVANOVIĆ A. P. LOFFHAGEN D. BECKER M. M. HODER Tomáš

Year of publication 2024
Type Article in Periodical
Magazine / Source Spectrochimica Acta Part B: Atomic Spectroscopy
MU Faculty or unit

Faculty of Science

Citation
web https://www.sciencedirect.com/science/article/pii/S0584854724002258
Doi http://dx.doi.org/10.1016/j.sab.2024.107080
Keywords Argon; Reaction kinetics; Time-dependent collision-radiative model; Nanosecond pulsed discharge; Electric field; Optical emission spectroscopy; Sub-nanosecond diagnostics
Description A theoretical analysis of excited argon state densities responsible for optical emission spectra of atmospheric pressure argon plasma is presented for its use in plasma diagnostics. Nanosecond pulsed barrier discharges are simulated using spatially one- and two-dimensional fluid-Poisson models using the reaction kinetics model presented by Stankov et al. [1], which considers all ten argon 2p states (Paschen notation) separately. The very first (single) discharge and repetitive discharges with frequencies from 5?kHz to 100?kHz are considered. A semi-automated procedure is utilized to find appropriate 2p states for electric field determination using an intensity ratio method, which is based on a time-dependent collisional-radiative model. The fluid simulations in combination with the semi-automated procedure are used to quantify the sensitivity of selected 2p-state ratios to given preionization of the gas. A highly sensitive time-correlated single photon counting experiment shows clearly that the selected ratio is sensitive to the electric field variation in the streamer head, yet additional calibration is needed for absolute values determination. Different approaches for effective lifetime determination are tested and applied also to measured data. The influence of radial and axial 2p state density integration on the intensity ratio method is discussed. The above mentioned models and procedures result in a flexible theory-based methodology applicable for development of new diagnostic techniques.
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