Your search keyword '"Collisional-radiative model"' showing total 88 results

1. Utilization of D2 molecular band emission for electron density measurement

Author

Nishijima, D., Baldwin, M.J., Chang, F., Hwangbo, D., and Tynan, G.R.

Published

2024

2. Spectroscopic measurement of atmospheric-pressure non-equilibrium Ar plasma using continuum and line spectra.

Author

Kikuchi, Wataru, Yamashita, Yuya, Nezu, Atsushi, and Akatsuka, Hiroshi

Subjects

*DISTRIBUTION (Probability theory), *ARGON plasmas, *ELECTRON density, *ELECTRON distribution, *SPECTRUM analysis, *BREMSSTRAHLUNG, *NONEQUILIBRIUM plasmas

Abstract

A robust method for determining the electron temperature and density of atmospheric-pressure non-equilibrium argon plasmas is reported. The methodology is based on the analysis of the continuum and line spectra of the plasma. Assuming that the electron energy distribution function (EEDF) is expressed as a two-temperature generalized EEDF (GEEDF), the gamma value of the GEEDF is determined through a grid search of the continuum spectrum analysis given by the bremsstrahlung process, which minimizes the mean-squared logarithmic error (MSLE). In addition, the relationship between the gamma value and the electron temperature and density is determined. Utilizing this relationship, the electron temperature and density are determined by minimizing the MSLE between the excited-state densities obtained from the line spectrum analysis and numerically calculated using the collisional-radiative model. This methodology yielded results that satisfied both continuum and line spectrum analyses. In addition, the same analysis was conducted either by continuum spectrum analysis or by line spectrum alone to compare the results. [ABSTRACT FROM AUTHOR]

Published

2024

3. Utilization of D2 molecular band emission for electron density measurement

Author

D. Nishijima, M.J. Baldwin, F. Chang, D. Hwangbo, and G.R. Tynan

Subjects

Deuterium, Molecular band emission, Optical emission spectroscopy, Collisional-radiative model, Machine learning, Nuclear engineering. Atomic power, TK9001-9401

Abstract

D2 molecular band emission observed at a wavelength range of λ∼557−643nm is utilized to measure electron density, ne, in D plasmas of the PISCES-A and PISCES-RF linear plasma devices. The D2 band is divided at λ=593nm to make an intensity ratio, D2L (∼557–593nm)/D2R (∼593–643nm), where D2L consists predominantly of the g3Σg+3dσ, h3Σg+3sσ, i3Πg3dπ, j3Δg3dδ → c3Πu2pπ transitions, while D2R mainly includes the d3Πu3pπ → a3Σg+2sσ Fulcher band emission. It is experimentally found that D2L/D2R depends strongly on ne with little Te dependence in ranges of ne∼(0.031−6.1)×1018 m−3 and Te∼2.3−13.9eV. This observed trend is consistent with collisional-radiative model calculations using Yacora on the Web.

Published

2024

4. Collisional-radiative modeling for the EUV spectrum of W 40+ -W 42+ ions.

Author

Lei, Lirong, Ding, Xiaobin, Wu, Cunqiang, Zhang, Denghong, Zhang, Ling, Zhang, Fengling, Yao, Ke, Yang, Yang, Fu, Yunqing, and Dong, Chenzhong

Subjects

*ION recombination, *PLASMA temperature, *PLASMA density, *ELECTRON density, *IONS, *PLASMA diagnostics

Abstract

The wavelengths and transition rates of W40+-W42+ ions within the range of 40–140 Å, have been calculated using the Flexible Atomic Code of the Dirac-Fock-Slater method with a central potential. We investigated the charge state distribution of W38+-W45+ ions at different temperatures by constructing an appropriate rate equation and demonstrate the importance of the dielectronic recombination process. Additionally, we simulated the emission spectra of W40+-W42+ ions in a Tokamak plasma environment using collisional-radiative modeling. Our findings demonstrate strong agreement with experimental results and other related theoretical investigations. Finally, we propose certain pairs of transition lines as diagnostic tools for plasma temperature and density, leveraging the correlation between line intensity ratio and electron temperature and density. [ABSTRACT FROM AUTHOR]

Published

2024

5. Study of Electron Impact Excitation of Na-like Kr Ion for Impurity Seeding Experiment in Large Helical Device.

Author

Gupta, Shivam, Oishi, Tetsutarou, and Murakami, Izumi

Subjects

ELECTRONIC excitation, PERTURBATION theory, OSCILLATOR strengths, ATOMIC structure, WAVE functions, SYNTHETIC biology, ELECTRON impact ionization

Abstract

In this work, a krypton gas impurity seeding experiment was conducted in a Large Helical Device. Emission lines from the Na-like Kr ion in the extreme ultraviolet wavelength region, such as 22.00 nm, 17.89 nm, 16.51 nm, 15.99 nm, and 14.08 nm, respective to 2 p 6 3 p (2 P 1 / 2 o) − 2 p 6 3 s (2 S 1 / 2) , 2 p 6 3 p (2 P 3 / 2 o) − 2 p 6 3 s (2 S 1 / 2) , 2 p 6 3 d (2 D 3 / 2) − 2 p 6 3 p (2 P 3 / 2 o) , 2 p 6 3 d (2 D 5 / 2) − 2 p 6 3 p (2 P 3 / 2 o) , and 2 p 6 3 d (2 D 3 / 2) − 2 p 6 3 p (2 P 1 / 2 o) transitions, are observed. In order to generate a theoretical synthetic spectrum, an extensive calculation concerning the excitation of the Kr 25 + ion through electron impact was performed for the development of a suitable plasma model. For this, the relativistic multiconfiguration Dirac–Hartree–Fock method was employed along with its extension to the relativistic configuration interaction method to compute the relativistic bound-state wave functions and excitation energies of the fine structure levels using the General Relativistic Atomic Structure Package-2018. In addition, another set of calculations was carried out utilizing the relativistic many-body perturbation theory and relativistic configuration interaction methods integrated within the Flexible Atomic Code. To investigate the reliability of our findings, the results of excitation energies, transition probabilities, and weighted oscillator strengths of different dipole-allowed transitions obtained from these different methods are presented and compared with the available data. Further, the detailed electron impact excitation cross-sections and their respective rate coefficients are obtained for various fine structure resolved transitions using the fully relativistic distorted wave method. Rate coefficients, calculated using the Flexible Atomic Code for population and de-population kinetic processes, are integrated into the collisional-radiative plasma model to generate a theoretical spectrum. Further, the emission lines observed from the Kr 25 + ion in the impurity seeding experiment were compared with the present plasma model spectrum, demonstrating a noteworthy overall agreement between the measurement and the theoretical synthetic spectrum. [ABSTRACT FROM AUTHOR]

Published

2023

6. Collisional-radiative modeling for the EUV spectrum of W40+-W42+ions

Author

Lirong Lei, Xiaobin Ding, Cunqiang Wu, Denghong Zhang, Ling Zhang, Fengling Zhang, Ke Yao, Yang Yang, Yunqing Fu, and Chenzhong Dong

Subjects

collisional-radiative model, tungsten ions, plasma spectrum, Science, Physics, QC1-999

Abstract

The wavelengths and transition rates of W ^40+ -W ^42+ ions within the range of 40–140 Å, have been calculated using the Flexible Atomic Code of the Dirac-Fock-Slater method with a central potential. We investigated the charge state distribution of W ^38+ -W ^45+ ions at different temperatures by constructing an appropriate rate equation and demonstrate the importance of the dielectronic recombination process. Additionally, we simulated the emission spectra of W ^40+ -W ^42+ ions in a Tokamak plasma environment using collisional-radiative modeling. Our findings demonstrate strong agreement with experimental results and other related theoretical investigations. Finally, we propose certain pairs of transition lines as diagnostic tools for plasma temperature and density, leveraging the correlation between line intensity ratio and electron temperature and density.

Published

2024

7. Optical emission spectroscopy diagnosis of low-pressure microwave discharge helium plasma based on collisional-radiative model.

Author

Lin, Keren, Nezu, Atsushi, and Akatsuka, Hiroshi

Abstract

An inverse model based on a low-pressure helium collisional-radiative (CR) model was developed. Parts of the rate coefficients were recalculated from the cross-sections. The dominant processes in the revised model were extracted to simplify the calculation and to develop an inverse model. The model can calculate the electron density and temperature of low-pressure helium plasma by inputting the population densities of levels 3 1 S , 3 3 S , and 3 1 D , which can be measured by optical emission spectroscopy (OES) measurement in the visible wavelength range. The results demonstrate that the electron temperature obtained by the model is extremely close to the original value in the CR model. The output values of the electron density were of the same order and magnitude as the input values. The electron density and temperature measured by OES measurement in the experiment using the developed inverse model are consistent with the results measured by the probe method. [ABSTRACT FROM AUTHOR]

Published

2022

8. Electron-Impact Ionization of the Tungsten Ions: W 38+ − W 45+.

Author

Bao, Runjia, Wei, Junkui, Li, Bowen, and Chen, Ximeng

Subjects

TUNGSTEN, IONS, COMMUNITIES

Abstract

In this manuscript, we present our calculations of detailed electron-impact single ionization cross-sections for tungsten ions, spanning charge states W 38 + − W 45 + . The level-to-level distorted-wave method implemented in the flexible atomic code (FAC) was used for calculation. Comparison between the present level-to-level distorted wave treatment and previous configuration-averaged calculations has been performed for the W 45 + ion, and we explore the possible reason for the difference observed between two calculations. We demonstrate the importance of radiative damping on the total electron-impact ionization cross-section for the W 43 + ion. Present calculations provide missing cross-sections for W 38 + − W 45 + . The data obtained are expected to be useful for modeling plasmas for fusion applications, especially for the ITER community. [ABSTRACT FROM AUTHOR]

Published

2022

9. Bayesian modeling of collisional-radiative models applicable to thermal helium beam plasma diagnostics

Author

E. Flom, M. Krychowiak, O. Schmitz, R. König, T. Barbui, F. Henke, M. Jakubowski, S. Kwak, S. Loch, J. Muñoz Burgos, and J. Svensson

Subjects

Bayesian inference, Collisional-radiative model, Helium spectroscopy, Plasma diagnostics, Nuclear engineering. Atomic power, TK9001-9401

Abstract

Thermal helium beam diagnostics using the line ratio spectroscopy method are widely used to infer temperature and density in fusion-relevant edge plasmas. These diagnostics consist of an observational system which measures emitted line radiation from either intrinsic or injected helium plasma impurities. These spectral features are then compared to the output of a collisional-radiative model to infer plasma parameters (Te, ne) from the observed helium radiation. In order to investigate the systematic uncertainties of such a diagnostic, we present the results of a Bayesian treatment of a helium collisional-radiative model (Schmitz et al., 2008) using synthetic data modeled after an existing system on the plasma experiment Wendelstein 7-X (Barbui et al. 2016). From this study, we present a new method for comprehensively combining measurement uncertainties with underlying atomic rate parameter uncertainties in the inference of plasma parameters. Finally, we also demonstrate the utility of this Bayesian approach in targeting sensitivities within the model, allowing determination of high-priority atomic data for future refinement and comparison between differing atomic models.

