Unravelling the secrets of the resistance of GaN to strongly ionising radiation

Miguel C. Sequeira; Jean Gabriel Mattei; Henrique Vazquez; Flyura Djurabekova; Kai Nordlund; Isabelle Monnet; Pablo Mota-Santiago; Patrick Kluth; Clara Grygiel; Shuo Zhang; Eduardo Alves; Katharina Lorenz

doi:10.1038/s42005-021-00550-2

Unravelling the secrets of the resistance of GaN to strongly ionising radiation

Miguel C. Sequeira^*, Jean Gabriel Mattei, Henrique Vazquez, Flyura Djurabekova, Kai Nordlund, Isabelle Monnet, Pablo Mota-Santiago, Patrick Kluth, Clara Grygiel, Shuo Zhang, Eduardo Alves, Katharina Lorenz

^*Corresponding author for this work

Research output: Contribution to journal › Article › peer-review

44 Citations (Scopus)

Abstract

GaN is the most promising upgrade to the traditional Si-based radiation-hard technologies. However, the underlying mechanisms driving its resistance are unclear, especially for strongly ionising radiation. Here, we use swift heavy ions to show that a strong recrystallisation effect induced by the ions is the key mechanism behind the observed resistance. We use atomistic simulations to examine and predict the damage evolution. These show that the recrystallisation lowers the expected damage levels significantly and has strong implications when studying high fluences for which numerous overlaps occur. Moreover, the simulations reveal structures such as point and extended defects, density gradients and voids with excellent agreement between simulation and experiment. We expect that the developed modelling scheme will contribute to improving the design and test of future radiation-resistant GaN-based devices.

Original language	English
Article number	51
Journal	Communications Physics
Volume	4
Issue number	1
DOIs	https://doi.org/10.1038/s42005-021-00550-2
Publication status	Published - Dec 2021

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abstract = "GaN is the most promising upgrade to the traditional Si-based radiation-hard technologies. However, the underlying mechanisms driving its resistance are unclear, especially for strongly ionising radiation. Here, we use swift heavy ions to show that a strong recrystallisation effect induced by the ions is the key mechanism behind the observed resistance. We use atomistic simulations to examine and predict the damage evolution. These show that the recrystallisation lowers the expected damage levels significantly and has strong implications when studying high fluences for which numerous overlaps occur. Moreover, the simulations reveal structures such as point and extended defects, density gradients and voids with excellent agreement between simulation and experiment. We expect that the developed modelling scheme will contribute to improving the design and test of future radiation-resistant GaN-based devices.",

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AU - Sequeira, Miguel C.

AU - Mattei, Jean Gabriel

AU - Vazquez, Henrique

AU - Djurabekova, Flyura

AU - Nordlund, Kai

AU - Monnet, Isabelle

AU - Mota-Santiago, Pablo

AU - Kluth, Patrick

AU - Grygiel, Clara

AU - Zhang, Shuo

AU - Alves, Eduardo

AU - Lorenz, Katharina

PY - 2021/12

Y1 - 2021/12

N2 - GaN is the most promising upgrade to the traditional Si-based radiation-hard technologies. However, the underlying mechanisms driving its resistance are unclear, especially for strongly ionising radiation. Here, we use swift heavy ions to show that a strong recrystallisation effect induced by the ions is the key mechanism behind the observed resistance. We use atomistic simulations to examine and predict the damage evolution. These show that the recrystallisation lowers the expected damage levels significantly and has strong implications when studying high fluences for which numerous overlaps occur. Moreover, the simulations reveal structures such as point and extended defects, density gradients and voids with excellent agreement between simulation and experiment. We expect that the developed modelling scheme will contribute to improving the design and test of future radiation-resistant GaN-based devices.

AB - GaN is the most promising upgrade to the traditional Si-based radiation-hard technologies. However, the underlying mechanisms driving its resistance are unclear, especially for strongly ionising radiation. Here, we use swift heavy ions to show that a strong recrystallisation effect induced by the ions is the key mechanism behind the observed resistance. We use atomistic simulations to examine and predict the damage evolution. These show that the recrystallisation lowers the expected damage levels significantly and has strong implications when studying high fluences for which numerous overlaps occur. Moreover, the simulations reveal structures such as point and extended defects, density gradients and voids with excellent agreement between simulation and experiment. We expect that the developed modelling scheme will contribute to improving the design and test of future radiation-resistant GaN-based devices.

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Unravelling the secrets of the resistance of GaN to strongly ionising radiation

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