1993
DOI: 10.1088/0953-4075/26/3/016
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A close look at Ar photoion spectra around the K edge: non-diagram transitions and double photoionization

Abstract: Relative abundances of the various ionic charges resulting from photoionization of argon by monochromatked synchrotron radiation at energies between 3150 and 4900 eV have been measured with low statistical error. Despite the fact that already, right at the onset of K excitation (3203.5 eV), almost the full Is binding energy is deposited in the atom, the relative abundances change smoothly over the region of np excitation up to 6 eV above the limit. While this behaviour, caused by Rydberg shake-off (about 0.5 p… Show more

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Cited by 44 publications
(32 citation statements)
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“…The formulae for the two-electron matrix elements are given, for example, in [92,93], and their direct summation can be accomplished easily. The total line strength of radiative transitions (10) and the total Auger transition rate (12), (13) consist of the statistical multipliers, depending on the numbers of electrons in the active shells or subshells, and of the one-or two-electron quantities, depending only on the radial orbitals of these electrons. It enables the extrapolation of the global characteristics for the other transitions between the same shells (subshells) of the same element as well as for the same transitions in the atoms of different elements.…”
Section: Elementary Processes Following the Cascade And Their Averagementioning
confidence: 99%
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“…The formulae for the two-electron matrix elements are given, for example, in [92,93], and their direct summation can be accomplished easily. The total line strength of radiative transitions (10) and the total Auger transition rate (12), (13) consist of the statistical multipliers, depending on the numbers of electrons in the active shells or subshells, and of the one-or two-electron quantities, depending only on the radial orbitals of these electrons. It enables the extrapolation of the global characteristics for the other transitions between the same shells (subshells) of the same element as well as for the same transitions in the atoms of different elements.…”
Section: Elementary Processes Following the Cascade And Their Averagementioning
confidence: 99%
“…They give the dependence of the intensities of various ions on the photon energy. The more refined data are obtained when using the coincidence technique [10][11][12][13][14][15][16]. The photoelectron-photoion coincidence experiment enables one to separate the charge state distribution corresponding to the creation of a vacancy in a given subshell.…”
Section: Introductionmentioning
confidence: 99%
See 1 more Smart Citation
“…Radiative (CSD) of ions produced by the inner-shell transitions are due to displacement of vacancies to higher photoionization of rare gas atoms were performed at shells, while non-radiation transitions are accompanied some restricted energies of the photons that could be by ejection of an electron from the atomic sub-shells obtained from use of an x-ray tube [1][2][3][4]. The decay of inner-shell [10]. The de-Monochromatic synchrotron radiation sources are now excitation of this inner-shell hole via successive radiative being used for detailed studies of the ion charge state (x-ray) and non-radiative (Auger and Coster-Kronig) distributions as a function of the exciting photon energy transitions leads to highly charged ions.…”
Section: Introductionmentioning
confidence: 99%
“…This, in turn, is due to the low cross-sections of ME transitions in atoms even in the isothermal regime, and their even lower crosssections near threshold. The few existing studies employ mostly electron emission (Armen et al, 1985;Wark et al, 1991), X-ray absorption (Deutsch and Hart, 1986;Gomilsek et al, 2001;Schaphorst et al, 1993), and photoion (Doppelfeld et al, 1993;Levin et al, 1990) spectra. Most of the atoms studied until the last few years were low-Z (mostly light alkali metals) and inert gas atoms, which require only relatively simple calculations.…”
Section: Introductionmentioning
confidence: 99%