Published

2022

10. Impact of vibrationally resolved H2 on particle balance in Eirene simulations.

Author

Holm, Andreas, Wünderlich, Dirk, Groth, Mathias, and Börner, Petra

Subjects

*LOW temperature plasmas, *EXCITED states, *DENSE plasmas

Abstract

To evaluate the impact of transport of metastable, vibrationally excited states of the hydrogen molecule in dense and cold plasmas each vibrational state must be simulated as an individual species. Eirene neutral gas simulations of a one‐dimensional flux‐tube using a metastable‐resolved model indicate a 30–50% decrease in the effective dissociation rate compared to simulations using a metastable‐unresolved setup, which consider a single molecular species. Zero‐dimensional Eirene simulations omitting transport effects predict a 25–65% decrease in the effective dissociation rate due to differences between the metastable‐unresolved AMJUEL and the metastable‐resolved H2VIBR rates available in Eirene. The exclusion of molecular hydrogen depletion via electronically excited states and vibrational transitions v→v±N,N>1 from the metastable‐resolved rates reduce the effective dissociation rate. By accounting for the difference caused by the different collisional‐radiative treatment of the metastable‐resolved rates compared to the metastable‐unresolved rates, transport effects are expected to be relevant under detached divertor conditions. It is, however, not possible to individually assess the role of the collisional‐radiative processes and transport on the effective dissociation rate using the currently available atomic and molecular rates for the metastable‐resolved and metastable‐unresolved Eirene setups. [ABSTRACT FROM AUTHOR]

Published

2022

11. Non-equilibrium simulation of energy relaxation for earth reentry utilizing a collisional-radiative model.

Author

Du, Yao-Wen, Sun, Su-Rong, Tan, Mei-Jing, Zhou, Yu, Chen, Xuan, Meng, Xian, and Wang, Hai-Xing

Subjects

*MACH number, *ONE-dimensional flow, *THRESHOLD energy, *ELASTIC scattering, *CHARGE exchange, *COLLISIONAL plasma, *ENERGY transfer

Abstract

A high-temperature air collisional-radiative model considering both vibrational and electronic excited states is established to investigate the plasma characteristics along the stagnation-line in the post-shock flow by coupling with the one-dimensional flow model. The results obtained by the model are in reasonable agreement with the experimental data and previous calculation results. The evolutions of different temperatures and energy relaxation processes are analyzed in detail for the height of 76.42 km and Mach number of 40.58. The vibrational and electronic excited modes play a critical role on the energy transfer. The vibrational excitation processes under heavy-particle impact can transfer the translational energy to the vibrational mode, then to the electrons by the vibrational de-excitation processes. The excitation of atoms by heavy-particle impact can gain energy from the translational mode, and the de-excitation processes of high-lying excited states under electron impact result in the energy transfer to electrons. The elastic collisions also play a role on the direct transfer from translational energy to electrons. The calculations are performed for a wide range of flight altitudes and Mach numbers to investigate the thermochemical state and energy relaxation. By comparing the energy transfer processes under different altitudes and Mach numbers, it is found that the energy transfer is dominated by vibrational processes for the low-Height low-Mach condition, and the contribution of electronic excited mode is negligible. The division of thermochemical state and chemical reactions in the Height-Mach number diagram is obtained, which provides the basis for the selection of thermochemical model required for atmospheric reentry calculation. • A CR model coupled with 1D flow model is established to study energy relaxation. • The vibrational and electronic excited modes are critical for the energy transfer. • Analysis of energy relaxation is done in a wide range of heights and Mach numbers. • The division of thermochemical state in Height-Mach number diagram is obtained. [ABSTRACT FROM AUTHOR]

Published

2022

12. Spatial Distributions of 3p54s States of Argon Atoms in RF Magnetron Sputtering Plasma with a Collisional-Radiative Model.

Author

Azzaoui, M., Khelfaoui, F., and Ballah, Z.

Subjects

RADIOFREQUENCY sputtering, EQUATIONS of state, RESONANT states, THIN film deposition, ATOMS, MAGNETRON sputtering

Abstract

Thin films are used in various industrial fields, namely in the manufacture of solar cells, flat screens and in improving the physical properties of material surfaces. In thin film deposition processes, the degree of equilibrium and other plasma characteristics such as the nature, density and temperature must be identified in order to understand the occurrence of various phenomena. In this work, the main focus is on studying the spatial distributions of densities of excited states of Ar* (3p54s (1sx: x = 2-5)), as well as the relative contributions of processes such as the electron impact effect, the radiative de-excitation, the diffusion phenomena of metastable states and the Penning ionization in the population and depopulation of different argon atoms states. For this purpose, a Collisional-Radiative Model (CRM) including 41 states was applied using specified parameters in RF magnetron sputtering plasma. These parameters include electron temperature, electron and ion densities of argon. The rate equations of the state densities led to a matrix system that was solved numerically by iterative Gauss-Seidel Method. The results show that the axial distributions of different excited states and those on the cathode side are slightly larger than those found on the anode side, and they show also that both densities are less than at the reactor center. For metastable states 3p54s (1s5, 1s3), the Penning ionization is important, but it is not important for resonant states 3p54s (1s4, 1s2). Different densities of the excited states are not symmetrical with respect to the center of the reactor due to the existence of a magnetic field at the cathode. [ABSTRACT FROM AUTHOR]

Published

2021

13. Spectroscopic Studies of Laser-Based Far-Ultraviolet Plasma Light Source.

Author

Masnavi, Majid and Richardson, Martin

Subjects

PLASMA sources, LIGHT sources, PLASMA temperature, DENSE plasmas, ELECTRON plasma, SPECTRAL irradiance

Abstract

A series of experiments is described which were conducted to measure the absolute spectral irradiances of laser plasmas created from metal targets over the wavelength region of 123–164 nm by two separate 1.0 μm lasers, i.e., using 100 Hz, 10 ns, 2–20 kHz, 60–100 ns full-width-at-half-maximum pulses. A maximum radiation conversion efficiency of ≈3%/2 π sr is measured over a wavelength region from ≈125 to 160 nm. A developed collisional-radiative solver and radiation-hydrodynamics simulations in comparison to the spectra detected by the Seya–Namioka-type monochromator reveal the strong broadband experimental radiations which mainly originate from bound–bound transitions of low-ionized charges superimposed on a strong continuum from a dense plasma with an electron temperature of less than 10 eV. [ABSTRACT FROM AUTHOR]

Published

2021

14. Electron-Impact Ionization of the Tungsten Ions: W38+ − W45+

Author

Runjia Bao, Junkui Wei, Bowen Li, and Ximeng Chen

Subjects

tungsten ions, electron-impact ionization, cross-section, collisional–radiative model, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

In this manuscript, we present our calculations of detailed electron-impact single ionization cross-sections for tungsten ions, spanning charge states W38+− W45+. The level-to-level distorted-wave method implemented in the flexible atomic code (FAC) was used for calculation. Comparison between the present level-to-level distorted wave treatment and previous configuration-averaged calculations has been performed for the W45+ ion, and we explore the possible reason for the difference observed between two calculations. We demonstrate the importance of radiative damping on the total electron-impact ionization cross-section for the W43+ ion. Present calculations provide missing cross-sections for W38+− W45+. The data obtained are expected to be useful for modeling plasmas for fusion applications, especially for the ITER community.

Published

2022

15. Comparison of a collisional-radiative fluid model of H2 in UEDGE to the kinetic neutral code EIRENE

Author

A. Holm, P. Börner, T.D. Rognlien, W.H Meyer, and M. Groth

Subjects

Collisional-radiative model, Hydrogen molecules, Fluid model, UEDGE, EIRENE, Molecules, Nuclear engineering. Atomic power, TK9001-9401

Abstract

A fluid collisional-radiative model for H2 has been implemented in the edge-fluid code UEDGE and compared to the kinetic neutral code EIRENE on a simple, 2D, orthogonal domain with a constant, static plasma distribution. The novel CRUMPET Python tool was used to implement dissociation and energy rate coefficients that consider molecular-assisted processes, binding energy, and radiation due to molecular processes into the UEDGE fluid molecular model. The agreement between the fluid and kinetic molecular models was found to be within 20% when corresponding rates were used in UEDGE and EIRENE for a domain with absorbing boundaries. When wall recycling was considered, EIRENE predicted up to a factor of 2.2 higher molecular densities than UEDGE at T

Published

2021

16. Key Parameter Measurements of the Low-Pressure Gas Discharge Plasmas Used for Studying the Ion Extraction Process

Author

Li, Heping, Chu, Qiuhui, Wang, Xin, Wang, Peng, Chai, Junjie, Li, Zhanxian, and Jiang, Hong, editor

Published

2017

17. Neutral transport code for rovibrational population calculation of molecular hydrogen in large helical device plasmas.

