Kinetic simulation of the ideal multipole resonance probe

Active plasma resonance spectroscopy (APRS) is a process-compatible plasma diagnostic method, which utilizes the natural ability of plasmas to resonate on or near the electron plasma frequency. The multipole resonance probe (MRP) is a particular design of APRS that has a high degree of geometric and...

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Bibliographic Details
Published in:Journal of applied physics 2022-08, Vol.132 (6)
Main Authors: Gong, Junbo, Friedrichs, Michael, Oberrath, Jens, Brinkmann, Ralf Peter
Format: Article
Language:English
Subjects:
Applied physics
Damping
Dynamic models
Electric fields
Electron energy
Electron plasma
Material requirements planning
Multipoles
Plasma
Plasma frequencies
Plasma resonance
Resonance probes
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Summary:Active plasma resonance spectroscopy (APRS) is a process-compatible plasma diagnostic method, which utilizes the natural ability of plasmas to resonate on or near the electron plasma frequency. The multipole resonance probe (MRP) is a particular design of APRS that has a high degree of geometric and electric symmetry. The principle of the MRP can be described on the basis of an idealized geometry that is particularly suited for theoretical investigations. In a pressure regime of a few Pa or lower, kinetic effects become important, which cannot be predicted by the Drude model. Therefore, in this paper, a dynamic model of the interaction of the idealized MRP with a plasma is established. The proposed scheme reveals the kinetic behavior of the plasma that is able to explain the influence of kinetic effects on the resonance structure. Similar to particle-in-cell, the spectral kinetic method iteratively determines the electric field at each particle position, however, without employing any numerical grids. The optimized analytical model ensures the high efficiency of the simulation. Eventually, the presented work is expected to cover the limitation of the Drude model, especially for the determination of the pure collisionless damping caused by kinetic effects. A formula to determine the electron temperature from the half-width Δ ω is proposed.
ISSN:0021-8979
1089-7550
DOI:10.1063/5.0098031