Dielectronic recombination of the open 4d-shell of tungsten: W37+–W28+

Preval, S. P.; Badnell, N. R.; O’Mullane, M.

doi:10.1088/1361-6455/aaa182

Cited by 7 publications

(8 citation statements)

References 51 publications

(104 reference statements)

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“…Our previous study reported the electron-impact MRC only from the ground levels of the ions [24][25][26]. The current results are presented for thirteen temperature values in the range from 1.46•10 6 K to 7.29•10 9 K. It should be noted that peak abundance temperature obtained from the modeling for W 26+ equals 1×10 7 K [27,28]. The study of MRC includes the EA channels corresponding to the excitations to shells with principal quantum numbers n 8 and 9 n 25.…”

Section: Introductionmentioning

confidence: 76%

Maxwellian rate coefficients for electron-impact ionization of W ²⁶⁺

Kynienė

Merkelis

Sukys

et al. 2018

J. Phys. B: At. Mol. Opt. Phys.

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Excitation-autoionization (EA) and direct ionization (DI) Maxwellian rate coefficients (MRC) are presented for the levels of the ground configuration of the W26+ ion. The study of EA and DI cross sections is performed by applying the Dirac–Fock–Slater method within the level-to-level distorted-wave approximation including radiative damping. Excitations to the high-nl shells (n ≤ 25) are taken into account for the EA process. It is shown that electron-impact ionization from the different levels of the ground configuration produces a significant variation of MRC. Excitations to configurations with energy levels that straddle the ionization threshold play the main role in enhancing MRC for the highest level of the ground configuration. The difference of 40% among the EA MRC is determined for the levels of the ground configuration.

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Section: Introductionmentioning

confidence: 76%

Maxwellian rate coefficients for electron-impact ionization of W ²⁶⁺

Kynienė

Merkelis

Sukys

et al. 2018

J. Phys. B: At. Mol. Opt. Phys.

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“…Next, we show our results, and compare our rate coefficients to currently available literature. We then calculate an updated steady state ionization fraction including the data calculated in this work, and the data calculated in [11][12][13]. Finally, we conclude the paper, and discuss future work on the open 4f-shell of tungsten.…”

Section: Introductionmentioning

confidence: 94%

“…We now compare two sets of ionization fractions, calculated using recombination rate coefficient data from this work (61-to 73-like) and The Tungsten Project (00-to 46-like, [11,12,13]), and using the scaled data from Pütterich et al [3]. For the ionization fraction calculated using the present data, we use the data from Pütterich et al for 47-to 60-like, as we have not calculated data for these charge states yet.…”

Section: Steady State Ionizationmentioning

confidence: 99%

“…In an attempt to resolve the disagreement, The Tungsten Project was created to calculate a set of final-state resolution DR and RR rate coefficients for tungsten using the distorted wave code AUTOSTRUCTURE [8][9][10]. To date, the project has produced DR and RR rate coefficients for W 74+ -W 28+ [11][12][13]. All data from The Tungsten Project is currently hosted on the Atomic Data Analysis Structure (ADAS) website 5 in the standard adf09 (DR) and adf48 (RR) formats, the specifications for which can also be found on the ADAS website.…”

Section: Introductionmentioning

confidence: 99%

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Dielectronic recombination of lanthanide and low ionization state tungsten ions: W¹³⁺–W¹⁺

Preval

Badnell

O’Mullane

2018

J. Phys. B: At. Mol. Opt. Phys.

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The experimental thermonuclear reactor, ITER, is currently being constructed in Cadarache, France. The reactor vessel will be constructred with a beryllium coated wall, and a tungsten coated divertor. As a plasmafacing component, the divertor will be under conditions of extreme temperature, resulting in the sputtering of tungsten impurities into the main body plasma. Modelling and understanding the potential cooling effects of these impurities requires detailed collisional-radiative modelling. These models require a wealth of atomic data for the various atomic species in the plasma. In particular, partial, final-state resolved dielectronic/radiative recombination (DR/RR) rate coefficients for tungsten are required. In this manuscript, we present our calculations of detailed DR/RR rate coefficients for the lanthanide-like, and low ionization stages of tungsten, spanning charge states W 13+ to W 1+ . The calculations presented here constitutes the first detailed exploration of such low ionization state tungsten ions. We are able to reproduce the general trend of calculations performed by other authors, but find significant differences between ours and their DR rate coefficients, especially at the lowest temperatures considered.

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“…[124] In addition, a systematic theoretical calculations of recombination rate coefficients for tungsten ions have been performed by employing the AU-TOSTRUCTURE code and can be found in the references in Refs. [125][126][127].…”

Section: Applications In the Astrophysical And Fusion Plasmasmentioning

confidence: 99%

Atomic structure and collision dynamics with highly charged ions

Ma¹,

Zhang²,

Wen³

et al. 2022

Chinese Phys. B

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The research progresses on the investigations of atomic structure and collision dynamics with highly charged ions based on the heavy ion storage rings and electron ion beam traps in recent 20 years are reviewed. The structure part covers test of quantum electrodynamics and electron correlation in strong Coulomb field studied through dielectronic recombination spectroscopy and VUV/x-ray spectroscopy. The collision dynamics part includes charge exchange dynamics in ion-atom collisions mainly in Bohr velocity region, ion induced fragmentation mechanisms of molecules, hydrogen-bound and van de Waals bound clusters, interference and phase information observed in ion-atom/molecule collisions. With this achievements, two aspects of theoretical studies related to low energy and relativistic energy collisions are presented. The applications of data relevant to key atomic processes like dielectronic recombination and charge exchanges involving highly charged ions are discussed. At end of this review, some future prospects of research related to highly charged ions are proposed.

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Dielectronic recombination of the open 4d-shell of tungsten: W³⁷⁺–W²⁸⁺

Cited by 7 publications

References 51 publications

Maxwellian rate coefficients for electron-impact ionization of W ²⁶⁺

Maxwellian rate coefficients for electron-impact ionization of W ²⁶⁺

Dielectronic recombination of lanthanide and low ionization state tungsten ions: W¹³⁺–W¹⁺

Atomic structure and collision dynamics with highly charged ions

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Dielectronic recombination of the open 4d-shell of tungsten: W37+–W28+

Cited by 7 publications

References 51 publications

Maxwellian rate coefficients for electron-impact ionization of W 26+

Maxwellian rate coefficients for electron-impact ionization of W 26+

Dielectronic recombination of lanthanide and low ionization state tungsten ions: W13+–W1+

Atomic structure and collision dynamics with highly charged ions

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Dielectronic recombination of the open 4d-shell of tungsten: W³⁷⁺–W²⁸⁺

Maxwellian rate coefficients for electron-impact ionization of W ²⁶⁺

Maxwellian rate coefficients for electron-impact ionization of W ²⁶⁺

Dielectronic recombination of lanthanide and low ionization state tungsten ions: W¹³⁺–W¹⁺