The planar Multipole Resonance Probe: a functional analytic approach

Friedrichs, Michael; Oberrath, Jens

doi:10.1140/epjti/s40485-018-0049-x

Cited by 15 publications

(32 citation statements)

References 29 publications

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“…Another advantage of the PACP is that its design is relatively simple as compared with the MRP, which typically consists of two metallic hemispheres separated by a dielectric layer, a conical balun, dielectric tube, and coaxial cable. [26] The MRP can monitor n e , T e , and electron collision frequency, [25][26][27] whereas the PACP can monitor n e and V f . Each probe can measure, respectively, the different parameters.…”

Section: Methodsmentioning

confidence: 99%

“…Several other probe methods that are effective in PECVD environments have been proposed, such as the self-excited electron resonance spectroscopy (SEERS), the surface wave probe (SWP), multipole resonance probe (MRP), and capacitive probe (CP). [19][20][21][22][23][24][25][26][27][28][29][30][31] The compact combined sensor, which is used as a heat flux sensor and a planer LP, has also been developed. [32,33] SEERS, which is a passive plasma probe based on a general hydrodynamical discharge model, can monitor n e and the electron collision rate.…”

Section: Introductionmentioning

confidence: 99%

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Development of a novel plasma probe for the investigation and control of plasma‐enhanced chemical vapor deposition coating processes

Kasashima

Brenner

Vissing

2020

Plasma Processes & Polymers

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A plasma probe and measuring method were developed to simultaneously determine both the electron density, n e , and floating potential in plasmaenhanced chemical vapor deposition (PECVD) coating processes within lowpressure plasmas. The functionality of the probe with a high deposition rate is demonstrated on the basis of examples using hexamethyldisiloxane as a precursor gas. The results show that the developed probe can determine both the n e (∼10 15 m −3) and the time-varying floating potential. The results also indicate that the probe is effective for monitoring the changes in the plasma condition caused by the pressure and the gas flow rate during the coating process. This method can contribute to confirm the process and chamber conditions in PECVD processes.

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Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Development of a novel plasma probe for the investigation and control of plasma‐enhanced chemical vapor deposition coating processes

Kasashima

Brenner

Vissing

2020

Plasma Processes & Polymers

View full text Add to dashboard Cite

show abstract

“…A thin dielectric layer with covers the electrodes and chamber wall. As described in [14,16], we assume that the chamber wall is infinite and the insulator is ignorable. A naturally oriented Cartesian coordinate system (x, y, z) is used, which locates the dielectric at −d < z < 0 and the plasma at z > 0.…”

Section: Equilibrium and Unperturbed Trajectorymentioning

confidence: 99%

“…In the past decade, several planar-type APRS probes have been developed, such as the planar multipole resonance probe (pMRP) [10][11][12][13][14][15][16], curling probe [17][18][19], and flat cutoff probe [20][21][22]. These probes can be flatly embedded into the chamber wall or chuck for minimally invasive process monitoring.…”

Section: Introductionmentioning

confidence: 99%

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Kinetic investigation of the planar Multipole Resonance Probe under arbitrary pressure

Wang¹,

Friedrichs²,

Oberrath³

et al. 2021

Preprint

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Active plasma resonance spectroscopy (APRS) refers to a class of plasma diagnostic methods that use the ability of plasma to resonate at or near the electron plasma frequency for diagnostic purposes. The planar multipole resonance probe (pMRP) is an optimized realization of APRS.It has a non-invasive structure and allows simultaneous measurement of electron density, electron temperature, and electron-neutral collision frequency. Previous work has investigated the pMRP through the Drude model and collision-less kinetic model. The Drude model misses important kinetic effects such as collision-less kinetic damping. The collision-less kinetic model is able to capture pure kinetic effects. However, it is only applicable to the low-pressure plasma. To further study the behavior of the pMRP, we develop a collisional kinetic model in this paper, which applies to arbitrary pressure. In this model, the kinetic equation is coupled to the Poisson equation under the electrostatic approximation. The real part of the general admittance is calculated to describe the spectral response of the probe-plasma system. Both collision-less kinetic damping and collisional damping appear in the spectrum. This model provides a possibility to calculate the electron density, electron temperature, and electron-neutral collision frequency from the measurements.

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Measurement of localized plasma perturbation with hairpin resonator probes

et al. 2019

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In situ plasma diagnostics present the classical problem of the scientific measurement: how does one accurately measure a system without also perturbing it? The uncertainty in the degree of perturbation then reflects an inherent uncertainty in the diagnostic results. Microwave probes are no exception. This work discusses an experimental methodology for quantifying the local perturbation in hairpin resonator probe measurements. By pulsing the delivered power to a plasma, an electron density hairpin spike (HS) is readily detected at generator shutoff. The phenomenon is understood to arise from an apparent density rise as the plasma sheath collapses, thus raising the spatially averaged density measured between the hairpin tines. Other explanations for the density rise are eliminated, and the utility of the HS is presented. Under the conditions investigated, the HS provides an experimental comparison to a previous sheath correction factor developed by Sands et al.

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The planar Multipole Resonance Probe: a functional analytic approach

Cited by 15 publications

References 29 publications

Development of a novel plasma probe for the investigation and control of plasma‐enhanced chemical vapor deposition coating processes

Development of a novel plasma probe for the investigation and control of plasma‐enhanced chemical vapor deposition coating processes

Kinetic investigation of the planar Multipole Resonance Probe under arbitrary pressure

Measurement of localized plasma perturbation with hairpin resonator probes

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