Full hyperfine structure study of singly ionized tantalum

Bouazza, S.

doi:10.1088/0031-8949/86/01/015302

Cited by 9 publications

(9 citation statements)

References 33 publications

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“…Later, other palladium group ions were studied successfully with the same goal: Mo II [2], Ru II [3], Pd II [4] and Ag II [5]. Recently, we carried out fine structure (FS) studies of Zr II [6], Hf II [7], Ti II [8] and Ta II [9], enhancing previous works by giving more accurate spin-orbit and Slater integral values and very often for the first time the leading eigenvector percentages of levels and calculated Landé g-factors. Moreover, sometimes we eliminated erroneous levels reported in earlier analyses.…”

Section: Introductionmentioning

confidence: 99%

The second spectrum of niobium: I. Accurate fine structure study of even-parity levels

Bouazza¹

2013

Phys. Scr.

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For the first time, a parametric analysis of the fine and hyperfine structure for even-parity levels of Nb II, involving 17 configurations, has been performed. The interpretation has been carried out based on a linked-parameter method of level-fitting calculations in a large multiconfiguration basis. The sets of fine structure parameters, the leading eigenvector percentages of levels, as well as their calculated magnetic Landé g-factors are newly given. Furthermore, we confirm on the whole the validity of the attributions to term designations, previously proposed. The single-electron hyperfine structure parameters are determined in their entirety for 93 Nb II for the model space (4d + 5s) 4 with a good accuracy and confirmed by ab initio calculations. Finally, a complete list of the predicted magnetic hyperfine structure constants A of all levels of this model space was generated.

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Section: Introductionmentioning

confidence: 99%

The second spectrum of niobium: I. Accurate fine structure study of even-parity levels

Bouazza¹

2013

Phys. Scr.

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“…Furthermore the accuracy of the amplitude of the energy level eigenvector is known to have particularly a strong influence on the determination of the effective mono-electronic hyperfine structure parameters deduced from magnetic dipole A and electric quadrupole B constants, experimentally obtained. For these reasons we propose to extend previous fs studies, using a method successfully tested for atoms: Si I [31], Hf I [32], Zr I [33], and ions: Nb II [34] Ta II [35], V II [36]. This method should find particular application for systems composed of many Rydberg configurations mutually interacting.…”

Section: Fine Structure Considerations For Odd-parity Levelsmentioning

confidence: 99%

“…The last but not the least work was done by Hassini et al [8] who reported 138 levels derived from 617 spectral lines in the range 2536 to 24 786 cm −1 . The method applied here for fine and hyperfine structure studies was successfully used previously as regards neutral and singly ionized atoms: Zr I, Hf I, Nb II, Ta II, V II, Ti II [34][35][36]44,45], gathering the set of their studied configurations in model space when it was possible. In the fs calculations we took into account the basis setup consisted of the 7 interacting configurations: 5s 2 5p 2 6s, The spin-orbit integrals ξ nd and ξ 5p effect the interactions with distant configurations.…”

Section: Fine Structure Considerations For Even-parity Levelsmentioning

confidence: 99%

“…To give it experimental significance we have to weight it by the ratio of spin-orbit constants obtained thanks to fs study and ab initio calculations, i.e. to multiply it by ξ nl (f s)/ξ nl (ab initio) as we did for instance in previous work [35]. Using the expectation values of Table 12 is very satisfactory for two first calculated ratios but rather worse for the last one, maybe because we did not exploit directly some experimental A hfs constants of the 5s5p 4 levels (not available up to now) but only some bits existing in levels of other configurations (see index g in Tab.…”

Section: Hyperfine Structure Considerations For Even-parity Levelsmentioning

confidence: 99%

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Fine, hyperfine and Zeeman structures of levels of 123Sb I

2016

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Abstract. The hyperfine and Zeeman structures of 14 lines of isotope123 Sb covering the UV-NIR spectral range have been measured. The experimental data have been used in order to reanalyse and revise Sb I energy levels. We named majority of them for the first time since they were previously labelled only by their energy values, without any term designations. In both cases of odd-and even-parity levels we took into consideration up to 7 interacting configurations; the set of fine structure parameters and the leading eigenvector percentages of levels as well as their calculated Landé-factors are given. Semi-empirical hfs parameter values extracted from experimental data were compared with ab initio results computed by the use of Cowan code.

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“…Recently we carried out fs studies of some singly ionised atoms, e.g. Ta II [8] or Nb II [9], in an effort to complete previous works and to eliminate erroneous level assignments. This time we propose a similar work concerning V II, which presents high interest for astrophysical investigations since it is very useful in the study of the history of nucleosynthesis, chemically peculiar stars and the sun.…”

Section: Introductionmentioning

confidence: 99%

Fine Structure Analysis of the Configuration System of V II. Part II: Odd-Parity Levels

Bouazza¹,

Holt²,

Rosner³

et al. 2014

JMP

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The 3d 3 4p, 3d 3 5p and 3d 2 4s4p odd configurations of the V II spectrum have been reanalysed and three 3d 2 4s4p triplets are assigned higher energies than previously proposed. We have determined the fine structure parameters, the largest and next largest eigenvector percentages of levels, their calculated Landé gJ-factors and predicted positions for missing experimental levels up to 100,000 cm −1 for the 3d 2 4s4p configuration. Furthermore for the first time a hyperfine structure (HFS) parametric treatment, involving levels of these two configurations has been carried out. The deduced single-electron HFS parameter values are successfully checked with those obtained by means of ab initio calculations.

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Full hyperfine structure study of singly ionized tantalum

Cited by 9 publications

References 33 publications

The second spectrum of niobium: I. Accurate fine structure study of even-parity levels

The second spectrum of niobium: I. Accurate fine structure study of even-parity levels

Fine, hyperfine and Zeeman structures of levels of 123Sb I

Fine Structure Analysis of the Configuration System of V II. Part II: Odd-Parity Levels

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