Development and characterization of a helicon plasma source

Sharma, N.; Chakraborty, Monojit; Neog, N. K.; Bandyopadhyay, M.

doi:10.1063/1.5030624

Cited by 18 publications

(13 citation statements)

References 34 publications

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“…Pictures were taken above 200 W RF power, the threshold to achieve a helicon plasma regime. The magnet was installed in the upper part of the discharge tube following the biggest value of the magnetic field (∼400 G) located upstream, which made the upper position produce a higher plasma density [3,19]. The brightest emissions are observed in the antenna region at the lowest pressure of 0.08 Pa.…”

Section: The Effect Of Neutral Pressure On Visible Light Emissionmentioning

confidence: 99%

“…Among them, the magnetic field is one of the most important factors. Under certain conditions, the plasma density is proportional to the magnetic field [15][16][17][18][19], except for the low field peak phenomenon [3,20,21]. Based on the results of experiments and simulations, Guo et al [22] deduced that the helicon wave absorption is enhanced when the density gradient in the axial direction is comparable to the axial magnetic field gradient.…”

Section: Introductionmentioning

confidence: 99%

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Effect of neutral pressure on the blue core in Ar helicon plasma under an inhomogeneous magnetic field

Wang

Liu²,

Sun³

et al. 2023

Plasma Sci. Technol.

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The effect of neutral pressure on blue core in Ar helicon plasma under inhomogeneous magnetic field was investigated in this work. The neutral pressure was set to 0.08 Pa, 0.36 Pa and 0.68 Pa. Nikon camera, intensifies charge coupled device (ICCD), optical emission spectrometer (OES), and Langmuir probe were used to diagnose the blue core in helicon plasma. Helicon plasma discharges experienced density jumps from E-, H- to W-mode before power just rose to 200 W. The plasma density increased and maintained the central peak with the increase of neutral pressure. However, the brightness of the blue core gradually decreased. It demonstrated that the relative intensity of Ar II spectral lines and the ionization ratio in the central area were reduced. Radial electron temperature profiles were flattened and became hollow as neutral pressure increased. It demonstrated that increasing the neutral pressure weakened the central heating efficiency dominated by helicon wave and strengthened the edge heating efficiency governed by the TG wave and skin effect. Therefore, the present experiment successfully reveals how the neutral pressure affects the heating mechanism of helicon plasma in inhomogeneous magnetic field.

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Section: The Effect Of Neutral Pressure On Visible Light Emissionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Effect of neutral pressure on the blue core in Ar helicon plasma under an inhomogeneous magnetic field

Wang

Liu²,

Sun³

et al. 2023

Plasma Sci. Technol.

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“…Helicon plasmas have attracted great attention in applications of material processing, surface treatment and electric thrusters due to their high ionization rate and high plasma density [1][2][3][4]. Most researches in helicon plasma sources have been carried out in a wide range of electron density from 10 10 to 10 14 cm −3 under relatively low external magnetic fields (0.1 mT-0.1 T) and radio-frequency (RF) power (1-5 kW) [5][6][7][8]. For ion heating in large linear devices, helicon plasma sources were also studied under higher magnetic fields (0.1-5 T) and higher RF powers (10-100 kW) [9][10][11][12].…”

Section: Introductionmentioning

confidence: 99%

“…the total electron collision frequency with ions ν e-i and neutrals ν m ). Using equations(5) and (8) to eliminate j  and E ,  one can obtain…”

mentioning

confidence: 99%

Comparison of heating mechanisms of argon helicon plasma in different wave modes with and without blue core

Cui

Zhang²,

Yuan³

et al. 2022

Plasma Sci. Technol.

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In this work, we investigated the discharge characteristics and heating mechanisms of argon helicon plasma in different wave coupled modes with and without blue core. Spatially resolved spectroscopy and emission intensity of argon atom and ion lines were measured via local optical emission spectroscopy (LOES), and electron density was measured experimentally by an RF-compensated Langmuir probe (LP). The relation between the emission intensity and the electron density was obtained and the wavenumbers of helicon and TG waves were calculated by solving the dispersion relation in wave modes. The results show that at least two distinct wave coupled modes appear in argon helicon plasma at increasing RF power, i.e., blue core (or BC) mode with a significant bright core of blue lights and a normal wave (NW) mode without blue core. The emission intensity of atom line 750.5 nm (IArI750.5 nm) is related to the electron density and tends to be saturated in wave coupled modes due to the neutral depletion, while the intensity of ion line 480.6 nm (IArII480.6 nm) is a function of the electron density and temperature, and increases dramatically as the RF power is increased. Theoretical analysis shows that TG waves are strongly damped at the plasma edge in NW and/or BC modes, while helicon waves are the dominant mechanism of power deposition or central heating of electrons in both modes. The formation of BC column mainly depends on the enhanced central electron heating by helicon waves rather than TG waves since the excitation of TG waves would be suppressed in this special anti-resonance region.

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“…11) After design and development of the system, characterization of the system is done and the transition to the helicon mode is established by various experiments. 12) With electronegative gases, HeliPS can produce electronegative plasma where positive ions and negative ions co-exist along with the electrons and background neutral gas molecules. We have used usual electropositive argon gas as the working gas together with the electronegative gases hydrogen and oxygen in the experiment.…”

Section: Introductionmentioning

confidence: 99%

Study on negative ion production by electronegative gases in a helicon source

Chakraborty

Sharma

Neog

et al. 2020

Jpn. J. Appl. Phys.

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A helicon plasma source (HeliPS) experimental set-up is developed to perform experiments in electronegative gases. Characterization of HeliPS is done in argon and oxygen discharge by varying the working pressure, magnetic field strength as well as radio frequency power at 13.56 MHz thereby identifying the optimum parameters for its operation. After characterization, experiments have been performed in electronegative gases such as oxygen and hydrogen to understand the effect of electron affinity in producing negative ions in such plasmas. To enhance the negative ion production, both magnetic filter and magnetic cage, used innovatively in such a system, shows interesting results on their influence in electronegative plasma production.

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Development and characterization of a helicon plasma source

Cited by 18 publications

References 34 publications

Effect of neutral pressure on the blue core in Ar helicon plasma under an inhomogeneous magnetic field

Effect of neutral pressure on the blue core in Ar helicon plasma under an inhomogeneous magnetic field

Comparison of heating mechanisms of argon helicon plasma in different wave modes with and without blue core

Study on negative ion production by electronegative gases in a helicon source

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