Author

Sawada, Keiji, Nakamura, Hiroaki, Saito, Seiki, Kawamura, Gakushi, Kobayashi, Masahiro, Haga, Kenta, Migita, Ryusei, Sawada, Takumi, and Hasuo, Masahiro

Subjects

*PLASMA devices, *ELECTRON distribution, *ELECTRON temperature, *ELECTRON density, *HYDROGEN, *VIBRATIONAL spectra

Abstract

An rovibrationally resolved collisional‐radiative model of molecular hydrogen (K. Sawada and M. Goto, Atoms 4: 29, 2016) is included in the authors' neutral transport code for large helical device (LHD) plasmas. The spatial distributions of the electron temperature and density, including the divertor and divertor leg regions, are given to the code. The molecules released from the graphite divertor target are tracked. The initial rotational and vibrational states of the released molecules are provided by simulation using a molecular dynamics model. The rovibrational population produced in an LHD plasma is evaluated. [ABSTRACT FROM AUTHOR]

Published

2020

18. Characterisation of volume and surface dielectric barrier discharges in N2–O2 mixtures using optical emission spectroscopy.

Author

Kogelheide, Friederike, Offerhaus, Björn, Bibinov, Nikita, Krajinski, Philip, Schücke, Lars, Schulze, Julian, Stapelmann, Katharina, and Awakowicz, Peter

Subjects

*EMISSION spectroscopy, *OPTICAL spectroscopy, *ELECTRIC charge, *BROADBAND dielectric spectroscopy, *DIELECTRICS, *GAS mixtures, *MIXTURES

Abstract

A volume and a twin surface dielectric barrier discharge (VDBD and SDBD) are generated in different nitrogen–oxygen mixtures at atmospheric pressure by applying damped sinusoidal voltage waveforms with oscillation periods in the microsecond time scale. Both electrode configurations are located inside vacuum vessels and operated in a controlled atmosphere to exclude the influence of surrounding air. The discharges are characterised with different spatial and temporal resolution by applying absolutely calibrated optical emission spectroscopy in conjunction with numerical simulations and current–voltage measurements. Plasma parameters, namely the electron density and the reduced electric field, and the dissipated power are found to depend strongly on the oxygen content in the working gas mixture. Different spatial and temporal distributions of plasma parameters and dissipated power are explained by surface and residual volume charges for different O2 admixtures due to their effects on the electron recombination rate. Thus, the oxygen admixture is found to strongly influence the breakdown process and plasma conditions of a VDBD and a SDBD. [ABSTRACT FROM AUTHOR]

Published

2020

19. Numerical analysis of chemical reaction processes in different anode attachments of a high‐intensity argon arc.

Author

Sun, Su‐Rong, Wang, Hai‐Xing, and Zhu, Tao

Subjects

*CHEMICAL processes, *CHEMICAL reactions, *ANALYTICAL chemistry, *ANODES, *NUMERICAL analysis, *ELECTRON distribution

Abstract

The attachment mode of arc on anode is closely related to the non‐equilibrium chemical kinetics process of the anode region of arc. In this paper, the detailed chemical reaction mechanisms in the flow‐affected region for both diffuse and constricted argon arc attachments are investigated by means of one‐dimensional discharge coupled with a single‐fluid, two‐temperature model. The collisional‐radiative model is used to examine the chemical reaction processes occurring in the anode region, including the arc centreline and fringe region. The numerical results are validated by comparison with available experimental data. The obtained radial distributions of electron temperature, electron density, excited states densities, ionization, and recombination processes reveal that different mechanisms dominate the diffuse and constricted arc‐anode attachments. [ABSTRACT FROM AUTHOR]

Published

2020

20. Population Kinetics Modeling of Low-Temperature Argon Plasma

Author

Hyun-Kyung Chung, Mi-Young Song, Ji-Won Kwon, Myeong-Geon Lee, Jihoon Park, Namjae Bae, Jeamin Song, Gon-Ho Kim, Dipti, and Yuri Ralchenko

Subjects

argon optical emission spectroscopy, plasma processing, coronal models, collisional-radiative model, nonlocal thermodynamic equilibrium plasmas, population kinetics, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

Optical emission spectroscopy has been widely used in low-temperature argon plasma diagnostics. A coronal model is usually used to analyze the measured line ratios for diagnostics with a single temperature and density. However, many plasma processing conditions deviate from single temperature and density, optically thin conditions, or even coronal plasma conditions due to cascades from high-lying states. In this paper, we present a collisional-radiative model to investigate the validity of coronal approximations over a range of plasma conditions of Te = 1–4 eV and Ne = 108–1013 cm−3. The commonly used line ratios are found to change from a coronal limit where they are independent of Ne to a collisional-radiative regime where they are not. The effects of multiple-temperature plasma, radiation trapping, wall neutralization, and quenching on the line ratios are investigated to identify the plasma conditions under which these effects are significant. This study demonstrates the importance of the completeness of atomic datasets in applying a collisional-radiative model to low-temperature plasma diagnostics.

Published

2021

21. Evaluation of Fe XIV Intensity Ratio for Electron Density Diagnostics by Laboratory Measurements

Author

Nagaaki Kambara, Tomoko Kawate, Tetsutarou Oishi, Yasuko Kawamoto, Hiroyuki A. Sakaue, Daiji Kato, Nobuyuki Nakamura, Hirohisa Hara, and Izumi Murakami

Subjects

EUV spectroscopy, ionized gas, electron density diagnostics, collisional–radiative model, LHD, EBIT, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

The intensity ratio of Fe XIV 264.765A/274.203A is useful to determine the electron density of solar corona, and the relationship between the electron density and the intensity ratio obtained from a model should be evaluated using laboratory plasmas to estimate the electron density more precisely. We constructed a new collisional–radiative model (CR-model) for Fe XIV (an Al-like iron ion) by considering the processes of proton-impact excitation and electron-impact ionization to the excited states of a Mg-like iron ion. The atomic data used in the CR-model were calculated using the HULLAC atomic code. The model was evaluated based on laboratory experiments using a compact electron beam ion trap, called CoBIT, and the Large Helical Device (LHD). The measured Fe XIV 264.785 Å/274.203 Å line intensity ratio with CoBIT was 1.869 ± 0.036, and it agreed well with our CR-model results. Concurrently, the measured ratio using LHD was larger than the results of our CR-model and CHIANTI. The estimated electron densities using our CR-model agreed with those from CHIANTI within a factor of 1.6–2.4 in the range of ne≈1010−11cm−3. Further model development is needed to explain the ratio in a high-electron density region.

Published

2021

22. Calculation of the extreme-ultraviolet radiation conversion efficiency for a laser-produced tin plasma source

Author

Majid Masnavi and Homaira Parchamy

Subjects

Extreme-ultraviolet lithography, Laser-produced plasmas, Collisional-radiative model, Radiation-hydrodynamics, Highly-charged tin spectra, Physics, QC1-999

Abstract

This article presents the calculation results on the conversion efficiency (CE) of 1.064 μm laser-produced plasmas (LPPs) extreme-ultraviolet (EUV) tin (Sn) light sources with the Gaussian and a triangular-flat-topped like laser pulse temporal shapes. The computational model includes a collisional-radiative model and 1D hydrodynamics code that predicts reported experimental and theoretical results on the CE of 1.064 μm and 10.6 μm LPP EUV sources with the planar and mass-limited spherical Sn targets. The calculations for the case of a spherical target reveal that an optimum triangular-flat-topped like laser pulse generates a higher CE compared to the Gaussian pulse, especially, for the longer laser pulse duration than ≈ 30 ns. The study demonstrated that a rising intensity rate of the laser pulse has a vital role to optimize the CE as well as to prolong the in-band (13.5 ± 0.135 nm) spectral emission of a small Sn spherical target. The model predicts a ≈ 30 ns rising time duration for a linearly increasing intensity of triangular-flat-topped 1.064 μm laser pulse is necessary to obtain a maximum CE with a typical ≈ 40 μm diameter liquid Sn droplet.

Published

2019

23. Spectroscopic Studies of Laser-Based Far-Ultraviolet Plasma Light Source

Author

Majid Masnavi and Martin Richardson

Subjects

laser-produced plasma, plasma light source, far-ultraviolet spectroscopy, Seya–Namioka monochromator, radiation-hydrodynamics, collisional-radiative model, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

A series of experiments is described which were conducted to measure the absolute spectral irradiances of laser plasmas created from metal targets over the wavelength region of 123–164 nm by two separate 1.0 μm lasers, i.e., using 100 Hz, 10 ns, 2–20 kHz, 60–100 ns full-width-at-half-maximum pulses. A maximum radiation conversion efficiency of ≈3%/2πsr is measured over a wavelength region from ≈125 to 160 nm. A developed collisional-radiative solver and radiation-hydrodynamics simulations in comparison to the spectra detected by the Seya–Namioka-type monochromator reveal the strong broadband experimental radiations which mainly originate from bound–bound transitions of low-ionized charges superimposed on a strong continuum from a dense plasma with an electron temperature of less than 10 eV.

Published

2021

24. Optical emission spectroscopy and collisional-radiative modeling for low temperature Ar plasmas.

Author

Chai, Kil-Byoung and Kwon, Duck-Hee

Subjects

*INDUCTIVELY coupled plasma atomic emission spectrometry, *LOW temperature plasmas, *EMISSION spectroscopy, *OPTICAL spectroscopy

Abstract

Highlights • Diagnostics of electron temperature and density for low temperature Ar plasma by an optical emission spectroscopy combined with a collisional-radiative (CR) model has been investigated and compared with a Langmuir probe diagnostics. • The CR model considers two-temperature electron energy distribution function and an escape factor for finite cylinder geometry in a capacitively-coupled plasma and an inductively-coupled plasma. • Two-temperature EEDF model works well with the non-Maxwellian plasmas and the finite-cylinder escape factor gives plasma emission spectra close to the measured spectra. Abstract Reliability of electron temperature and density diagnostics by an optical emission spectroscopy and a collisional radiative modeling is investigated by being compared with a Langmuir probe diagnostics for capacitively-coupled and inductively-coupled Ar plasmas in the ranges of electron temperature 1.2–2.2 eV and density 4.0 × 10 9 − 8.0 × 10 11 cm − 3. Particular attention has been paid to radiation trapping and electron energy distribution function (EEDF) regarding the modeling. It is found that the two-temperature EEDF model gives better agreement of electron temperature diagnostics with the Langmuir probe measurement for non-Maxwellian plasma. The radiation trapping with an escape factor for finite size cylinder geometry reduces the discrepancy between the modeled and measured spectral line intensities compared to an escape factor for plane parallel geometry, specially for the optically thick 811.5 nm transition to the metastable level whose population depends on the diffusion rate. [ABSTRACT FROM AUTHOR]

