On a heating mechanism for cold hydrogen and deuterium atoms produced at the edge of a tokamak plasma

Hey, John D.; Chu, C. C.; Hintz, E.

doi:10.1088/0953-4075/32/14/321

Cited by 46 publications

(142 citation statements)

References 34 publications

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“…͑18 and 30 allowed, 2 and 4 ⌬J forbidden͒. [5][6][7] The corresponding perturbed line strengths are calculated according to the method described in Ref. 23.…”

Section: Analysis Of the Zeeman Profiles And Discussionmentioning

confidence: 99%

“…1,2 Its quantitative estimate is required for the purpose of evaluating the particle fueling rate and controling the recycling neutrals in the long pulse discharge operation. 3,4 Information on neutral atoms has been obtained from spectroscopic measurements of the Zeeman ͑Paschen-Back͒ split profiles of lines emitted from the divertor or the periphery region in TEXTOR ͑Tokamak-Experiment for Technology Oriented Research͒, [5][6][7][8] JT-60U ͑Japan atomic energy research institute Tokamak-60 Upgrade͒, 9,10 Alcator C-Mod, [11][12][13] Doublet III-D, [14][15][16] ASDEX-U ͑Axially Symmetric Divertor Experiment Upgrade͒, 17,18 Tore Supra, 19,20 TRIAM-1M ͑Torus of Research Institute for Applied Mechanics͒ ͑Ref. 21͒ for hydrogen/deuterium, and in LHD ͑Large Helical Device͒ for helium.…”

Section: Introductionmentioning

confidence: 99%

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Polarization resolved Hα spectra from the large helical device: Emission location, temperature, and inward flux of neutral hydrogen

et al. 2005

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Spectral profiles of the Hα line emitted from the large helical device plasma [O. Motojima et al., Phys. Plasmas 6, 1843 (1999)] have been measured with polarization-separation optics and a high-resolution spectrometer. Besides the underlying high-temperature component, which probably arises from charge-exchange recombination, the profiles are interpreted as superpositions of Zeeman profiles for two different magnetic field strengths. The emission locations are thus identified on the magnetic field map; the emissions are localized in the inner and outer regions just outside the ergodic layer, and each field-strength contribution to the overall Zeeman profile represents two radiator temperatures, and inward atom flow velocities in the range of (1–7)×103m∕s.

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“…͑18 and 30 allowed, 2 and 4 ⌬J forbidden͒. [5][6][7] The corresponding perturbed line strengths are calculated according to the method described in Ref. 23.…”

Section: Analysis Of the Zeeman Profiles And Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Polarization resolved Hα spectra from the large helical device: Emission location, temperature, and inward flux of neutral hydrogen

et al. 2005

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“…͑2͒ the H Ϫ on their way to center can be cooled by excited argon atoms by the mechanism analogous to the one described in Ref. 8. The authors of Ref.…”

Section: B Negative Ion Population Fractionsmentioning

confidence: 96%

“…The authors of Ref. 8 showed that the heating of excited (nϭ3) hydrogen atoms by a hot deuteron background is ϳ10 times more effective than the heating of the atoms in ground state. In other words, the heat transfer between an excited atom and a hot background is much more effective than for the atom in ground state.…”

Section: B Negative Ion Population Fractionsmentioning

confidence: 99%

Effect of argon additive on H− density and temperature in volume negative ion source

Ivanov

Bacal

Rouillé

et al. 2004

Review of Scientific Instruments

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Various plasma parameters were measured for several hydrogen-argon mixtures in the multicusp H Ϫ ion source Camembert III, equipped with tantalum filaments. The density and the temperature of electrons were measured with the Langmuir probe situated in the center of the source and associated with the photodetachment diagnostics. The two-laser photodetachment diagnostics was used to obtain the temperatures of the two negative ion populations. At low hydrogen pressure ͑0.8 mTorr͒ a small concentration of argon additive enhances the hydrogen negative ion density ͑by approximately 60%͒, it also increases the electron density. The negative ion population fractions having the high-and low-temperature values behave differently when varying the total pressure in pure hydrogen and in hydrogen with argon additive. Several possible explanations of the drastic change of the relative ratio of negative ion populations when the argon fraction is increased, are proposed. Another interesting phenomenon observed during the experiments is the decrease with time of the H Ϫ density in the presence of argon. After adding the argon during the time interval of ϳ1 h the H Ϫ density goes down and finally establishes at a minimum value. The final H Ϫ density is lower than the H Ϫ density in pure hydrogen plasma before adding argon. This ''poisoning'' is discussed in terms of wall production of vibrationally excited H 2 molecules.

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“…So for instance, it is an established fact that the Zeeman effect, or more precisely the Paschen-Back effect, dominates the fine-structure splitting of the Balmer-α line emission at the plasma edge of fusion devices 27 . In case of Maxwellian distribution function of atoms every magnetic component of the spectral line is described using a Doppler profile taking into account the different source of excited atoms 27,28 . In the case of MSE measurements the emissions takes place predominantly in the static crossed electric and magnetic fields, being a subject of studies for high Rydberg states 26,29 .…”

Section: Atomic Model Of the Zeeman-stark Multipletmentioning

confidence: 99%

Influence of non-local thermodynamic equilibrium and Zeeman effects on magnetic equilibrium reconstruction using spectral motional Stark effect diagnostic

Reimer

Marchuk

Geiger

et al. 2017

Review of Scientific Instruments

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On a heating mechanism for cold hydrogen and deuterium atoms produced at the edge of a tokamak plasma

Cited by 46 publications

References 34 publications

Polarization resolved Hα spectra from the large helical device: Emission location, temperature, and inward flux of neutral hydrogen

Polarization resolved Hα spectra from the large helical device: Emission location, temperature, and inward flux of neutral hydrogen

Effect of argon additive on H− density and temperature in volume negative ion source

Influence of non-local thermodynamic equilibrium and Zeeman effects on magnetic equilibrium reconstruction using spectral motional Stark effect diagnostic

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