Measurement of scandium and vanadium K-shell ionization cross sections by electron impact

An, Zhu; Tang, Chun; Zhou, Chen; Zhengming, Luo

doi:10.1088/0953-4075/33/18/315

Cited by 24 publications

(25 citation statements)

References 28 publications

(43 reference statements)

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“…cross section curves are summations over all the fine-structure transitions from the V 0 ground level. The available experimental data [35,36] agree well with our model (RDW + Extrapol.) within their respective error bars.…”

Section: Calculationssupporting

confidence: 84%

“…1, our calculated K-shell EII cross sections in V 0 are compared to the experimental data compiled by Liu et al [35], the measurements of An et al [36], the empirical XCVTS formula of Haque et al [34], the combination of distorted-wave-Born and plane-wave-Born approximations (DWBA + PWBA) of Bote et al [33], the MRBEB model of Guerra et al [30] and this latter model corrected for the density effect as suggested by Davies et al [1] (MRBEB + Density Effects). Our RDW + Extrapol.…”

Section: Calculationsmentioning

confidence: 86%

“…Beyond the dip, the density-effect correction proposed by Davies et al [1] attenuates the relativistic rise of both the RDW + Extrapol. and Guerra et al [30]; dash line: MRBEB model of Guerra et al [30] with the density-effect correction proposed by Davies et al [1]; dot-dash line: combination of distorted-waveBorn and plane-wave-Born approximations of Bote et al [33]; dot-double-dash line: empirical XCVTS formula of Haque et al [34]; full squares: compilation of experimental data by Liu et al [35]; full circles: measurements by An et al [36]. (2)).…”

Section: Calculationsmentioning

confidence: 99%

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Vanadium fine-structure K-shell electron impact ionization cross sections for fast-electron diagnostic in laser–solid experiments

Palmeri

Quinet

Batani

2015

Atomic Data and Nuclear Data Tables

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a b s t r a c tThe K-shell electron impact ionization (EII) cross section, along with the K-shell fluorescence yield, is one of the key atomic parameters for fast-electron diagnostic in laser-solid experiments through the K-shell emission cross section. In addition, in a campaign dedicated to the modeling of the K lines of astrophysical interest (Palmeri et al. (2012)), the K-shell fluorescence yields for the K-vacancy fine-structure atomic levels of all the vanadium isonuclear ions have been calculated.In this study, the K-shell EII cross sections connecting the ground and the metastable levels of the parent vanadium ions to the daughter ions K-vacancy levels considered in Palmeri et al. (2012) have been determined. The relativistic distorted-wave (DW) approximation implemented in the FAC atomic code has been used for the incident electron kinetic energies up to 20 times the K-shell threshold energies. Moreover, the resulting DW cross sections have been extrapolated at higher energies using the asymptotic behavior of the modified relativistic binary encounter Bethe model (MRBEB) of Guerra et al. (2012) with the density-effect correction proposed by Davies et al. (2013).

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Section: Calculationssupporting

confidence: 84%

Section: Calculationsmentioning

confidence: 86%

Section: Calculationsmentioning

confidence: 99%

See 1 more Smart Citation

Vanadium fine-structure K-shell electron impact ionization cross sections for fast-electron diagnostic in laser–solid experiments

Palmeri

Quinet

Batani

2015

Atomic Data and Nuclear Data Tables

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“…• Scandium: The experimental results by An et al [2] are not in agreement with any of the theories presented here, so new experimental data are required to better understand this case.…”

