Circular dichroism in core photoelectron emission from (1×1) oxygen on W(110): experiment and multiple-scattering theory

Circular dichroism in core photoelectron emission from (1×1) oxygen on W(110): experiment and multiple-scattering theory

We have measured the circular dichroism in angular distributions (CDAD) of W 4f emission from a stable one-monolayer structure of oxygen on W(110) that is locally (1×1) in character. Photoelectrons were excited at kinetic energies of approximately 250 eV from the two chemically-shifted peaks present...

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Bibliographic Details
Published in:Journal of electron spectroscopy and related phenomena Vol. 106; no. 1; pp. 7 - 28
Main Authors: Ynzunza, R.X., Daimon, H., Palomares, F.J., Tober, E.D., Wang, Z., Garcı́a de Abajo, F.J., Morais, J., Denecke, R., Kortright, J.B., Hussain, Z., Van Hove, M.A., Fadley, C.S.
Format: Journal Article
Language:English
Published: Elsevier B.V 2000
Subjects:
Electron–solid interactions, scattering, diffraction
Low index single crystal surfaces
Oxygen
Photoelectron diffraction
Synchrotron radiation photoelectron spectroscopy
Tungsten
Oxygen
Synchrotron radiation photoelectron spectroscopy
Electron–solid interactions, scattering, diffraction
Low index single crystal surfaces
Photoelectron diffraction
Tungsten
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Summary:We have measured the circular dichroism in angular distributions (CDAD) of W 4f emission from a stable one-monolayer structure of oxygen on W(110) that is locally (1×1) in character. Photoelectrons were excited at kinetic energies of approximately 250 eV from the two chemically-shifted peaks present in these spectra (for bulk W and ‘oxide’ W bound to three O atoms) using right and left circularly polarized radiation (RCP and LCP, respectively), as well as linearly polarized radiation (LP) to provide a reference data set. Measurements were made over a large fraction of the solid angle above the surface, using a new beamline and experimental station at the Advanced Light Source. In switching between RCP and LCP, the data are found to show large CDAD effects of up to ±50%, as well as both peak ‘rotation’ effects (as first discussed by Daimon et al. in measurements on Si(100)), and more complex changes that are not so simply described. Multiple scattering diffraction calculations are found to very well reproduce all of the effects seen experimentally, and to represent a more accurate way of dealing with such effects than a prior peak rotation model. The LP data is also found to closely resemble the sum of the RCP and LCP intensities, and this is quantitatively explained. Such CDAD effects are thus expected to be generally seen in all work in solid materials, and important to allow for in studies of magnetic materials, with multiple scattering theory expected to yield a quantitative description of them.
ISSN:0368-2048
1873-2526
DOI:10.1016/S0368-2048(99)00083-3