English

Towards controllable Si-doping in oxide molecular beam epitaxy using a solid SiO source: Application to $\beta$-Ga2O3

Materials Science 2024-11-25 v1 Applied Physics

Abstract

The oxidation-related issues in controlling Si doping from the Si source material in oxide molecular beam epitaxy (MBE) is addressed by using solid SiO as an alternative source material in a conventional effusion cell. Line-of-sight quadrupole mass spectrometry of the direct SiO-flux (ΦSiO\Phi_{SiO}) from the source at different temperatures (TSiOT_{SiO}) confirmed SiO molecules to sublime with an activation energy of 3.3eV. The TSiOT_{SiO}-dependent ΦSiO\Phi_{SiO} was measured in vacuum before and after subjecting the source material to an O2_{2}-background of 10510^{-5} mbar (typical oxide MBE regime). The absence of a significant ΦSiO\Phi_{SiO} difference indicates negligible source oxidation in molecular O2_{2}. Mounted in an oxygen plasma-assisted MBE, Si-doped β\beta-Ga2O3 layers were grown using this source. The ΦSiO\Phi_{SiO} at the substrate was evaluated [from 2.9x109^{9} cm2^{-2}s1^{-1} (TSiOT_{SiO}=700{\deg}C) to 5.5x1013^{13} cm2^{-2}s1^{-1} (TSiO_{SiO}=1000{\deg}C)] and Si-concentration in the β\beta-Ga2O3 layers measured by secondary ion mass spectrometry highlighting unprecedented control of continuous Si-doping for oxide MBE, i.e., NSiN_{Si} from 4x1017^{17} cm3^{-3} (TSiOT_{SiO}=700{\deg}C) up to 1.7x1020^{20} cm3^{-3} (TSiOT_{SiO}=900{\deg}C). For a homoepitaxial β\beta-Ga2O3 layer an Hall charge carrier concentration of 3x1019^{19} cm3^{-3} in line with the provided ΦSiO\Phi_{SiO} (TSiOT_{SiO}=800{\deg}C) is demonstrated. No SiO-incorporation difference was found between β\beta-Ga2O3(010) layers homoepitaxially grown at 750{\deg}C and β\beta-Ga2O3(-201) layers heteroepitaxially grown at 550{\deg}C. The presence of activated oxygen (plasma) resulted in partial source oxidation and related decrease of doping concentration (particularly at TSiOT_{SiO}<800{\deg}C) which has been tentatively explained with a simple model. Degassing the source at 1100{\deg}C reverted the oxidation.

Keywords

Cite

@article{arxiv.2202.05762,
  title  = {Towards controllable Si-doping in oxide molecular beam epitaxy using a solid SiO source: Application to $\beta$-Ga2O3},
  author = {A. Ardenghi and O. Bierwagen and A. Falkenstein and G. Hoffmann and J. Lähnemann and M. Martin and P. Mazzolini},
  journal= {arXiv preprint arXiv:2202.05762},
  year   = {2024}
}
R2 v1 2026-06-24T09:32:28.500Z