Published

2019

25. Theoretical investigation on the spectra of M1 transition of W53+ ion.

Author

Xu, Yanlan, Wu, Cunqiang, Zhang, Denghong, Yang, Yang, Yao, Ke, Fu, Yunqing, Zhang, Ling, Koike, Fumihiro, Kato, Daiji, Murakami, Izmui, Sakaue, Hiroyuki A., Dong, Chenzhong, and Ding, Xiaobin

Subjects

*FUSION reactors, *IONS, *IONS spectra, *MAGNETIC dipoles

Abstract

The properties and spectrum of the highly charged tungsten ions draw more and more attention, due to its potential application in the next generation fusion reactor. The transition wavelength and rate of the magnetic-dipole transition between the levels of the ground configuration of W53+ ion in the range of 10 − 20 nm were calculated by Dirac–Fock–Slater (DFS) method with a local central potential and Multi-Configuration Dirac-Hartree-Fock (MCDHF) method, respectively. The results are consistent with the previous EBIT experimental data and other theoretical data. A collisional-radiative model was constructed, and the spectrum of magnetic-dipole transition of W53+ ion observed on EBIT (Y. Ralchenko et al., Phys. Rev. A. 83 , 032517, 2011) was reproduced theoretically. Another two new transitions near the wavelength of 16.683 nm and 18.018 nm are also assigned to the M1 transition of W53+ ion. • The EBIT spectrum of W53+ ion was reproduced and analyzed by CRM with accurate atomic data. • The new M1 transition between the ground configuration of W53+ ions were assigned to the experimental spectrum. • The MCDHF transition wavelength was used instead of DFS results to get better agreement with the experiments. [ABSTRACT FROM AUTHOR]

Published

2024

26. Investigation of a Collisional Radiative Model for Laser-Produced Plasmas

Author

Nicholas L. Wong, Fergal O’Reilly, and Emma Sokell

Subjects

collisional-radiative model, laser-produced plasma, ion distribution, ionization bottleneck, radiative recombination, collisional ioniztion, three-body recombination, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

Plasmas of a variety of types can be described by the collisional radiative (CR) model developed by Colombant and Tonan. From the CR model, the ion distribution of a plasma at a given electron temperature and density can be found. This information is useful for further simulations, and due to this, the employment of a suitable CR model is important. Specifically, ionization bottlenecks, where there are enhanced populations of certain charge states, can be seen in these ion distributions, which in some applications are important in maintaining large amounts of a specific ion. The present work was done by implementing an accepted CR model, proposed by Colombant and Tonon, in Python and investigating the effects of variations in the ionization energy and outermost electron subshell occupancy term on the positions of ionization bottlenecks. Laser Produced Plasmas created using a Nd:YAG laser with an electron density of ∼ne = 1021 cm−3 were the focus of this work. Plots of the collisional ionization, radiative recombination, and three-body recombination rate coefficients as well as the ion distribution and peak fractional ion population for various elements were examined. From these results, it is evident that using ionization energies from the NIST database and removing the orbital occupancy term in the CR model produced results with ionization bottlenecks in expected locations.

Published

2020

27. 小特集：磁場閉じ込め核融合装置における水素原子分子輸送研究の新展開 ２．要素モデルの統合が実現する壁から プラズマまでを含めた中性粒子輸送研究

Author

SAITO, Seiki, NAKAMURA, Hiroaki, SAWADA, Keiji, KAWAMURA, Gakushi, and KOBAYASHI, Masahiro

Subjects

peripheral plasma transport, plasma wall interaction, tungsten, neutral transport code, collisional-radiative model, molecular assisted recombination, carbon, rovibrational population, EMC3-EIRENE code, molecular dynamics

Abstract

非接触をはじめとするダイバータプラズマの諸現象を理解するため，壁での粒子リサイクリング，荷電粒子，中性粒子を扱うコードの統合を進めている．水素分子には，電子状態のほか，回転および振動の内部自由度があり，分子活性化再結合をはじめとするプラズマ中の水素分子の各種の反応速度係数は，水素分子の始状態の振動・回転量子数により，数桁にわたって変化する．また，低温のプラズマでは，プラズマ中の電子やプロトン衝突による水素分子の振動・回転励起がプラズマのエネルギー損失チャンネルとして重要と考えられる．このため，水素分子の振動・回転状態を中性粒子やプラズマの輸送と組み合わせて解く統合モデルを開発した．

Published

2022

28. Collisional radiative model for the M1 transition spectrum of the highly-charged W54+ ions.

Author

Ding, Xiaobin, Yang, Jiaoxia, Zhu, Linfan, Koike, Fumihiro, Murakami, Izumi, Kato, Daiji, Sakaue, Hiroyuki A., Nakamura, Nobuyuki, and Dong, Chenzhong

Subjects

*COLLISIONS (Physics), *RADIATIVE flow, *ION traps, *ELECTRON beams, *PLASMA gases

Abstract

A detailed-level collisional-radiative model for the M1 transition spectrum of the Ca-like W 54+ ion as observed in an electron beam ion trap (EBIT) was constructed based on atomic data calculated by the relativistic configuration interaction method and distorted wave theory. The present calculated transition energy, rate and intensity of W 54+ M1 transitions are compared with previous theoretical and experimental values. The results are in reasonable agreement with the available experimental and theoretical data. The synthetic spectrum explained the EBIT spectrum in the 12–20 nm region, while a new possibly strong transition has been predicted to be observable with an appropriate electron beam energy. The present work provides accurate atomic data that may be used in plasma diagnostics applications. [ABSTRACT FROM AUTHOR]

Published

2018

29. Theoretical investigation on the soft X-ray spectrum of the highly-charged W54+ ions.

Author

Ding, Xiaobin, Yang, Jiaoxia, Koike, Fumihiro, Murakami, Izumi, Kato, Daiji, Sakaue, Hiroyuki A, Nakamura, Nobuyuki, and Dong, Chenzhong

Subjects

*SOFT X rays, *X-ray spectroscopy, *TUNGSTEN ions, *RADIATIVE transfer, *PHASE transitions, *CALCIUM

Abstract

A detailed level collisional-radiative model of the E1 transition spectrum of Ca-like W 54+ ion has been constructed. All the necessary atomic data has been calculated by relativistic configuration interaction (RCI) method with the implementation of Flexible Atomic Code (FAC). The results are in reasonable agreement with the available experimental and previous theoretical data. The synthetic spectrum has explained the EBIT spectrum in 29.5–32.5 Å , while several new strong transitions has been predicted to be observed in 18.5–19.6 Å for the future EBIT experiment with electron density n e = 10 12 cm −3 and electron beam energy E e = 18.2 keV. [ABSTRACT FROM AUTHOR]

Published

2018

30. Population trapping: The mechanism for the lost resonance lines in Pm-like ions.

Author

Kato, Daiji, Sakaue, Hiroyuki A., Murakami, Izumi, and Nakamura, Nobuyuki

Subjects

*PROMETHIUM, *BISMUTH, *ATOM trapping, *ION traps, *COLLISIONAL excitation

Abstract

We report a population kinetics study on line emissions of the Pm-like Bi 22+ performed by using a collisional-radiative (CR) model. Population rates of excited levels are analyzed to explain the population trapping in the 4 f 13 5 s 2 state which causes the loss of the 5 s − 5 p resonance lines in emission spectra. Based on the present analysis, we elucidate why the population trapping is not facilitated for a meta-stable excited level of the Sm-like Bi 21+ . The emission line spectra are calculated for the Pm-like isoelectronic sequence from Au 18+ through W 13+ and compared with experimental measurements by electron-beam-ion-traps (EBITs). Structures of the spectra are similar for all of the cases except for calculated W 13+ spectra. The calculated spectra are hardly reconciled with the measured W 13+ spectrum using the compact electron-beam-ion-trap (CoBIT) [Phys. Rev. A 92 (2015) 022510]. [ABSTRACT FROM AUTHOR]

Published

2017

31. Determination of the Electron Density and Electron Temperature in A Magnetron Discharge Plasma Using Optical Spectroscopy and the Collisional-Radiative Model of Argon.

Author

Evdokimov, K., Konishchev, M., Pichugin, V., Pustovalova, A., Ivanova, N., and Sun', Ch.

Subjects

*ELECTRON density, *ELECTRON temperature, *MAGNETRON sputtering, *PLASMA flow, *COLLISIONS (Physics), *OPTICAL spectroscopy, *ARGON

Abstract

A method for determining the electron temperature and electron density in a plasma is proposed that is based on minimization of the difference between the experimental relative intensities of the spectral argon (Ar) lines and those same intensities calculated with the aid of the collisional-radiative model. The model describes the kinetics of the ground state and 40 excited states of the Ar atom and takes into account the following processes: excitation and deactivation of the states of the atom by electron impact, radiative decay of the excited states, self-absorption of radiation, ionization of excited states by electron impact, and quenching of metastable states as a consequence of collisions with the chamber walls. Using the given method, we have investigated the plasma of a magnetron discharge on a laboratory setup for intermediate-frequency magnetron sputtering for a few selected operating regimes. [ABSTRACT FROM AUTHOR]

Published

2017

32. Resonance-enhanced electron-impact excitation of Cu-like gold.

Author

Xia, L., Zhang, C.Y., Si, R., Guo, X.L., Chen, Z.B., Yan, J., Li, S., Chen, C.Y., and Wang, K.

