2018
DOI: 10.1016/j.jqsrt.2018.07.004
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MCDHF calculations of isotope shifts in neutral antimony

Abstract: a b s t r a c tAb initio multiconfiguration Dirac-Hartree-Fock (MCDHF) calculations have been carried out in order to determine the isotope shift (IS) electronic parameters of transitions belonging to electric dipole (E1) transition arrays 5s 2 5p 3 − 5s 2 5p 2 6s , 5s 2 5p 2 6s − 5s 2 5p 2 6p and 5s 2 5p 2 6s − 5s 2 5p 2 7p in neutral antimony, Sb I. In a correlation model limited to single and double excitations from the valence shells, these parameters, combined with the changes in mean-square nuclear charg… Show more

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Cited by 12 publications
(17 citation statements)
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“…as it was done [14][15][16][17] using the RIS3 program [18] designed as a module of the Grasp2K atomic structure package [19] .…”
Section: Isotope Shiftsmentioning
confidence: 99%
See 1 more Smart Citation
“…as it was done [14][15][16][17] using the RIS3 program [18] designed as a module of the Grasp2K atomic structure package [19] .…”
Section: Isotope Shiftsmentioning
confidence: 99%
“…We expect these three configurations to have significantly different electronic densities at the origin, according to their respective occupation number of the s orbitals [30] . Thanks to a simple occupation number-based analysis, we expect the following inequalities ρ(5 d 8 6 p) < ρ(5 d 7 6 s 6 p) < ρ(5 d 6 6 s 2 6 p) (14) to hold, in which the density increases with the occupation number of the 6 s orbital. Independent Dirac-Fock calculations for each configuration, assuming a common [Xe]4 f 14 core, confirm our intuitions since the computed electron densities, relative to the lowest value, are, in units of a −1 0 , ρ(5…”
Section: Sharing Rulementioning
confidence: 99%
“…These values differ on average by 11.5% when compared with measured values from [72]. This difference may reduce with the inclusion of deeper core-valence correlations and possibly core-core correlations [28,48,68]. Variation in nuclear deformation between the isotopes, not accounted for in these computations, may also contribute to the differ-ences between the experimental and computational isotope shifts.…”
Section: Results: Isotope Shiftsmentioning
confidence: 89%
“…Advents in modern computing allow for relativistic atomic structure calculations to be performed with results consistent with experimentally determined values to a few parts in 10 5 [21][22][23][24]. Such computations are also used to determine mass and field shift parameters of isotope shifts for King plot analyses [4,10,[25][26][27][28][29]. Low-lying energy levels in ytterbium have been explored through computational means [30][31][32][33][34][35][36][37][38][39][40][41][42][43][44], however they do not compute isotopes separately and often avoid the 3 P o 0 state.…”
Section: Introductionmentioning
confidence: 99%
“…We expect these three configurations to have significantly different electronic densities at the origin, according to their respective occupation number of the s orbitals [30]. Thanks to a simple occupation number-based analysis, we expect the following inequalities ρ(5d 8 6p) < ρ(5d 7 6s6p) < ρ(5d 6 6s 2 6p) (14) to hold, in which the density increases with the occupation number of the 6s orbital. Independent Dirac-Fock calculations for each configuration, assuming a common [Xe]4f 14 core, confirm our intuitions since the computed electron densities, relative to the lowest value, are, in units of a −1 0 , ρ(5d 8 6p) = 0 < ρ(5d 7 6s6p) = 103 < ρ(5d 6 6s 2 6p) = 230.…”
Section: Sharing Rulementioning
confidence: 99%