2001
DOI: 10.1006/adnd.2000.0849
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PHOTOELECTRON ANGULAR DISTRIBUTION PARAMETERS FOR ELEMENTS Z=1 TO Z=54 IN THE PHOTOELECTRON ENERGY RANGE 100–5000 eV

Abstract: Parameters of the angular distribution of photoelectrons along with the subshell photoionization cross sections calculated for all subshells of atoms with 1 ≤ Z ≤ 54 are presented in the Table for nine photoelectron energies in the range 100-5000 eV. Relativistic treatment of the photoeffect is used. The calculations have been performed within the quadrupole approximation with the central Dirac-Fock-Slater potential. The hole left by the emitted electron has been taken into account in the framework of the froz… Show more

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Cited by 362 publications
(243 citation statements)
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“…The VB spectra are dominated by non-bonding Fe 3d 6 orbital states in the vicinity of 2 eV below the Fermi level [5][6][7]. The relative intensity of this peak decreases with increasing the excitation energy owing to lower Fe 3d photoionization cross-section values [57]. The spectra from the chemically etched pyrite (lower panels) are quite similar to the abraded samples.…”
Section: Haxpesmentioning
confidence: 83%
See 1 more Smart Citation
“…The VB spectra are dominated by non-bonding Fe 3d 6 orbital states in the vicinity of 2 eV below the Fermi level [5][6][7]. The relative intensity of this peak decreases with increasing the excitation energy owing to lower Fe 3d photoionization cross-section values [57]. The spectra from the chemically etched pyrite (lower panels) are quite similar to the abraded samples.…”
Section: Haxpesmentioning
confidence: 83%
“…The spectra were acquired at photon energies from 2 keV to 6 keV and, in some cases, to 9 keV; the slit width was of 0.5 mm for all the excitation photon energies. Atomic ratios of elements (I i,h ) relative to S were calculated from the intensity area of the detail spectra for each energy (A i,h ) employing photoionization cross-sections ( i,h ) tabulated in [57,58] and the ones extrapolated for the higher energies, and taking into account IMFP ( (KE) i ) calculated for FeS 2 and Fe 9 S 10 employing TPP−2M formula [38] and analyzer's transmission function (T(KE) i ) [40][41][42] using following equation…”
Section: Methodsmentioning
confidence: 99%
“…photoionization cross section on the electron energy [25,26] closer to the conduction band than the energy that is given by the doping level alone. In this case, electron accumulation occurs at the surface and, depending on the amount of negative polarization, a two-dimensional electron gas can be formed.…”
Section: Figure 4: Dependence Of the Photoelectron Inelastic Mean Frementioning
confidence: 93%
“…Indeed, this is reflected in theoretical tabulations of these cross-sections, which predict the Ca 4s, Sr 5s and V 4s cross-sections are between 13 and 21 times larger than the O 2p cross-section at 4 keV. 20 In order to more accurately assess the origin of the differences in the HAXPES spectra between CVO and SCVO, we turn to a more quantitative analysis, in which the relative photoionization cross-sections for each orbital are fitted to the experimental data, yielding approximate empirical relative cross-sections. The data are first corrected for inelastic scattering processes, leading to the Shirley-type background shown by the dashed line in Fig.…”
Section: Valence Band Electronic Structurementioning
confidence: 99%
“…19 However, at such hard energies, there are several additional considerations. Most importantly, the cross section for photoionization drops off at higher energies, particularly for shallow binding energies at the valence band, 20 and practical instrument resolutions are poorer than at low energies. Additionally, the electron momentum distribution is focused into much tighter angles, meaning the coverage of the Brillouin zone of a typical HAXPES measurement is much broader, although recent technical advances have facilitated the momentum-resolved spectral function at hard x-ray energies.…”
Section: Introductionmentioning
confidence: 99%