Subjects

*GOLD, *EXCITATION spectrum, *APPROXIMATION theory, *RESONANCE, *ELECTRON impact ionization, *ELECTRONIC excitation

Abstract

Employing the independent-process and isolated-resonance approximations using distorted-waves (IPIRDW), we have performed a series of calculations of the resonance-enhanced electron-impact excitations (EIE) among 27 singly excited levels from the n ≤ 6 configurations of Cu-like gold (Au, Z = 79 ). Resonance excitation (RE) contributions from both the n = 4 → 4 − 7 and n = 3 → 4 core excitations have been considered. Our results demonstrate that RE contributions are significant and enhance the effective collision strengths (ϒ) of certain excitations by up to an order of magnitude at low temperature (10 6.1 K), and are still important at relatively high temperature (10 7.5 K). Results from test calculations of the resonance-enhanced EIE processes among 16 levels from the n ≤ 5 configurations using both the Dirac R -matrix (DRM) and IPIRDW approaches agree very well with each other. This means that the close-coupling effects are not important for this ion, and thus warrants the reliability of present resonance-enhanced EIE data among the 27 levels. The results from the collisional-radiative model (CRM) show that, at 3000 eV, near where Cu-like Au is most abundant, RE contributions have important effects (up to 25%) on the density diagnostic line intensity ratios, which are sensitive near 10 20 cm − 3 . The present work is the first EIE research including RE contributions for Cu-like Au. Our EIE data are more accurate than previous results due to our consideration of RE contributions, and the data should be helpful for modeling and diagnosing a variety of plasmas. [ABSTRACT FROM AUTHOR]

Published

2017

33. Impact of vibrationally resolved H 2 on particle balance in Eirene simulations

Author

Andreas Holm, Dirk Wünderlich, Mathias Groth, Petra Börner, Department of Applied Physics, Max-Planck-Institut für Plasmaphysik, Fusion and Plasma Physics, Forschungszentrum Jülich, Aalto-yliopisto, and Aalto University

Subjects

collisional-radiative model, Eirene, ddc:570, hydrogen molecules, Condensed Matter Physics, vibrational states

Abstract

openaire: EC/H2020/633053/EU//EUROfusion Funding Information: The authors would like to thank Professor U. Fantz and Professor D. Reiter for valuable discussions enabling this work. This work has been carried out within the framework of the EUROfusion Consortium and has received funding from the Euratom research and training programme 2014–2018 and 2019–2020 under grant agreement number 633053. The views and opinions expressed herein do not necessarily reflect those of the European Commission. This work was supported by the Academy of Finland under grant no. 13330050. Publisher Copyright: © 2022 The Authors. Contributions to Plasma Physics published by Wiley-VCH GmbH. To evaluate the impact of transport of metastable, vibrationally excited states of the hydrogen molecule in dense and cold plasmas each vibrational state must be simulated as an individual species. Eirene neutral gas simulations of a one-dimensional flux-tube using a metastable-resolved model indicate a 30–50% decrease in the effective dissociation rate compared to simulations using a metastable-unresolved setup, which consider a single molecular species. Zero-dimensional Eirene simulations omitting transport effects predict a 25–65% decrease in the effective dissociation rate due to differences between the metastable-unresolved AMJUEL and the metastable-resolved H2VIBR rates available in Eirene. The exclusion of molecular hydrogen depletion via electronically excited states and vibrational transitions (Formula presented.) from the metastable-resolved rates reduce the effective dissociation rate. By accounting for the difference caused by the different collisional-radiative treatment of the metastable-resolved rates compared to the metastable-unresolved rates, transport effects are expected to be relevant under detached divertor conditions. It is, however, not possible to individually assess the role of the collisional-radiative processes and transport on the effective dissociation rate using the currently available atomic and molecular rates for the metastable-resolved and metastable-unresolved Eirene setups.

Published

2022

34. Optical emission spectroscopy diagnostics for plasma parameters investigation in a Duo-Plasmaline surface-wave sustained discharge

Author

Lazhar Rachdi, Vladimir Sushkov, Marc Hofmann, and Publica

Subjects

Collisional-radiative model, Optical emission spectroscopy, Corona model, Argon, Surface-wave plasma, Instrumentation, Spectroscopy, Atomic and Molecular Physics, and Optics, Analytical Chemistry

Abstract

In this study, we used optical emission spectroscopy (OES) as a diagnostic tool in a Duo-Plasmaline surface-wave discharge. Argon plasma emission is recorded in order to calculate the electron density ne and the electron temperature Te in argon gas at a pressure range of 10-30 Pa. To describe argon emission, a corona model using different line ratios is compared to a more complete collisional-radiative model (CRM). It has been found that metastable states play an important role in the population model via electron impact excitation and radiation trapping and should be taken into account for the considered pressure range. The obtained parameters are in the range of 1.4 eV for the electron temperature and 5 × 1016 m-3 for the electron density.

Published

2022

35. Investigation of applicability of coronal and collisional-radiative plasma models in a high-frequency discharge

Subjects

collisional-radiative model, popula-tion modeling of atomic hydrogen, язык программирования python, моделирование населённости атома водорода, столкновительно-излучательная модель, coronal model, python programming language, корональная модель

Abstract

Тема выпускной квалификационной работы: «Исследование применимости корональной и столкновительно-излучательной моделей плазмы в высокочастотном разряде». Данная работа посвящена определению границ применимости корональной и столкновительно-излучательной моделей в высокочастотном разряде. Цель работы заключается в программной реализации расчёта и моделирования населённости атома водорода методами Ð²Ñ‹ÑˆÐµÐ¾Ð¿Ð¸ÑÐ°Ð½Ð½Ñ‹Ñ Ð¼Ð¾Ð´ÐµÐ»ÐµÐ¹. Результатом моделирования является набор Ð´Ð°Ð½Ð½Ñ‹Ñ , Ð´ÐµÐ¼Ð¾Ð½ÑÑ‚Ñ€Ð¸Ñ€ÑƒÑŽÑ‰Ð¸Ñ Ð½Ð°ÑÐµÐ»Ñ‘Ð½Ð½Ð¾ÑÑ‚ÑŒ на каждом уровне атома при Ñ€Ð°Ð·Ð½Ñ‹Ñ Ð¿Ð»Ð¾Ñ‚Ð½Ð¾ÑÑ‚ÑÑ Ñ€Ð°Ð·Ñ€ÑÐ´Ð° с постоянной температурой, при Ñ€Ð°Ð·Ð½Ñ‹Ñ Ñ‚ÐµÐ¼Ð¿ÐµÑ€Ð°Ñ‚ÑƒÑ€Ð°Ñ Ñ€Ð°Ð·Ñ€ÑÐ´Ð° с постоянной плотностью. Путём сравнения результатов определялась граница применимости корональной модели, при этом столкновительно-излучательная модель считалась заведомо более точной. Полученные значения населённости показывают, что с увеличение плотности точность корональной модели снижается. При Ð²Ñ‹ÑÐ¾ÐºÐ¸Ñ Ð¿Ð»Ð¾Ñ‚Ð½Ð¾ÑÑ‚ÑÑ Ð¿Ð»Ð°Ð·Ð¼Ñ‹ она является применимой только на Ð½Ð¸Ð·ÐºÐ¸Ñ ÑƒÑ€Ð¾Ð²Ð½ÑÑ (с главным квантовым числом порядка 10). С увеличением температуры корональная модель, наоборот, точнее описывает населённость атома.Данные результаты могут быть использованы в спектроскопии чистящего разряда, устраняющего примесные частицы с Ð¿Ð¾Ð²ÐµÑ€Ñ Ð½Ð¾ÑÑ‚Ð¸ Ð¾Ð¿Ñ‚Ð¸Ñ‡ÐµÑÐºÐ¸Ñ Ð·ÐµÑ€ÐºÐ°Ð». С помощью моделирования населённости Ð¿Ñ€Ð¸Ð¼ÐµÑÐ½Ñ‹Ñ Ñ‡Ð°ÑÑ‚Ð¸Ñ† становится возможным интерпретация Ð´Ð°Ð½Ð½Ñ‹Ñ ÑÐ¿ÐµÐºÑ‚Ñ€Ð¾ÑÐºÐ¾Ð¿Ð¸Ð¸ для определения концентрации частиц в плазме. Результаты данной работы позволяют сделать вывод, что корональная модель в большинстве случаев применима для задач спектроскопии высокочастотного разряда, поскольку описывает низкие уровни атома водорода с высокой точностью., The subject of the graduate qualification work is “Investigation of coronal and collision-radiation models applicability in high-frequency discharge”. The given work is devoted to define boundaries of applicability of coronal and collision-radiation models in high-frequency discharge. Purpose of the work is to program and to get numeric results of atomic hydrogen population. The result of the program is numerical data which describe population on each level with different discharge densities and equal temperature, with different discharge temperature and equal density. These data are compared to each other in order to define boundaries of coronal model applicability. During this process collision-radiation model considered to be much more accurate.Result of numerical modeling shows, that accuracy of coronal model decreases with growth of density. For high densities of plasma it can be used only for low levels (main quantum number of the order of 10). With increasing temperature, the coronal model, on the contrary, more accurately describes the population of the atom. These results can be used in cleaning discharge spectroscopy, which removes impurity particles from optical mirror surface. Analyses of spectroscopy data for defining impurity particles density become possible with the help of numerical modeling of population of such particles. Results of this work shows that coronal model in most cases can be applied for high-frequency discharge spectroscopy problems, because it describes the low levels of atomic hydrogen with high accuracy.

