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oai:uvadoc.uva.es:10324/337292025-03-26T19:10:03Zcom_10324_1148com_10324_931com_10324_894com_10324_28025com_10324_954col_10324_1270col_10324_28026

Marqués Cuesta, Luis Alberto Aboy Cebrián, María Ruiz Prieto, Manuel Santos Tejido, Iván López Martín, Pedro Pelaz Montes, María Lourdes 2019 Producción Científica By using classical molecular dynamics simulations and a novel technique to identify defects based on the calculation of atomic strain, we have elucidated the detailed mechanisms leading to the anomalous generation and growth of {001} loops found after ultra-fast laser annealing of ion-implanted Si. We show that the building block of the {001} loops is the very stable Arai tetra-interstitial [N. Arai, S. Takeda, M. Kohyama, Phys. Rev. Lett. 78, 4265 (1997)], but their growth is kinetically prevented within conventional Ostwald ripening mechanisms under standard processing conditions. However, our simulations predict that at temperatures close to the Si melting point, Arai tetra-interstitials directly nucleate at the boundaries of fast diffusing self-interstitial agglomerates, which merge by a coalescence mechanism reaching large sizes in the nanosecond timescale. We demonstrate that the crystallization of such agglomerates into {001} loops and their subsequent growth is mediated by the tensile and compressive strain fields that develop concurrently around the loops. We also show that further annealing produces the unfaulting of {001} loops into perfect dislocations. Besides, from the simulations we have fully characterized the {001} loops, determining their atomic structure, interstitial density and formation energy. application/pdf http://uvadoc.uva.es/handle/10324/33729 eng Elsevier {001} loops in silicon unraveled info:eu-repo/semantics/article TEXT UVaDOC. Repositorio Documental de la Universidad de Valladolid Hispana