Kai Siegbahn scite author profile

Electron spectra from an extensive series of sulfur compounds have been studied. A correlation has been established between the observed position of inner electron lines of sulfur and structure. The influence of structure on the electron binding energies is discussed in terms of a calculated atomic charge, based on the concepts of electronegativity and partial ionic character of bonds. The results are useful for the study of bonding and structure in sulfur chemistry, and are applied particularly to the discussion of the sulfur-oxygen bond (S=O).

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Vibrational and Vibronic Structure in the Valence Electron Spectra of CH₃X Molecules (X=F, Cl, Br, I, OH)

Karlsson

et al. 1977

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Valence electron spectra of the methyl halides and of methyl alcohol have been induced by means of the HeI resonance radiation at 21.22 eV. A large number of new vibrational bands are reported. The observation of these was facilitated by a high instrumental resolving power and fast data acquisition. In most cases the new bands are observed in 1 A 1→2 E transitions but also the electron band of the 1 A 1→2 A 1 transition of CH3I exhibits extensive progressions of closely spaced vibrational bands not previously reported. The vibrational structure of the 1 A 1→2 E transitions is affected by vibronic coupling. The structure of the 2e electron band of CH3Cl probably reflects the operation of the Ham effect. Calculations of the band structure including spin-orbit coupling are performed according to a model which is briefly described.

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Molecular Spectroscopy by Means of ESCA III.Carbon compounds

et al. 1970

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Carbon 1s energies are measured by ESCA for a series of aliphatic saturated compounds, carbonyl compounds, and some aromatic compounds. For convenient use in chemical structure analysis the binding energy shifts are correlated with a charge parameter obtained from electronegativity considerations. The shifts are also analyzed in terms of group shifts from which group electronegativities are derived. A comparison is made between the shifts in solid and gaseous samples and it is shown that solid state effects are small for non-ionic compounds. The observed shifts are then compared with results of semi-empirical and ab initio molecular orbital calculations on free molecules. The theoretical calculations are simplified by use of an electrostatic potential model.

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Electron spectroscopy for atoms, molecules, and condensed matter

1982

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Kai Siegbahn

ESCA applied to liquids

Molecular Spectroscopy by Means of ESCA II. Sulfur compounds. Correlation of electron binding energy with structure

Vibrational and Vibronic Structure in the Valence Electron Spectra of CH₃X Molecules (X=F, Cl, Br, I, OH)

Molecular Spectroscopy by Means of ESCA III.Carbon compounds

Electron spectroscopy for atoms, molecules, and condensed matter

Contact Info

Product

Resources

About

Kai Siegbahn

ESCA applied to liquids

Molecular Spectroscopy by Means of ESCA II. Sulfur compounds. Correlation of electron binding energy with structure

Vibrational and Vibronic Structure in the Valence Electron Spectra of CH3X Molecules (X=F, Cl, Br, I, OH)

Molecular Spectroscopy by Means of ESCA III.Carbon compounds

Electron spectroscopy for atoms, molecules, and condensed matter

Contact Info

Product

Resources

About

Vibrational and Vibronic Structure in the Valence Electron Spectra of CH₃X Molecules (X=F, Cl, Br, I, OH)