Current status and new insights about the capacitively coupled electronegative plasma source: injection of energetic beam-like electrons to electrode

Makabe, Toshiaki

doi:10.1088/1361-6463/acaab6

Cited by 4 publications

(4 citation statements)

References 88 publications

(140 reference statements)

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“…The magnetic field strength required to induce the mode transition increases as the pressure increases. Furthermore, a new method involving the injection of an electron beam (EB) can modify the magnitude of electronegativity N N /n − e in the experimental and simulation results of oxygen DF-CCP [18].…”

Section: Introductionmentioning

confidence: 99%

Numerical characterization of capacitively coupled CF₄ plasmas modulated by anion beam injection

Zhou,

Xu,

Wang

et al. 2024

Plasma Sources Sci. Technol.

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In the study of electronegative CF4 capacitively coupled plasmas (CCP), plasma modulation is typically achieved by varying parameters such as pressure and voltage, et al. In this work, the particle-in-cell/Monte Carlo (PIC/MC) method is used to simulate modulation of CF4 CCP with injection of anions (F-) ion beam (FB). The results demonstrate that FB injection effectively enhances the dissociation collision process between F- ions and neutral molecules, thus altering the densities of electrons and ions. An effective modulation of the characteristic parameters of the plasma of CF4 can be achieved by controlling the current and energy of FB. Particularly noteworthy is the transition of the heating mode from the DA mode to the dissociation mode as the FB current increases to 0.038 A (energy fixed at 10 keV) or when the FB energy exceeds 10 keV (current fixed on 0.038 A). This transition is attributed to the generation of a substantial number of electrons through dissociative collisions. This approach provides insight into the controlled modulation of plasma characteristics in CF4 CCP, offering potential applications in various plasma-based technologies.

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Section: Introductionmentioning

confidence: 99%

Numerical characterization of capacitively coupled CF₄ plasmas modulated by anion beam injection

Zhou,

Xu,

Wang

et al. 2024

Plasma Sources Sci. Technol.

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“…noble gas) discharges include only two charged species: electrons and singly-charged atomic ions of the parent gas [22]. At higher pressures and/or in molecular gases this simple approach cannot be kept, in such settings a number of ionic species need to be accounted for in the calculations and an increasing number of elementary processes need to be considered [23][24][25][26][27][28][29][30].…”

Section: Introductionmentioning

confidence: 99%

Self-consistent calculation of the optical emission spectrum of an argon capacitively coupled plasma based on the coupling of particle simulation with a collisional-radiative model

Donkó,

Tsankov,

Hartmann

et al. 2024

J. Phys. D: Appl. Phys.

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We report the development of a computational framework for the calculation of the optical emission spectrum of a low-pressure argon capacitively coupled plasma, which is based on the coupling of a particle-in-cell / Monte Carlo collision simulation code with a diffusion-reaction-radiation code for Ar I excited levels. In this framework, the particle simulation provides the rates of the direct and stepwise electron-impact excitation and electron-impact de-excitation for 30 excited levels, as well as the rates of electron-impact direct and stepwise ionization. These rates are used in the solutions of the diffusion equations of the excited species in the second code, along with the radiative rates between a high number of Ar I transitions. The calculations also consider pooling ionization, quenching reactions, and radial diffusion losses. The electron energy distribution function is computed self-consistently, and the calculations reproduce reasonably well the experimentally measured optical emission spectrum of a symmetric capacitively coupled plasma source operated at 13.56MHz with 300V peak-to-peak voltage, in the 2-100Pa pressure range. The accuracy of the approach appears to be limited by the one-dimensional nature of the model, the treatment of the radiation trapping through the use of escape factors, and the effects of radiative cascades from higher excited levels not taken into account in the model.

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“…O 2 [24,25] and CF 4 [26][27][28], the formation (via electron attachment) and destruction (via recombination or mutual neutralization) of negative ions have to be accounted for as well in the simulations. With the appearance of multiple ionic species, an increasing number of elementary processes needs to be considered [29,30]. The predictive capability of any discharge model is based on the successful identification of the set of elementary processes that account for the main physical effects in the system and under the specific conditions.…”

Section: Introductionmentioning

confidence: 99%

Metastable argon atom kinetics in a low-pressure capacitively coupled radio frequency discharge

Hartmann

Korolov

Schulenberg

et al. 2023

Plasma Sources Sci. Technol.

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The kinetics of excited atoms in a low-pressure argon capacitively coupled plasma source are investigated by an extended Particle-in-Cell / Monte Carlo Collisions simulation code coupled with a Diffusion-Reaction-Radiation code which considers a large number of excited states of Ar atoms. The spatial density distribution of Ar atoms in the 1s$_5$ state within the electrode gap and the gas temperature are also determined experimentally using Tunable Diode Laser Absorption Spectroscopy. Processes involving the excited states, especially the four lower-lying 1s states are found to have significant effects on the ionization balance of the discharge. The level of agreement achieved between the computational and experimental results indicate that the discharge model is reasonably accurate and the computations based on this model allow the identification of the populating and de-populating processes of the excited states.

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Current status and new insights about the capacitively coupled electronegative plasma source: injection of energetic beam-like electrons to electrode

Cited by 4 publications

References 88 publications

Numerical characterization of capacitively coupled CF₄ plasmas modulated by anion beam injection

Numerical characterization of capacitively coupled CF₄ plasmas modulated by anion beam injection

Self-consistent calculation of the optical emission spectrum of an argon capacitively coupled plasma based on the coupling of particle simulation with a collisional-radiative model

Metastable argon atom kinetics in a low-pressure capacitively coupled radio frequency discharge

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Current status and new insights about the capacitively coupled electronegative plasma source: injection of energetic beam-like electrons to electrode

Cited by 4 publications

References 88 publications

Numerical characterization of capacitively coupled CF4 plasmas modulated by anion beam injection

Numerical characterization of capacitively coupled CF4 plasmas modulated by anion beam injection

Self-consistent calculation of the optical emission spectrum of an argon capacitively coupled plasma based on the coupling of particle simulation with a collisional-radiative model

Metastable argon atom kinetics in a low-pressure capacitively coupled radio frequency discharge

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Numerical characterization of capacitively coupled CF₄ plasmas modulated by anion beam injection

Numerical characterization of capacitively coupled CF₄ plasmas modulated by anion beam injection