APL Materials (Aug 2024)

Surface reconstructions and electronic structure of metallic delafossite thin films

  • Qi Song,
  • Zhiren He,
  • Brendan D. Faeth,
  • Christopher T. Parzyck,
  • Anna Scheid,
  • Chad J. Mowers,
  • Yufan Feng,
  • Qing Xu,
  • Sonia Hasko,
  • Jisung Park,
  • Matthew R. Barone,
  • Y. Eren Suyolcu,
  • Peter A. van Aken,
  • Betül Pamuk,
  • Craig J. Fennie,
  • Phil D. C. King,
  • Kyle M. Shen,
  • Darrell G. Schlom

DOI
https://doi.org/10.1063/5.0217540
Journal volume & issue
Vol. 12, no. 8
pp. 081117 – 081117-9

Abstract

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The growing interest in the growth and study of thin films of low-dimensional metallic delafossites, with the general formula ABO2, is driven by their potential to exhibit electronic and magnetic characteristics that are not accessible in bulk systems. The layered structure of these compounds introduces unique surface states as well as electronic and structural reconstructions, making the investigation of their surface behavior pivotal to understanding their intrinsic electronic structure. In this work, we study the surface phenomena of epitaxially grown PtCoO2, PdCoO2, and PdCrO2 films, utilizing a combination of molecular-beam epitaxy and angle-resolved photoemission spectroscopy. Through precise control of surface termination and treatment, we discover a pronounced 3×3 surface reconstruction in PtCoO2 films and PdCoO2 films, alongside a 2 × 2 surface reconstruction observed in PdCrO2 films. These reconstructions have not been reported in prior studies of delafossites. Furthermore, our computational investigations demonstrate the BO2 surface’s relative stability compared to the A-terminated surface and the significant reduction in surface energy facilitated by the reconstruction of the A-terminated surface. These experimental and theoretical insights illuminate the complex surface dynamics in metallic delafossites, paving the way for future explorations of their distinctive properties in low-dimensional studies.