Growth and coverage dependent electronic structure of MgO on Ag(001)

HIghlights•Growth and coverage dependent electronic structure of MgO(001) ultrathin films on Ag(001).•Reduction of bulk MgO band gap at the ultrathin regime in proximity to Ag(001) substrate.•Coverage dependent ARPES band mapping of MgO(001).•Effects of image charge screening on the valence band ele...

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Published in:Surface science 2018-11, Vol.677, p.60-67
Main Authors: Barman, Sukanta, Kundu, Asish K., Menon, Krishnakumar S.R.
Format: Article
Language:English
Subjects:
Banded structure
Binding energy
Dislocations
Electronic structure
Energy gap
Image charge
LEED
Low energy electron diffraction
Magnesium
Magnesium oxide
Mathematical analysis
Metal oxides
Oxide thin film
Photoelectric emission
Photoelectron spectroscopy
Photoelectrons
Screening
Silver
Size effects
Spectrum analysis
Substrates
Thin films
Valence band
X ray photoelectron spectroscopy
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description HIghlights•Growth and coverage dependent electronic structure of MgO(001) ultrathin films on Ag(001).•Reduction of bulk MgO band gap at the ultrathin regime in proximity to Ag(001) substrate.•Coverage dependent ARPES band mapping of MgO(001).•Effects of image charge screening on the valence band electronic structure. [Display omitted] Growth and coverage dependent electronic structure of MgO films on Ag(001) have been studied using low energy electron diffraction (LEED), X-ray photoelectron spectroscopy (XPS) and angle-resolved photoemission spectroscopic (ARPES) techniques. The appearance of mosaic structure in the LEED pattern has been observed around 10 ML coverage due to misfit dislocations in the metal-oxide interface. The XPS core level spectra show a substantial amount of binding energy shift relative to their bulk values, indicating the reduction of the on-site Coulomb (U) and change transfer (Δ) energies in oxide layers. This binding energy shift is mainly associated with the image charge screening effect of the highly polarizable metallic substrate. The effect of image charge screening is also reflected in the valence band electronic structure as the bands are shifted to lower binding energies with decreasing film coverage maintaining the bulk MgO band gap till 5 ML. However, for the film coverages below 5 ML, the band gap is reduced substantially in presence of O 2p-Ag 5sp hybridized bands with the finite size effects in proximity to the Ag(001) substrate. Furthermore, our measured valence band electronic structure has been compared with the theoretical calculations and a good agreement has been observed between them for the bulk MgO, however, a more detailed calculation is necessary to explain the monolayer MgO band structure properly.
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[Display omitted] Growth and coverage dependent electronic structure of MgO films on Ag(001) have been studied using low energy electron diffraction (LEED), X-ray photoelectron spectroscopy (XPS) and angle-resolved photoemission spectroscopic (ARPES) techniques. The appearance of mosaic structure in the LEED pattern has been observed around 10 ML coverage due to misfit dislocations in the metal-oxide interface. The XPS core level spectra show a substantial amount of binding energy shift relative to their bulk values, indicating the reduction of the on-site Coulomb (U) and change transfer (Δ) energies in oxide layers. This binding energy shift is mainly associated with the image charge screening effect of the highly polarizable metallic substrate. The effect of image charge screening is also reflected in the valence band electronic structure as the bands are shifted to lower binding energies with decreasing film coverage maintaining the bulk MgO band gap till 5 ML. 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[Display omitted] Growth and coverage dependent electronic structure of MgO films on Ag(001) have been studied using low energy electron diffraction (LEED), X-ray photoelectron spectroscopy (XPS) and angle-resolved photoemission spectroscopic (ARPES) techniques. The appearance of mosaic structure in the LEED pattern has been observed around 10 ML coverage due to misfit dislocations in the metal-oxide interface. The XPS core level spectra show a substantial amount of binding energy shift relative to their bulk values, indicating the reduction of the on-site Coulomb (U) and change transfer (Δ) energies in oxide layers. This binding energy shift is mainly associated with the image charge screening effect of the highly polarizable metallic substrate. The effect of image charge screening is also reflected in the valence band electronic structure as the bands are shifted to lower binding energies with decreasing film coverage maintaining the bulk MgO band gap till 5 ML. 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[Display omitted] Growth and coverage dependent electronic structure of MgO films on Ag(001) have been studied using low energy electron diffraction (LEED), X-ray photoelectron spectroscopy (XPS) and angle-resolved photoemission spectroscopic (ARPES) techniques. The appearance of mosaic structure in the LEED pattern has been observed around 10 ML coverage due to misfit dislocations in the metal-oxide interface. The XPS core level spectra show a substantial amount of binding energy shift relative to their bulk values, indicating the reduction of the on-site Coulomb (U) and change transfer (Δ) energies in oxide layers. This binding energy shift is mainly associated with the image charge screening effect of the highly polarizable metallic substrate. The effect of image charge screening is also reflected in the valence band electronic structure as the bands are shifted to lower binding energies with decreasing film coverage maintaining the bulk MgO band gap till 5 ML. 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source ScienceDirect Journals
subjects Banded structure
Binding energy
Dislocations
Electronic structure
Energy gap
Image charge
LEED
Low energy electron diffraction
Magnesium
Magnesium oxide
Mathematical analysis
Metal oxides
Oxide thin film
Photoelectric emission
Photoelectron spectroscopy
Photoelectrons
Screening
Silver
Size effects
Spectrum analysis
Substrates
Thin films
Valence band
X ray photoelectron spectroscopy
title Growth and coverage dependent electronic structure of MgO on Ag(001)
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