APL Materials (Apr 2023)

Silicon-doped β-Ga2O3 films grown at 1 µm/h by suboxide molecular-beam epitaxy

  • Kathy Azizie,
  • Felix V. E. Hensling,
  • Cameron A. Gorsak,
  • Yunjo Kim,
  • Naomi A. Pieczulewski,
  • Daniel M. Dryden,
  • M. K. Indika Senevirathna,
  • Selena Coye,
  • Shun-Li Shang,
  • Jacob Steele,
  • Patrick Vogt,
  • Nicholas A. Parker,
  • Yorick A. Birkhölzer,
  • Jonathan P. McCandless,
  • Debdeep Jena,
  • Huili G. Xing,
  • Zi-Kui Liu,
  • Michael D. Williams,
  • Andrew J. Green,
  • Kelson Chabak,
  • David A. Muller,
  • Adam T. Neal,
  • Shin Mou,
  • Michael O. Thompson,
  • Hari P. Nair,
  • Darrell G. Schlom

DOI
https://doi.org/10.1063/5.0139622
Journal volume & issue
Vol. 11, no. 4
pp. 041102 – 041102-12

Abstract

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We report the use of suboxide molecular-beam epitaxy (S-MBE) to grow β-Ga2O3 at a growth rate of ∼1 µm/h with control of the silicon doping concentration from 5 × 1016 to 1019 cm−3. In S-MBE, pre-oxidized gallium in the form of a molecular beam that is 99.98% Ga2O, i.e., gallium suboxide, is supplied. Directly supplying Ga2O to the growth surface bypasses the rate-limiting first step of the two-step reaction mechanism involved in the growth of β-Ga2O3 by conventional MBE. As a result, a growth rate of ∼1 µm/h is readily achieved at a relatively low growth temperature (Tsub ≈ 525 °C), resulting in films with high structural perfection and smooth surfaces (rms roughness of <2 nm on ∼1 µm thick films). Silicon-containing oxide sources (SiO and SiO2) producing an SiO suboxide molecular beam are used to dope the β-Ga2O3 layers. Temperature-dependent Hall effect measurements on a 1 µm thick film with a mobile carrier concentration of 2.7 × 1017 cm−3 reveal a room-temperature mobility of 124 cm2 V−1 s−1 that increases to 627 cm2 V−1 s−1 at 76 K; the silicon dopants are found to exhibit an activation energy of 27 meV. We also demonstrate working metal–semiconductor field-effect transistors made from these silicon-doped β-Ga2O3 films grown by S-MBE at growth rates of ∼1 µm/h.