Quantifying the impact of an electronic drag force on defect production from high-energy displacement cascades in alpha-zirconium
JF March-Rico and CM McSwain and BD Wirth, JOURNAL OF NUCLEAR MATERIALS, 542, 152539 (2020).
DOI: 10.1016/j.jnucmat.2020.152539
Molecular dynamics displacement cascade simulations with PKA energies up to 40 keV at 600 K have been performed to investigate the impact of electronic energy losses in a-zirconium. The following data sets are compared: 1) displacement cascades performed with nuclear stopping only and 2) displacement cascades with simultaneous nuclear and electronic stopping. Electronic energy losses are modeled by a drag force with strength proportional to the energy-dependent electronic stopping power using the intrinsic "fix electron/stopping" command in LAMMPS. Consistent with typical characteristics of cascade defect generation, the production efficiency of Frenkel pairs falls below 20% of the NRT- predicted value for high PKA energies, defect clustering increases with PKA energy, and two distinct power-law regimes of the form N-F = A(E-p)(m) correlate the surviving number of Frenkel pairs; the separate power-law fits describe defect production prior to and following sub- cascade formation. When implemented, electronic energy losses account for a 10-20% reduction in surviving Frenkel pairs for high-energy PKAs. The energy loss method implemented in LAMMPS results in nuclear damage energies comparable with the values predicted by SRIM using the full- cascade option, and represents a user-friendly method to incorporate ionization losses in molecular dynamics simulations. (C) 2020 Elsevier B.V. All rights reserved.
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