Experimental and simulated argon spectra in the 2.3-3.4 nm region from tokamak plasmas

Abstract: Experimental argon spectra in the 2.3-3.4 nm region from the Jet tokamak on a single null divertor configuration have been simulated. The spectra include lines from five ionization states, namely from Ar15+ Li-like to Ar11+ N-like ions. Collisional-radiative models have been constructed for these five Ar ions, considering electron collisional excitation and radiative decay as the populating processes of the excited states. These models give photon emission coefficients for the emitted lines at electron density… Show more

“…For this simulation both transport coefficients are the same as for the Ar seeded discharge of Ref. [21], implying, as found in several JET spectroscopic data analysis, the presence of a peripheral transport barrier, obtained reducing D and/or increasing V inward. The lack of other experimental spectroscopic data and/or of time resolved spectra hinders any verification of the used atomic data.…”

“…Until recently, simulations of full spectra were less frequent. These include, e. g., full simulation in the XUV range of n=2 to n=2 L-shell Ne, Ar and Fe spectra [18,19], of n=3 to n=2 L-shell Ne and Ar spectra [20,21], and of n=3 to n=3 M-shell Fe and Ni spectra [22,23]. The analysis of spectra emitted by hot and well-diagnosed magnetic fusion plasmas is important since it touches on atomic physics issues to be used in the analysis of high spectral resolution astrophysical observations, i.e.…”

“…on the determination of the electron temperature, electron density and elemental abundances. In most cases atomic data are supposed to be valid and the simulations give D(r) and V(r), like, e.g., in Refs [20,21]. But with high quality and large amount of spectroscopic data, it is possible to go further and to verify also S ion and α rec .…”

“…After evaluation of radial CSD, post-process subroutines are used to produce simulated spectra, using line photon emission coefficients (PECs) from collisionalradiative models (CRM). Like for Refs [18][19][20][21][22][23], the PECs have been obtained using the HULLAC code.…”

Spectral Line Shapes as a Diagnostic Tool in Magnetic Fusion

“…For this simulation both transport coefficients are the same as for the Ar seeded discharge of Ref. [21], implying, as found in several JET spectroscopic data analysis, the presence of a peripheral transport barrier, obtained reducing D and/or increasing V inward. The lack of other experimental spectroscopic data and/or of time resolved spectra hinders any verification of the used atomic data.…”

“…Until recently, simulations of full spectra were less frequent. These include, e. g., full simulation in the XUV range of n=2 to n=2 L-shell Ne, Ar and Fe spectra [18,19], of n=3 to n=2 L-shell Ne and Ar spectra [20,21], and of n=3 to n=3 M-shell Fe and Ni spectra [22,23]. The analysis of spectra emitted by hot and well-diagnosed magnetic fusion plasmas is important since it touches on atomic physics issues to be used in the analysis of high spectral resolution astrophysical observations, i.e.…”

“…on the determination of the electron temperature, electron density and elemental abundances. In most cases atomic data are supposed to be valid and the simulations give D(r) and V(r), like, e.g., in Refs [20,21]. But with high quality and large amount of spectroscopic data, it is possible to go further and to verify also S ion and α rec .…”

“…After evaluation of radial CSD, post-process subroutines are used to produce simulated spectra, using line photon emission coefficients (PECs) from collisionalradiative models (CRM). Like for Refs [18][19][20][21][22][23], the PECs have been obtained using the HULLAC code.…”

Spectral Line Shapes as a Diagnostic Tool in Magnetic Fusion

“…Not only the intense lines of 3d–2p transitions, but also 4d–2p or even 5d–2p lines were observed in their experiment. Mattioli et al (2001) analysed the experimental spectra of argon in the wavelength range 23–34 Å from jet tokamak plasmas, and simulated them using collisional–radiative models constructed for Ar xii –Ar xvi ions. To interpret these plasma spectra, one needs atomic data within n = 4 or even n = 5 configurations.…”

Identification and analysis of soft X-ray lines of Ar xiii-Ar xvi in laboratory and astrophysical plasmas

Benchmark calculation of electron-impact ionization cross sections and rate coefficients of atomic ions in Ar isonuclear sequence