Stabilization of polar Mn3O4(001) film on Ag(001): Interplay between kinetic and structural stability

•Growth of well-ordered Mn3O4(001) film on Ag(001).•Polar Mn3O4(001) surface is stabilized through surface reconstructions.•Evidence of interplay between kinetic and structural stability of Mn3O4(001) film.•Probe the surface structural phase-space of Mn3O4(001) film by LEED and XPS. [Display omitted...

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Veröffentlicht in:Surface science 2017-10, Vol.664, p.207-215
Hauptverfasser: Kundu, Asish K., Barman, Sukanta, Menon, Krishnakumar S. R.
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Sprache:eng
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Zusammenfassung:•Growth of well-ordered Mn3O4(001) film on Ag(001).•Polar Mn3O4(001) surface is stabilized through surface reconstructions.•Evidence of interplay between kinetic and structural stability of Mn3O4(001) film.•Probe the surface structural phase-space of Mn3O4(001) film by LEED and XPS. [Display omitted] Stabilization processes of polar surfaces are often very complex and interesting. Understanding of these processes is crucial as it ultimately determines the properties of the film. Here, by the combined study of Low Energy Electron Diffraction (LEED), X-ray Photoelectron Spectroscopy (XPS) and Ultraviolet Photoemission Spectroscopy (UPS) techniques we show that, although there can be many processes involved in the stabilization of the polar surfaces, in case of Mn3O4(001)/Ag(001), it goes through different reconstructions of the Mn2O4 terminated surface which is in good agreements with the theoretical predictions. The complex surface phase diagram has been probed by LEED as a function of film thickness, oxygen partial pressure and substrate temperature during growth, while their chemical compositions have been probed by XPS. Below a critical film thickness of ∼ 1 unit cell height (8 sublayers or 3 ML) of Mn3O4 and oxygen partial pressure range of 2  ×   10−8 mbar < P(O2) ≤ 5  ×   10−7 mbar, different surface structures are detected and beyond this thickness a constant evolution of apparent p(2 × 2) structure have been observed due to the coexistence of p(2 × 1) and c(2 × 2) structures. Similar apparent p(2 × 2) structure has also observed by the oxidation of Ag(001)-supported MnO(001) surface. Our study also shows that the substrate temperature during growth plays a crucial role in determining the final structure of the polar Mn3O4 film and as a consequence of that a strong interplay between structural and kinetic stability in the Mn3O4 film has been observed. Further, stripe-like LEED pattern has been observed from the Mn3O4(001) surface, for the film grown at higher oxygen partial pressure (> 5  ×   10−7 mbar) and higher temperature UHV annealing. The origin of these stripes has been explained with the help of UPS results.
ISSN:0039-6028
1879-2758
DOI:10.1016/j.susc.2017.06.017