Dynamic behavior of valence-shell excitations of atomic neon studied by high-resolution inelastic x-ray scattering

Zhu, Lin-Fan; Xu, Wenzhen; Yang, Kè; Jiang, Zheng; Xu, Kailai; Xie, B. P.; Feng, D. L.; Hiraoka, Nozomu; Tsuei, Ku‐Ding

doi:10.1103/physreva.85.030501

Cited by 28 publications

(22 citation statements)

References 38 publications

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“…Furthermore, the ionization continuum also contributes to the elastic scattering in these experiments due to the same reason. So these previous elastic differential cross sections definitely have contributions from the inelastic scattering, which have been observed recently by inelastic x-ray-scattering experiments [8][9][10][11]. Because of the lack of experimental data, only Bentley et al [12,13] have calculated the elastic squared form factor of molecular hydrogen using ground wave functions prepared by different theoretical methods [14].…”

mentioning

confidence: 92%

“…With the dramatic development of third-generation synchrotron radiation and the crystal spectrometer, the brightness and the energy resolution of the x-ray-scattering technique have been greatly improved, which provides the possibility for high-precision measurements of the elastic differential cross section of x-ray scattering by atoms and molecules. Recently, the dynamic parameters of the valence shell excitations of some atoms and molecules have been measured by the x-ray-scattering technique with high-energy resolution in our group [8][9][10][11] and with moderateenergy resolution in Seidler's group [15,16], and some interesting excitation mechanisms have been revealed. In this Brief Report, we extend this experimental technique to study the elastic scattering of the x ray by a free molecule, and pure electronic structure information about the ground state is determined.…”

mentioning

confidence: 99%

“…The experimental setup used in this work is shown in Fig. 1 and has been described in our previous works [8][9][10][11]. Briefly, a Si(333) monochromator was used to achieve a high-energy resolution of 70 meV.…”

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confidence: 99%

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Determination of the electronic structure of atoms and molecules in the ground state: Measurement of molecular hydrogen by high-resolution x-ray scattering

Liu

Mei

et al. 2014

Phys. Rev. A

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The high-resolution x-ray-scattering technique is used to study the elastic scattering of atoms and molecules in the gas phase. The elastic squared form factor, which is the square of the Fourier transformation of the electron density distribution in position space and reveals the pure electronic structure of atoms and molecules in the ground state, of molecular hydrogen is measured at an incident photon energy of about 9889 eV and an energy resolution of about 70 meV. Although it is generally thought that the x-ray-scattering technique is identical to high-energy electron scattering, at least for elastic scattering these two techniques have an apparent difference, i.e., the pure electronic structure of a molecule in the ground state can be determined by x-ray scattering while it cannot be obtained by the high-energy electron impact method due to the interference between the scattering of separate nuclei and of the electrons in the target. The present experimental results match the theoretical calculations very well, which demonstrates that high-resolution x-ray scattering is a powerful tool to study the electronic structure of atoms and molecules in the ground state.

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confidence: 92%

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confidence: 99%

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Determination of the electronic structure of atoms and molecules in the ground state: Measurement of molecular hydrogen by high-resolution x-ray scattering

Liu

Mei

et al. 2014

Phys. Rev. A

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“…These have been studied before, theoretically 46,59 and experimentally using both EELS 60 and IXS. 10 The IXS measurements by Zhu et al…”

Section: Multi-electron Atomsmentioning

confidence: 99%

Ab initio calculation of inelastic scattering

Carrascosa

Kirrander

2017

Phys. Chem. Chem. Phys.

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Nonresonant inelastic electron and X-ray scattering cross sections for bound-to-bound transitions in atoms and molecules are calculated directly from ab initio electronic wavefunctions. The approach exploits analytical integrals of Gaussian-type functions over the scattering operator, which leads to accurate and efficient calculations. Ne atoms, open-shell C and Na atoms, and the N 2 molecule, with both inner-shell and valence electronic transitions considered. The method is appropriate for use in conjunction with quantum molecular dynamics simulations and for the analysis of new ultrafast X-ray scattering experiments.

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“…Further on, the high energy resolution of the end station (∼ 270 meV at low-q) could also render the present end-station as a powerful tool to reveal new insights related to low-energy non-dipole transitions in atoms and molecular systems through q-dependent studies within the low-q regime. [50][51][52][53][54][55][56][57][58] Moreover, XRS from semicore levels of heavy elements studied with the present instrument will give improved resolution of the overlapping multiplet featuresan important improvement for broader application of XRS to f-electron systems. [59][60][61][62] The continuous progress with the x-ray optics as well as the availability of modern undulator radiation beamlines, such as the anticipated new undulator beamline at SSRL dedicated to high resolution x-ray spectroscopy, will further boost this technique to a wide range of applications.…”

Section: Discussionmentioning

confidence: 99%

A high resolution and large solid angle x-ray Raman spectroscopy end-station at the Stanford Synchrotron Radiation Lightsource

Sokaras

Nordlund

Weng

et al. 2012

Review of Scientific Instruments

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We present a new x-ray Raman spectroscopy end-station recently developed, installed, and operated at the Stanford Synchrotron Radiation Lightsource. The end-station is located at wiggler beamline 6-2 equipped with two monochromators-Si(111) and Si(311) as well as collimating and focusing optics. It consists of two multi-crystal Johann type spectrometers arranged on intersecting Rowland circles of 1 m diameter. The first one, positioned at the forward scattering angles (low-q), consists of 40 spherically bent and diced Si(110) crystals with 100 mm diameters providing about 1.9% of 4π sr solid angle of detection. When operated in the (440) order in combination with the Si (311) monochromator, an overall energy resolution of 270 meV is obtained at 6462.20 eV. The second spectrometer, consisting of 14 spherically bent Si(110) crystal analyzers (not diced), is positioned at the backward scattering angles (high-q) enabling the study of non-dipole transitions. The solid angle of this spectrometer is about 0.9% of 4π sr, with a combined energy resolution of 600 meV using the Si (311) monochromator. These features exceed the specifications of currently existing relevant instrumentation, opening new opportunities for the routine application of this photon-in/photonout hard x-ray technique to emerging research in multidisciplinary scientific fields, such as energyrelated sciences, material sciences, physical chemistry, etc.

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Dynamic behavior of valence-shell excitations of atomic neon studied by high-resolution inelastic x-ray scattering

Cited by 28 publications

References 38 publications

Determination of the electronic structure of atoms and molecules in the ground state: Measurement of molecular hydrogen by high-resolution x-ray scattering

Determination of the electronic structure of atoms and molecules in the ground state: Measurement of molecular hydrogen by high-resolution x-ray scattering

Ab initio calculation of inelastic scattering

A high resolution and large solid angle x-ray Raman spectroscopy end-station at the Stanford Synchrotron Radiation Lightsource

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