Published

2022

36. Effect of the generalized Breit interaction on the [formula omitted]-shell x-ray spectra of hot krypton plasmas.

Author

Zhou, Li, Yang, Zhihao, He, Zhencen, Luo, Tianluo, Duan, Mingliang, An, Zhu, and Hu, Zhimin

Subjects

*HIGH temperature plasmas, *X-ray spectra, *PLASMA diagnostics, *INERTIAL confinement fusion, *PLASMA density, *PLASMA temperature, *RELATIVISTIC plasmas

Abstract

• K-shell x-ray spectra of hot krypton plasmas were simulated by using a collision-radiative model, for which the atomic parameters were generated by using the flexible atomic code (FAC). • Effects of the generalized Breit interaction (GBI) on the atomic parameters and the K-shell x-ray spectra of hot krypton plasmas have been investigated, and thus the GBI effect on the accuracy of the plasma diagnostics has been estimated. • This work will contribute to plasma diagnostics in fusion science, due to that the krypton is used as a tracer to obtain the temperature and density in the inertial confinement fusion experiments, and it is used as a coolant in magnetic confinement fusion experiments. K -shell spectra are widely used for the plasma diagnostics in fusion science and astrophysics. Here, we report on a theoretical investigation of the relativistic and QED effects, i.e., the Breit interaction (BI) or the generalized Breit interaction (GBI), on the simulation of K -shell x-ray spectra of hot krypton plasmas. The simulation was conducted using a collisional-radiative model, for which the atomic parameters were generated by using the flexible atomic code. As expected, the present work shows that the BI and GBI produce similar effects for such a light element as krypton, which maximum difference of 3.7% in the emission spectra. When comparing to results calculated with just the Coulomb interaction, the GBI affects the specific line intensity by up to 15%, thus bringing about approximately 4%, 13% uncertainties for deducing the electron density and temperature of plasmas, respectively. [ABSTRACT FROM AUTHOR]

Published

2023

37. State-to-state modeling of ultrashort laser-induced plasmas.

Author

Morel, Vincent, Bultel, Arnaud, Schneider, Ioan, and Grisolia, Christian

Subjects

*ULTRASHORT laser pulses, *PLASMA gases, *THERMODYNAMIC equilibrium, *LASER-induced breakdown spectroscopy, *TUNGSTEN

Abstract

The question of the Local Thermodynamic Equilibrium (LTE) of laser-induced plasmas is crucial regarding the Laser-Induced Breakdown Spectroscopy (LIBS) technique. The most relevant way to assess theoretically the possible departure from LTE is to develop state-to-state models of the chemical species involved. The present paper illustrates such an elaboration in the case of aluminum and tungsten. Based on this state-to-state approach, the two collisional-radiative models CoRaM-Al and CoRaM-W are elaborated. They include elementary processes under electron and heavy particle impact in thermal non-equilibrium, spontaneous emission, radiative recombination and thermal Bremsstrahlung. These models are applied to the case of ultrashort laser-induced plasmas expanding in an argon gas at different pressure, for which a relevant collisional-radiative model is also elaborated to predict the propagation of the shock wave. The laser conditions are close to those used for a typical LIBS analysis under ultrashort regime. At high argon pressure (10 5 Pa), the relaxation of the plasma takes place according to a rather low departure from LTE, as revealed by the thorough examination of the Boltzmann plots derived from the state-to-state models. This relaxation occurs at temperature higher for aluminum than for tungsten, but close to 10,000 K from 200 ns. Conversely, at low pressure (10 Pa), the extinction of the plasma is observed at ∼ 500 ns, just after a phase corresponding to significant departure from equilibrium. These results support the idea of the choice of short gate delays close to the laser pulse for the LIBS characterization of tungsten matrices in tokamak-like conditions. [ABSTRACT FROM AUTHOR]

Published

2017

38. Evaluation of Fe XIV Intensity Ratio for Electron Density Diagnostics by Laboratory Measurements

Author

Tomoko Kawate, Izumi Murakami, Nagaaki Kambara, Daiji Kato, Yasuko Kawamoto, Hiroyuki A. Sakaue, Hirohisa Hara, Tetsutarou Oishi, and Nobuyuki Nakamura

Subjects

Nuclear and High Energy Physics, Electron density, Materials science, EBIT, ionized gas, Plasma, Electron, QC770-798, Condensed Matter Physics, Atomic and Molecular Physics, and Optics, Ion, Large Helical Device, Ionization, Excited state, Nuclear and particle physics. Atomic energy. Radioactivity, Atomic physics, collisional–radiative model, LHD, EUV spectroscopy, Electron beam ion trap, electron density diagnostics

Abstract

The intensity ratio of Fe XIV 264.765A/274.203A is useful to determine the electron density of solar corona, and the relationship between the electron density and the intensity ratio obtained from a model should be evaluated using laboratory plasmas to estimate the electron density more precisely. We constructed a new collisional–radiative model (CR-model) for Fe XIV (an Al-like iron ion) by considering the processes of proton-impact excitation and electron-impact ionization to the excited states of a Mg-like iron ion. The atomic data used in the CR-model were calculated using the HULLAC atomic code. The model was evaluated based on laboratory experiments using a compact electron beam ion trap, called CoBIT, and the Large Helical Device (LHD). The measured Fe XIV 264.785 Å/274.203 Å line intensity ratio with CoBIT was 1.869 ± 0.036, and it agreed well with our CR-model results. Concurrently, the measured ratio using LHD was larger than the results of our CR-model and CHIANTI. The estimated electron densities using our CR-model agreed with those from CHIANTI within a factor of 1.6–2.4 in the range of ne≈1010−11cm−3. Further model development is needed to explain the ratio in a high-electron density region.

Published

2021

39. The M1 transitions and visible spectra of W13+ ion.

Author

Liu, Yile, Wu, Cunqiang, Ding, Xiaobin, Zhang, Fengling, Zhang, Ling, Yao, Ke, Yang, Yang, Koike, Fumihiro, Murakami, Izumi, Kato, Daiji, Sakaue, Hiroyuki A., Nakamura, Nobuyuki, and Dong, Chenzhong

Subjects

*IONS spectra, *ELECTRON density, *PLASMA density, *ION traps, *ELECTRON plasma, *VISIBLE spectra, *ELECTRON beams

Abstract

The theoretical visible transitions and spectra of W13+ ion from the Electron Beam Ion Trap are investigated by constructing and solving a collisional-radiative model (CRM) within the Quasi-Steady-State approximation. The necessary atomic data for constructing the CRM have been calculated using the relativistic configuration interaction (RCI) method and distorted wave approximation. The present results are in reasonable agreement with the available experimental observations and theoretical calculations. The relative intensities of the M1 transitions between the ground and low-lying excited fine-structure levels have been found to strongly depend on the electron density from n e =109 cm−3 to n e =1012 cm−3, which might be useful for the future diagnosis of the electron density of the plasma. • The experimental visible spectrum of W13+ ion was analyzed by the collisional radiative modeling with accurate atomic data. • The M1 transition between the ground and excited configuration of W13+ ions were assigned to the experimental spectrum. • The dependence of the spectrum intensity on the electron density was explained. [ABSTRACT FROM AUTHOR]

Published

2022

40. On the electron energy distribution function in the high power impulse magnetron sputtering discharge

Author

Rudolph, Martin, Revel, Adrien, Lundin, Daniel, Hajihoseini, Hamidreza, Brenning, Nils, Raadu, Michael A., Anders, Andre, Minea, Tiberiu M., Gudmundsson, Jon Tomas, Rudolph, Martin, Revel, Adrien, Lundin, Daniel, Hajihoseini, Hamidreza, Brenning, Nils, Raadu, Michael A., Anders, Andre, Minea, Tiberiu M., and Gudmundsson, Jon Tomas

Abstract

We apply the ionization region model (IRM) and the Orsay Boltzmann equation for electrons coupled with ionization and excited states kinetics (OBELIX) model to study the electron kinetics of a high power impulse magnetron sputtering (HiPIMS) discharge. In the IRM the bulk (cold) electrons are assumed to exhibit a Maxwellian energy distribution and the secondary (hot) electrons, emitted from the target surface upon ion bombardment, are treated as a high energy tail, while in the OBELIX the electron energy distribution is calculated self-consistently using an isotropic Boltzmann equation. The two models are merged in the sense that the output from the IRM is used as an input for OBELIX. The temporal evolutions of the particle densities are found to agree very well between the two models. Furthermore, a very good agreement is demonstrated between the bi-Maxwellian electron energy distribution assumed by the IRM and the electron energy distribution calculated by the OBELIX model. It can therefore be concluded that assuming a bi-Maxwellian electron energy distribution, constituting a cold bulk electron group and a hot secondary electron group, is a good approximation for modeling the HiPIMS discharge., QC 20210601

Published

2021

41. Spectroscopic Studies of Laser-Based Far-Ultraviolet Plasma Light Source

Author

Martin Richardson and Majid Masnavi

Subjects

radiation-hydrodynamics, Technology, far-ultraviolet spectroscopy, Materials science, QH301-705.5, QC1-999, 02 engineering and technology, Radiation, laser-produced plasma, 01 natural sciences, Spectral line, law.invention, Optics, Seya–Namioka monochromator, law, collisional-radiative model, 0103 physical sciences, General Materials Science, Biology (General), QD1-999, Instrumentation, Monochromator, 010302 applied physics, Fluid Flow and Transfer Processes, business.industry, Physics, Process Chemistry and Technology, Energy conversion efficiency, General Engineering, Plasma, Engineering (General). Civil engineering (General), 021001 nanoscience & nanotechnology, Laser, Computer Science Applications, Chemistry, Wavelength, plasma light source, Electron temperature, TA1-2040, 0210 nano-technology, business

Abstract

A series of experiments is described which were conducted to measure the absolute spectral irradiances of laser plasmas created from metal targets over the wavelength region of 123–164 nm by two separate 1.0 μm lasers, i.e., using 100 Hz, 10 ns, 2–20 kHz, 60–100 ns full-width-at-half-maximum pulses. A maximum radiation conversion efficiency of ≈3%/2πsr is measured over a wavelength region from ≈125 to 160 nm. A developed collisional-radiative solver and radiation-hydrodynamics simulations in comparison to the spectra detected by the Seya–Namioka-type monochromator reveal the strong broadband experimental radiations which mainly originate from bound–bound transitions of low-ionized charges superimposed on a strong continuum from a dense plasma with an electron temperature of less than 10 eV.

