Post-Irradiation Annealing of Bi Ion Tracks in Si3N4: In-Situ and Ex- Situ Transmission Electron Microscopy Study

A Ibrayeva and J O'Connell and R Rymzhanov and AJ van Vuuren and V Skuratov, CRYSTALS, 15, 852 (2025).

DOI: 10.3390/cryst15100852

High-energy (710 MeV) Bi ion track morphology in polycrystalline silicon nitride was investigated during post-irradiation annealing. Using both in-situ and ex-situ transmission electron microscopy, we monitored the recovery of crystallinity within initially amorphous ion track regions. In-situ annealing involved heating samples from room temperature to 1000 degrees C in 50 degrees C increments, each held for 10 s. We observed a steady decrease in both the size and number of tracks, with only a small number of residual crystalline defects remaining at 1000 degrees C. Ex- situ annealing experiments were conducted at 400 degrees C, 700 degrees C, and 1000 degrees C for durations of 10, 20, and 30 min. Complete restoration of the crystalline lattice occurred after 30 min at 700 degrees C and 20 min at 1000 degrees C. Due to inherent differences in geometry, heat flow, and stress conditions between thin lamella and bulk specimens, in-situ and ex-situ results cannot be compared. Molecular dynamics simulations further revealed that track shrinkage begins in cells within picoseconds, supporting the notion that recrystallization can start on very short timescales. Overall, these findings demonstrate that thermal recrystallization of damage induced by swift heavy ion irradiation in polycrystalline Si3N4 is possible. This study provides a foundation for future research aimed at better understanding radiation damage recovery in this material.

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