AIP Advances (Jun 2024)

Experimental and theoretical studies on self-diffusion in amorphous germanium

  • Tim Böckendorf,
  • Jan Kirschbaum,
  • Felix Kipke,
  • Dominique Bougeard,
  • John Lundsgaard Hansen,
  • Arne Nylandsted Larsen,
  • Matthias Posselt,
  • Hartmut Bracht

DOI
https://doi.org/10.1063/5.0183578
Journal volume & issue
Vol. 14, no. 6
pp. 065129 – 065129-8

Abstract

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Self-diffusion in amorphous germanium is studied at temperatures between 325 and 370 °C utilizing amorphous isotopically controlled germanium multilayer structures. The isotope multilayer is epitaxially grown on a single crystalline germanium-on-insulator structure by means of molecular beam epitaxy and subsequently amorphized by self-ion implantation. After heat treatment, the diffusional broadening of the isotope structure is measured with time-of-flight secondary ion mass spectrometry. The temperature dependence of self-diffusion is accurately described by the Arrhenius equation with the activation enthalpy Q = (2.21 ± 0.12) eV and pre-exponential factor D0=(2.32−2.10+20.79) cm2 s−1. The activation enthalpy equals the activation enthalpy of solid phase epitaxial recrystallization (SPER). This agreement suggests that self-diffusion in amorphous germanium is similar to SPER, also mainly mediated by local bond rearrangements. Classical molecular dynamics simulations with a modified Stillinger–Weber-type interatomic potential yield results that are consistent with the experimental data and support the proposed atomic mechanism.