Published

2021

42. The fast non-LTE code DEDALE.

Author

Gilleron, Franck and Piron, Robin

Abstract

We present Dédale, a fast code implementing a simplified non-local-thermodynamic-equilibrium (NLTE) plasma model. In this approach, the stationary collisional–radiative rates equations are solved for a set of well-chosen Layzer complexes in order to determine the ion state populations. The electronic structure is approximated using the screened hydrogenic model (SHM) of More with relativistic corrections. The radiative and collisional cross-sections are based on Kramers and Van Regemorter formula, respectively, which are extrapolated to derive analytical expressions for all the rates. The latter are improved thereafter using Gaunt factors or more accurate tabulated data. Special care is taken for dielectronic rates which are compared and rescaled with quantum calculations from the Averroès code. The emissivity and opacity spectra are calculated under the same assumptions as for the radiative rates, either in a detailed manner by summing the transitions between each pair of complexes, or in a coarser statistical way by summing the one-electron transitions averaged over the complexes. Optionally, n ℓ -splitting can be accounted for using a WKB approach in an approximate potential reconstructed analytically from the screened charges. It is also possible to improve the spectra by replacing some transition arrays with more accurate data tabulated using the SCO-RCG or FAC codes. This latter option is particularly useful for K-shell emission spectroscopy. The Dédale code was used to submit neon and tungsten cases in the last NLTE-8 workshop (Santa Fe, November 4–8, 2013). Some of these results are presented, as well as comparisons with Averroès calculations. [ABSTRACT FROM AUTHOR]

Published

2015

43. On the electron energy distribution function in the high power impulse magnetron sputtering discharge

Author

Adrien Revel, André Anders, Hamidreza Hajihoseini, Martin Rudolph, Jon Tomas Gudmundsson, Michael A. Raadu, Tiberiu Minea, Daniel Lundin, Nils Brenning, XUV Optics, MESA+ Institute, Leibniz Institute of Surface Engineering [Leipzig] (IOM), Laboratoire de physique des gaz et des plasmas (LPGP), Université Paris-Sud - Paris 11 (UP11)-Centre National de la Recherche Scientifique (CNRS), The Plasma & Coatings Physics group, Linköping University (LIU), Science Institute, University of Iceland, University of Iceland [Reykjavik], Université Paris-Saclay-Centre National de la Recherche Scientifique (CNRS), Alfven Laboratory, Royal Institute of Technology [Stockholm] (KTH ), Department of Space and Plasma Physics [Stockholm], KTH School of Electrical Engineering, and Royal Institute of Technology [Stockholm] (KTH )-Royal Institute of Technology [Stockholm] (KTH )

Subjects

Materials science, FOS: Physical sciences, Applied Physics (physics.app-ph), Electron, Impulse (physics), 01 natural sciences, Secondary electrons, 010305 fluids & plasmas, Collisional-radiative model, [PHYS.PHYS.PHYS-PLASM-PH]Physics [physics]/Physics [physics]/Plasma Physics [physics.plasm-ph], Ionization, 0103 physical sciences, Electron energy distribution function, ComputingMilieux_MISCELLANEOUS, 010302 applied physics, 22/2 OA procedure, High power impulse magnetron sputtering, Physics - Applied Physics, Sputter deposition, Condensed Matter Physics, Boltzmann equation, Physics - Plasma Physics, Plasma Physics (physics.plasm-ph), Excited state, High-power impulse magnetron sputtering, Atomic physics

Abstract

We apply the ionization region model (IRM) and the Orsay Boltzmann equation for electrons coupled with ionization and excited states kinetics (OBELIX) model to study the electron kinetics of a high power impulse magnetron sputtering (HiPIMS) discharge. In the IRM the bulk (cold) electrons are assumed to exhibit a Maxwellian energy distribution and the secondary (hot) electrons, emitted from the target surface upon ion bombardment, are treated as a high energy tail, while in the OBELIX the electron energy distribution is calculated self-consistently using an isotropic Boltzmann equation. The two models are merged in the sense that the output from the IRM is used as an input for OBELIX. The temporal evolutions of the particle densities are found to agree very well between the two models. Furthermore, a very good agreement is demonstrated between the bi-Maxwellian electron energy distribution assumed by the IRM and the electron energy distribution calculated by the OBELIX model. It can therefore be concluded that assuming a bi-Maxwellian electron energy distribution, constituting a cold bulk electron group and a hot secondary electron group, is a good approximation for modeling the HiPIMS discharge.

Published

2021

44. Optical emission spectroscopy diagnostics for plasma parameters investigation in a Duo-Plasmaline surface-wave sustained discharge.

Author

Rachdi, Lazhar, Sushkov, Vladimir, and Hofmann, Marc

Subjects

*EMISSION spectroscopy, *PLASMA diagnostics, *OPTICAL spectroscopy, *PLASMA spectroscopy, *ARGON plasmas, *INDUCTIVELY coupled plasma atomic emission spectrometry

Abstract

In this study, we used optical emission spectroscopy (OES) as a diagnostic tool in a Duo-Plasmaline surface-wave discharge. Argon plasma emission is recorded in order to calculate the electron density n e and the electron temperature T e in argon gas at a pressure range of 10–30 Pa. To describe argon emission, a corona model using different line ratios is compared to a more complete collisional-radiative model (CRM). It has been found that metastable states play an important role in the population model via electron impact excitation and radiation trapping and should be taken into account for the considered pressure range. The obtained parameters are in the range of 1.4 eV for the electron temperature and 5 × 1016 m−3 for the electron density. [Display omitted] • Development and comparison of emission models for argon Duo-Plasmaline plasma. • Assessment of importance of each process included in the emission model. • Comparison with experimental 2p lines in optical emission spectrum. • Calculation of electron temperature and density by experimental fitting. [ABSTRACT FROM AUTHOR]

Published

2022

45. Dynamics of a femtosecond/picosecond laser-induced aluminum plasma out of thermodynamic equilibrium in a nitrogen background gas.

Author

Morel, Vincent, Bultel, Arnaud, Annaloro, Julien, Chambrelan, Cédric, Edouard, Guillaume, and Grisolia, Christian

Subjects

*ALUMINUM compounds, *NITROGEN, *FEMTOSECOND lasers, *PICOSECOND pulses, *THERMODYNAMIC equilibrium, *LASER pulses

Abstract

Beyond the experimental studies, the assessment of the ability of ultra-short (femto or picosecond) laser pulses to provide correct estimates of the elemental composition of unknown samples using laser-induced breakdown spectroscopy requires the modeling of a typical situation. The present article deals with this modeling for aluminum in nitrogen. A spherical layer model is developed. The central aluminum plasma is produced by the ultra-short pulse. This plasma is described using our collisional–radiative model CoRaM-Al in an upgraded version involving 250 levels. Its expansion and relaxation take place in nitrogen, where the formation and the propagation of a shock wave are taken into account. In this shocked nitrogen layer, the equilibrium conditions are assumed. Mass, momentum and energy conservation equations written under an Eulerian form are used to correctly model the global dynamics. Energy losses are due to radiative recombination, thermal Bremsstrahlung and spontaneous emission. These elementary processes are implemented. The only input parameters are the pulse energy E 0 , the ablated mass M of the sample and the pressure p 0 of the surrounding gas. The equilibrium composition involving N 2 , N, N 2 + , N + and free electrons of the shocked nitrogen layer is calculated from the thermodynamic database of our collisional–radiative model CoRaM-N 2 . The conditions E 0 = 10 mJ and M ≃ 10 − 10 kg corresponding to a 532 nm laser pulse are chosen. The model assumes the initial equilibrium of the aluminum plasma produced by the laser pulse absorbed by the sample. Then, owing to the significant overpressure with respect to the background gas ( p 0 is assumed atmospheric), the surrounding gas starts to be compressed while the propagation of a shock wave takes place. The shock layer maximum pressure is obtained at approximately 20 ns. At this characteristic time, the nitrogen pressure is around 400 times the atmospheric pressure. A shock velocity of 7 km s − 1 is predicted. The central plasma is characterized by a rapidly decreasing pressure, which leads for a while to a very low temperature (3500 K) with respect to the initial one (65,000 K). Then, the aluminum plasma is in a moderate nonequilibrium situation for Al. For Al + , the nonequilibrium degree is higher and the excited states are very weakly populated. Then, the aluminum plasma temperature increases due to the compression by the shock layer. Later, the pressure converges to p 0 owing to the momentum transfer with the shock layer, and the shock velocity decreases. The central plasma progressively tends to equilibrium. A maximum expansion of approximately 1 mm in radius and a lifetime of 40 μs are predicted for the aluminum plasma. [ABSTRACT FROM AUTHOR]

Published

2015

46. Rovibrationally Resolved Time-Dependent Collisional-Radiative Model of Molecular Hydrogen and Its Application to a Fusion Detached Plasma

Author

Keiji Sawada and Motoshi Goto

Subjects

collisional-radiative model, molecular hydrogen, vibrational, rotational, population, time-dependent solution, Nuclear and particle physics. Atomic energy. Radioactivity, QC770-798

Abstract

A novel rovibrationally resolved collisional-radiative model of molecular hydrogen that includes 4,133 rovibrational levels for electronic states whose united atom principal quantum number is below six is developed. The rovibrational X 1 Σ g + population distribution in a SlimCS fusion demo detached divertor plasma is investigated by solving the model time dependently with an initial 300 K Boltzmann distribution. The effective reaction rate coefficients of molecular assisted recombination and of other processes in which atomic hydrogen is produced are calculated using the obtained time-dependent population distribution.

Published

2016

47. Kinetic and fluid simulations of parallel electron transport during equilibria and transients in the scrape-off layer

Author

Sarah Newton, John Omotani, Robert Kingham, Fulvio Militello, and Stefan Mijin

Subjects

electron, Materials science, simulatio, Fluids & Plasmas, 0299 Other Physical Sciences, scrape-off layer, kinetic, PLASMAS, CODE, Electron, Kinetic energy, Molecular physics, Physics, Fluids & Plasmas, parallel, IMPLICIT, COLLISIONAL-RADIATIVE MODEL, EQUATION, fluid, Science & Technology, Physics, Condensed Matter Physics, Electron transport chain, Nuclear Energy and Engineering, Physical Sciences, HEAT-FLUX, 0202 Atomic, Molecular, Nuclear, Particle and Plasma Physics, DIVERTOR, Layer (electronics)

Abstract

We present the first parallel electron transport results obtained using the newly developed 1D transport code SOL-KiT. With the capability to switch between consistent kinetic and fluid models for the electrons, we explore and report the differences in both equilibrium and transient simulations. Significant kinetic effects are found during transients, especially in the behaviour of the electron sheath heat transmission coefficient, which shows up to an eightfold increase. Equilibria are obtained for an input power scan with parameters relevant to medium size tokamaks. Detached equilibria are found to persist to higher input powers when electrons are treated kinetically. Furthermore, non-monotonic behaviour of the electron sheath heat transmission coefficient is observed in the power scan, with values being up to 40% above the classical value. We discuss the implications of the pr

Published

2020

48. Spatially-Resolved Spectroscopic Diagnostics of a Miniature RF Atmospheric Pressure Plasma Jet in Argon Open to Ambient Air