Section: K-shell Ionizationmentioning

confidence: 65%

Modified binary encounter Bethe model for electron-impact ionization

Guerra

Parente

Indelicato

et al. 2012

International Journal of Mass Spectrometry

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Theoretical expressions for ionization cross sections by electron impact based on the binary encounter Bethe (BEB) model, valid from ionization threshold up to relativistic energies, are proposed. The new modified BEB (MBEB) and its relativistic counterpart (MRBEB) expressions are simpler than the BEB (nonrelativistic and relativistic) expressions because they require only one atomic parameter, namely the binding energy of the electrons to be ionized, and use only one scaling term for the ionization of all sub-shells. The new models are used to calculate the K-, L- and M-shell ionization cross sections by electron impact for several atoms with Z from 6 to 83. Comparisons with all, to the best of our knowledge, available experimental data show that this model is as good or better than other models, with less complexity

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“…The experimental data are taken from Shah et al 33 for H; Nagy et al 34, Rejoub et al 35, Schram et al 36 and Shah et al 37 for He; Tawara et al 38 for N, O and Ne; Gulpe and Mehlhorn 39, 40 for N, O and Ne; Platten et al 41 for O, Ne, Si and Ar; Kamiya et al 42 for Al; Ishii et al 43 for Al, Si, Ca, Zn, Se, Y, Mo, Pd, In, Sn, Ba, Au, Pb, Bi and U; McDonald and Spicer 44 for Al; Hoffmann et al 45, 46 for Al, Si, Ar, Ca, Cr, Mn, Ni, Cu, Ge, Y, Ag, Sn, Au, Pb and Bi; Hink and Ziegler 47 for Al; Quarles and Semaan 48 for Ar; Shevelko et al 49 for K, Ca, Rb and Sr; Jessenberger and Hink 50 for Ti and Ni; He et al 51 for Ti, Cr and Mo; An et al 52 for V and 53 for Co; Scholz et al 54 for V, Cr, Mn, Fe, Co, Ni, Cu, Zn, Se, Rb, Sr, In, Sn, Ba, Pb and Bi; Luo et al 55 for Cr and Mo, and 56 for Mn; Llovet et al 56 for Mn and Fe; Shima et al 58 for Mn and Cu; Shima 59 for Cu; Pockman et al 60 for Ni; Genz et al 61 Ni, Cu and Ag; Seif al Naser et al 62 for Ni, Y, Ag, Ta, Au and Pb; Middleman et al 63 for Cu, Sr, Mo, In, Ta, Au and Bi; Hubner et al 64 for Cu; Tang et al 65 for Zn; Zhou et al 66 for Ga and Ge; Berenyi et al 69 for Se; Kiss et al 68 for Se; Berkner et al 69 for Pd and Au; Ricz et al 70 for Pd, Ag, In and Sn; Rester and Dance 71 for Ag, Sn and Au; Schlenk et al 72 for Ag; Davis et al 73 for Ag and Au.…”

Section: Resultsmentioning

confidence: 99%

Electron impact K‐shell ionization cross sections of atoms at relativistic energies

Patoary

Uddin

Haque

et al. 2008

Int J of Quantum Chemistry

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ABSTRACT:We propose an extension of the modified simplified-improved-binaryencounter dipole (MRIBED) model (Uddin et al., Phys Rev A 2005, 72, 032715), incorporating both the ionic and relativistic corrections, to investigate the K-shell ionization of atomic targets with atomic numbers Z ϭ 1 Ϫ 92 for incident energies up to 2 GeV. We also revisit our earlier models, MBELL (Haque et al. Phys Rev A 2006, 73, 012708) and MKLV (Uddin et al. Eur Phys J D 2006, 37, 361), for the K-shell ionization at these ultra-relativistic energies. The results from our extended version of MRIBED, MBELL, and MKLV models agree well with the experimental findings.

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Measurement of scandium and vanadium K-shell ionization cross sections by electron impact

Cited by 24 publications

References 28 publications

Vanadium fine-structure K-shell electron impact ionization cross sections for fast-electron diagnostic in laser–solid experiments

Vanadium fine-structure K-shell electron impact ionization cross sections for fast-electron diagnostic in laser–solid experiments

Modified binary encounter Bethe model for electron-impact ionization

Electron impact K‐shell ionization cross sections of atoms at relativistic energies

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