Micromachines (Sep 2023)

Measurement and Simulation of Ultra-Low-Energy Ion–Solid Interaction Dynamics

  • Michael Titze,
  • Jonathan D. Poplawsky,
  • Silvan Kretschmer,
  • Arkady V. Krasheninnikov,
  • Barney L. Doyle,
  • Edward S. Bielejec,
  • Gerhard Hobler,
  • Alex Belianinov

DOI
https://doi.org/10.3390/mi14101884
Journal volume & issue
Vol. 14, no. 10
p. 1884

Abstract

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Ion implantation is a key capability for the semiconductor industry. As devices shrink, novel materials enter the manufacturing line, and quantum technologies transition to being more mainstream. Traditional implantation methods fall short in terms of energy, ion species, and positional precision. Here, we demonstrate 1 keV focused ion beam Au implantation into Si and validate the results via atom probe tomography. We show the Au implant depth at 1 keV is 0.8 nm and that identical results for low-energy ion implants can be achieved by either lowering the column voltage or decelerating ions using bias while maintaining a sub-micron beam focus. We compare our experimental results to static calculations using SRIM and dynamic calculations using binary collision approximation codes TRIDYN and IMSIL. A large discrepancy between the static and dynamic simulation is found, which is due to lattice enrichment with high-stopping-power Au and surface sputtering. Additionally, we demonstrate how model details are particularly important to the simulation of these low-energy heavy-ion implantations. Finally, we discuss how our results pave a way towards much lower implantation energies while maintaining high spatial resolution.

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