Author

Florent P. Sainct, R. K. Gangwar, Luc Stafford, Antoine Durocher-Jean, Sylvain Coulombe, Norma Yadira Mendoza Gonzalez, Diagnostic des Plasmas Hors Equilibres (DPHE), Institut national universitaire Champollion [Albi] (INUC), Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées, Département de Physique [Montréal], and Université de Montréal (UdeM)

Subjects

Materials science, Absorption spectroscopy, Population, chemistry.chemical_element, 02 engineering and technology, 01 natural sciences, optical emission spectroscopy, [SPI]Engineering Sciences [physics], Physics::Plasma Physics, collisional-radiative model, [PHYS.PHYS.PHYS-PLASM-PH]Physics [physics]/Physics [physics]/Plasma Physics [physics.plasm-ph], 0103 physical sciences, atmospheric pressure plasma jet, Astrophysics::Solar and Stellar Astrophysics, Emission spectrum, education, 010302 applied physics, education.field_of_study, Glow discharge, Argon, Atmospheric pressure, optical absorption spectroscopy, Rotational temperature, 021001 nanoscience & nanotechnology, chemistry, Physics::Space Physics, Electron temperature, Atomic physics, 0210 nano-technology

Abstract

The spatially-resolved electron temperature, rotational temperature, and number density of the two metastable Ar 1 s levels were investigated in a miniature RF Ar glow discharge jet at atmospheric pressure. The 1 s level population densities were determined from optical absorption spectroscopy (OAS) measurements assuming a Voigt profile for the plasma emission and a Gaussian profile for the lamp emission. As for the electron temperature, it was deduced from the comparison of the measured Ar 2 p i &rarr, 1 s j emission lines with those simulated using a collisional-radiative model. The Ar 1 s level population higher than 10 18 m - 3 and electron temperature around 2.5 eV were obtained close to the nozzle exit. In addition, both values decreased steadily along the discharge axis. Rotational temperatures determined from OH(A) and N 2 (C) optical emission featured a large difference with the gas temperature found from a thermocouple, a feature ascribed to the population of emitting OH and N 2 states by energy transfer reactions involving the Ar 1 s levels.

Published

2020

49. Étude électrique et spectroscopique des décharges à barrière diélectrique à la pression atmosphérique en milieux réactifs

Author

Guemmache, Karim, Stafford, Luc, and Naudé, Nicolas

Subjects

Mesures de courant locales, Densité d’atomes métastables, Hélium, Thin films, Pression atmosphérique, Spectroscopie, Electronic temperature, Dielectric barrier discharge, Helium, Décharge homogène, Collisional-radiative model, Température électronique, Coatings, Density of metastable atoms, Spectroscopy, Glow discharge, Couches minces, Spectroscopie d'émission optique à résolution temporelle, Local current measurement, Time resolved optical emission spectroscopy, Milieux réactifs, Modèle collisionnel-radiatif, Décharge à barrière diélectrique, Reactive media, DBD, Atmospheric pressure, Homogeneous discharge, Décharge luminescente

Abstract

Le travail présenté dans le cadre de ce mémoire s’intéresse à l’étude des plasmas à la pression atmosphérique en configuration décharge à barrière diélectrique (DBD), pertinents pour le traitement de surface. Plus spécifiquement, les DBDs à l’étude sont en milieux réactifs pour le dépôt de couches minces (multi)fonctionnelles, soit en présence d’un précurseur organosilicié (HMDSO) et/ou d’un agent oxydant (N₂O). L’étude est centrée sur l’analyse de deux propriétés fondamentales du plasma : la température électronique (Tₑ) et la densité des atomes d’hélium dans un état métastable (n_He(2³S)). La première est étudiée en ayant recours à des mesures des populations des niveaux n=3 de l’hélium par spectroscopie optique d’émission, alors que la seconde l’est à partir de ces mêmes mesures couplées à des mesures électriques. La particularité de cette étude est la mise au point de nouveaux diagnostics électriques et spectroscopiques pour réaliser des mesures résolues spatialement, c'est-à-dire en fonction du temps de résidence (t_res) du mélange gazeux injecté en continu. Dans les milieux réactifs étudiés, ces nouveaux diagnostics montraient des changements dans les caractéristiques courant-tension entre l’entrée et la sortie de la décharge. Cependant, Tₑ conservait un profil homogène spatialement alors que la n_He(2³S) se montrait relativement plus faible en entrée, de par leurs interactions avec les précurseurs et les impuretés présents dans ces milieux. L’analyse des signatures optiques du HMDSO dans le volume de la décharge a aussi permis de faire des liens avec les propriétés de surface des couches réalisées en conditions similaires. Notamment, les mesures de vitesse de dépôt observées sur les couches, étant plus faibles avec l’augmentation du t_res, ont pu être liées aux émissions des fragments carbonés, plus fortes en entrée, ainsi qu’à la n_He(2³S), plus faible à cet endroit, sachant que ces derniers jouent un rôle important dans la fragmentation du précurseur HMDSO. De plus, l’analyse de rapport d’intensités d’émissions de ces fragments semble montrée une tendance similaire aux rapports atomiques O/C obtenus par mesures de spectroscopie à rayon X (XPS) sur les couches produites, mais l’interprétation de ces évolutions se veut plus complexe., The work presented in this master’s thesis focuses on the study of atmospheric pressure plasmas in a dielectric barrier discharge (DBD) configuration, which are relevant for surface treatment. More specifically, the DBDs under study are in reactive media for the deposition of (multi)functional coatings, either in the presence of an organosilicon precursor (HMDSO) and/or an oxidizing agent (N₂O). The study focuses on the analysis of two fundamental plasma properties: the electron temperature (Tₑ) and the density of helium atoms in a metastable state (n_He(2³S)). The first is studied using measurements of the n = 3 level helium populations by optical emission spectroscopy, while the second is based on these same measurements coupled with electrical measurements. The peculiarity of this study is the development of new electrical and spectroscopic diagnoses to carry out spatially resolved measurements, that is depending on the residence time (t_res) of the gas mixture injected continuously. In the reactive media studied, these new diagnoses showed changes in the current-voltage characteristics between the entrance and the exit of the discharge. However, the Tₑ maintained a spatially homogeneous profile while the n_He(2³S) was relatively lower at entry, because of their interactions with the precursors and the impurities present in these media. The analysis of the HMDSO optical signatures in the discharge volume also made it possible to establish links with the surface properties of the coatings produced under similar conditions. In particular, the measurements of deposition rate observed on the coatings, being lower with the increase of the t_res, could be linked to the emissions of the carbonaceous fragments, stronger at the entrance, as well as to the n_He(2³S), weaker here, knowing that they play an important role in the fragmentation of the HMDSO precursor. Moreover, the analysis of emission intensity ratios of these fragments seems to show a similar trend to the O/C atomic ratios obtained by X-ray spectroscopy (XPS) measurements on the coatings produced, but the interpretation of these evolutions is more complex.

Published

2020

50. Étude de la cinétique chimique et des propriétés radiatives d'un plasma d'arc dédié à la synthèse de nanoparticules de carbone

Author

Hleli, Ali, LAboratoire PLasma et Conversion d'Energie (LAPLACE), Centre National de la Recherche Scientifique (CNRS)-Université Toulouse III - Paul Sabatier (UT3), Université Fédérale Toulouse Midi-Pyrénées-Université Fédérale Toulouse Midi-Pyrénées-Institut National Polytechnique (Toulouse) (Toulouse INP), Université Fédérale Toulouse Midi-Pyrénées, Université Paul Sabatier - Toulouse III, Université de Tunis El Manar, Philippe Teulet, Hassen Ghalila, Yann Cressault, and Riadh Riahi

Subjects

Propriétés thermiques, Nanotubes de carbone, Thermal properties, Quasi-thermal plasma, [SPI.PLASMA]Engineering Sciences [physics]/Plasmas, Carbon nanotubes, Emission spectra, C2 Swan, Arc électrique, Plasma quasi-thermique, Modèle collisionnel-radiatif, Collisional-radiative model, Spectre d'émission, Electrical arc, CN Violet

Abstract

The electric arc process or the quasi-thermal plasma is one of the most used to produce nanomaterials. The study of the physicochemical phenomena underlaying arcs can be achieved by means of collisional-radiative models to thoroughly describe the chemical composition with the use of the particles number conservation law in the plasma. This method allows a straightforward calculation of thermal properties. These models provide a realistic description of the arc-induced chemistry and allow better understanding of the deviations from local thermodynamic equilibrium. It is in this context that the present work is clearly situated, relating to develop multi-temperature numerical tools able to predict, the chemical composition of Ar-He-N2 mixtures in the presence of carbon, nickel and yttrium removal from electrodes, experimentally used for carbon nanotubes synthesis, and determine the radiative proprieties such as the emission spectra of the C2 Swan and the CN Violet systems frequently observed in nitrogen and carbon containing mixtures and useful for arc characterization and diagnostics : the determination of the rotational and the vibrational temperatures.; Le procédé de synthèse par arc électrique ou plasma quasi-thermique est l'un des plus usités pour la production de nanomatériaux. L'étude des phénomènes physico-chimiques sous-jacents peut être réalisée au moyen de modèles collisionnels-radiatifs, pour décrire plus finement la composition chimique en s'appuyant sur les lois de conservation du nombre de particules dans le plasma, et accéder ensuite aux propriétés thermiques. Ces modèles fournissent une description réaliste de la chimie induite par les arcs et permettent de prendre en compte les éventuels écarts à l'équilibre thermodynamique local. C'est dans ce contexte que se situe ce travail, relatif au développement des outils numériques multi-températures pour, prédire la composition chimique du mélange Ar-He-N2 en présence de carbone, nickel et yttrium provenant de l'ablation des électrodes, employé expérimentalement pour la synthèse de nanoparticules de carbone, et élaborer une base de données spectroscopiques permettant de décrire les phénomènes radiatifs dans des mélanges composés de l'azote et du carbone, notamment la détermination des spectres en émission des deux systèmes C2 Swan et CN Violet fréquemment observés et utiles pour la caractérisation et le diagnostic des arcs : détermination des températures de rotation et de vibration.

Published

2020