Advanced Electronic Materials (Apr 2022)

Toward Functionalized Ultrathin Oxide Films: The Impact of Surface Apical Oxygen

  • Judith Gabel,
  • Matthias Pickem,
  • Philipp Scheiderer,
  • Lenart Dudy,
  • Berengar Leikert,
  • Marius Fuchs,
  • Martin Stübinger,
  • Matthias Schmitt,
  • Julia Küspert,
  • Giorgio Sangiovanni,
  • Jan M. Tomczak,
  • Karsten Held,
  • Tien‐Lin Lee,
  • Ralph Claessen,
  • Michael Sing

DOI
https://doi.org/10.1002/aelm.202101006
Journal volume & issue
Vol. 8, no. 4
pp. n/a – n/a

Abstract

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Abstract Thin films of transition metal oxides open up a gateway to nanoscale electronic devices beyond silicon characterized by novel electronic functionalities. While such films are commonly prepared in an oxygen atmosphere, they are typically considered to be ideally terminated with the stoichiometric composition. Using the prototypical correlated metal SrVO3 as an example, it is demonstrated that this idealized description overlooks an essential ingredient: oxygen adsorbing at the surface apical sites. The oxygen adatoms, which are present even if the films are kept in an ultrahigh vacuum environment and not explicitly exposed to air, are shown to severely affect the intrinsic electronic structure of a transition metal oxide film. Their presence leads to the formation of an electronically dead surface layer but also alters the band filling and the electron correlations in the thin films. These findings highlight that it is important to take into account surface apical oxygen or—mutatis mutandis—the specific oxygen configuration imposed by a capping layer to predict the behavior of ultrathin films of transition metal oxides near the single unit‐cell limit.

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