Spectroscopic study of a carbon pellet ablation cloud

Goto, M.; Morita, S.; Koubiti, M.

doi:10.1088/0953-4075/43/14/144023

Cited by 13 publications

(17 citation statements)

References 30 publications

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“…[13]. Experimentally, the electron density in the ablation cloud is several orders of magnitude higher than that of the background plasma [14] . The temporal variation of the intensity of an emission line from the ablation cloud, for instance the Hα line, can be regarded as a measure of the spatial profile of the particle deposition by assuming that the intensity is proportional to the ablation rate.…”

Section: Estimate Of the Deposition Profilementioning

confidence: 96%

Estimate of the Deposition Profile of Carbon Pellets Using a High-Speed VUV Imaging System in the LHD

Ming

Ohdachi

Suzuki

2013

Plasma Sci. Technol.

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The deposition profile of the impurity pellet is measured by a two-dimensional fastframing vacuum ultraviolet (VUV) camera system in the large helical device (LHD). The fast framing camera selectively measures the emission from the hydrogen-like ions of carbon (C VI) with a frame rate of several kHz. From the emission profile of the hydrogen-like carbon ions, which are in the process of ionization, the initial deposition profile of the carbon is estimated using a simple one-dimensional transport model.

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Section: Estimate Of the Deposition Profilementioning

confidence: 96%

Estimate of the Deposition Profile of Carbon Pellets Using a High-Speed VUV Imaging System in the LHD

Ming

Ohdachi

Suzuki

2013

Plasma Sci. Technol.

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“…Equation (2) indicates that the electron interactions with the emitter result in a homogeneous broadening represented by a Lorentzian function whose full width at half maximum (FWHM) is proportional to the plasma electron density n e and inversely proportional to the square root of the electron temperature T e . It should be noted that the dipole reduced matrix elements are involved through the operator R.R present in relation Equation (2). As the line considered here is of the same type as the Li-like (Li I, B III, N V) 2s-2p, i.e., ∆n = 0 transitions, we will not discuss the validity of impact electronic collision operators such the above one.…”

Section: Magnetic Field-free Casementioning

confidence: 99%

“…To have a better understanding of why different approaches might end up with different best-fit plasma parameters, it was recommended to contributors willing to analyze the proposed experimental data cases to calculate the relevant line profiles for a small prescribed grid of parameters. The first experimental case concerned the C II 723-nm 1s 2 2s 2 3p 2 P°-1s 2 2s 2 3d 2 D line emitted by the ablation cloud of a carbon pellet injected in the Large Helical Device (LHD) [2]. The data for this case consisted of two spectra, both measured along a line-of-sight that is nearly perpendicular to the magnetic field line but with a polarizer rotated, either nearly parallel "horizontal", or nearly perpendicular "vertical", to the magnetic field (see Figure 1).…”

Section: Introductionmentioning

confidence: 99%

Line-Shape Code Comparison through Modeling and Fitting of Experimental Spectra of the C ii 723-nm Line Emitted by the Ablation Cloud of a Carbon Pellet

Koubiti

Goto

Ferri

et al. 2014

Atoms

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International audienceVarious codes of line-shape modeling are compared to each other through the profile of the C II 723-nm line for typical plasma conditions encountered in the ablation clouds of carbon pellets, injected in magnetic fusion devices. Calculations were performed for a single electron density of 10 17 cm −3 and two plasma temperatures (T = 2 and 4 eV). Ion and electron temperatures were assumed to be equal (T e = T i = T). The magnetic field, B, was set equal to either to zero or 4 T. Comparisons between the line-shape modeling codes and two experimental spectra of the C II 723-nm line, measured perpendicularly to the B-field in the Large Helical Device (LHD) using linear polarizers, are also discussed

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“…The parameters of the ablation cloud of the cylindrical carbon pellet (1.2mm L u 1.2mm I ) measured with spectroscopic method are n e =5x10 16 cm -3 and T e =2.5eV for CII and n e =5x10 14 cm -3 and T e =3.0eV for CIII [26,27]. A typical example of visible spectra measured from the ablation cloud is plotted in Fig.11.…”

Section: Visible Spectroscopy Of Tungstenmentioning

confidence: 99%

A study of tungsten spectra using large helical device and compact electron beam ion trap in NIFS

Morita

Dong

Goto

et al. 2013

AIP Conference Proceedings

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Tungsten spectra have been observed from Large Helical Device (LHD) and Compact electron Beam Ion Trap (CoBIT) in wavelength ranges of visible to EUV. The EUV spectra with unresolved transition array (UTA), e.g., 6g-4f, 5g-4f, 5f-4d and 5p-4d transitions for W +24-+33 , measured from LHD plasmas are compared with those measured from CoBIT with monoenergetic electron beam (d2keV). The tungsten spectra from LHD are well analyzed based on the knowledge from CoBIT tungsten spectra. The C-R model code has been developed to explain the UTA spectra in details. Radial profiles of EUV spectra from highly ionized tungsten ions have been measured and analyzed by impurity transport simulation code with ADPAK atomic database code to examine the ionization balance determined by ionization and recombination rate coefficients. As the first trial, analysis of the tungsten density in LHD plasmas is attempted from radial profile of Zn-like WXLV (W 44+ ) 4p-4s transition at 60.9Å based on the emission rate coefficient calculated with HULLAC code. As a result, a total tungsten ion density of 3.5x10 10 cm -3 at the plasma center is reasonably obtained. In order to observe the spectra from tungsten ions in lower-ionized charge stages, which can give useful information on the tungsten influx in fusion plasmas, the ablation cloud of the impurity pellet is directly measured with visible spectroscopy. A lot of spectra from neutral and singly ionized tungsten are observed and some of them are identified. A magnetic forbidden line from highly ionized tungsten ions has been examined and Cd-like WXXVII (W 26+ ) at 3893.7Å is identified as the ground-term fine-structure transition of 4f 2 3 H 5 -3 H 4 . The possibility of D particle diagnostic in D-T burning plasmas using the magnetic forbidden line is discussed.

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Spectroscopic study of a carbon pellet ablation cloud

Cited by 13 publications

References 30 publications

Estimate of the Deposition Profile of Carbon Pellets Using a High-Speed VUV Imaging System in the LHD

Estimate of the Deposition Profile of Carbon Pellets Using a High-Speed VUV Imaging System in the LHD

Line-Shape Code Comparison through Modeling and Fitting of Experimental Spectra of the C ii 723-nm Line Emitted by the Ablation Cloud of a Carbon Pellet

A study of tungsten spectra using large helical device and compact electron beam ion trap in NIFS

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