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Autori principali: Gibson, J. M., Elliman, Robe, Susi, T., Mangler, C.
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2506.00176
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author Gibson, J. M.
Elliman, Robe
Susi, T.
Mangler, C.
author_facet Gibson, J. M.
Elliman, Robe
Susi, T.
Mangler, C.
contents Self-ion implantation amorphization is an established approach to study the structure and properties of amorphous silicon (a-Si). Fluctuation Electron Microscopy (FEM) has consistently observed Medium-Range Order (MRO) in this system that is not consistent with the Continuous Random Network (CRN) model. Using this technique we find that the degree of MRO first increases on thermal annealing and then decreases before finally recrystallizing. We discuss this new result in the light of previous experimental studies and recent theoretical observations on the favorability of the paracrystalline (PC) model over the CRN in a-Si. At ion doses far above the minimum required to amorphize, a high defect density is found in the PC phase, which anneals out at 500oC. The PC structure after 500oC annealing is independent of the initial implantation conditions and appears to represent a metastable and highly-ordered structure. Higher-temperature annealing causes a reduction in the degree of MRO and the structure approaches but does not reach a fully continuous random network before eventually crystallizing above 600oC. The effect of high dose implantation is to increase the defect density in the as-implanted state and the annealing of these defects is likely responsible for the large characteristic heat evolution at low temperature.
format Preprint
id arxiv_https___arxiv_org_abs_2506_00176
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Self-ion implantation and structural relaxation in amorphous silicon
Gibson, J. M.
Elliman, Robe
Susi, T.
Mangler, C.
Materials Science
Applied Physics
Self-ion implantation amorphization is an established approach to study the structure and properties of amorphous silicon (a-Si). Fluctuation Electron Microscopy (FEM) has consistently observed Medium-Range Order (MRO) in this system that is not consistent with the Continuous Random Network (CRN) model. Using this technique we find that the degree of MRO first increases on thermal annealing and then decreases before finally recrystallizing. We discuss this new result in the light of previous experimental studies and recent theoretical observations on the favorability of the paracrystalline (PC) model over the CRN in a-Si. At ion doses far above the minimum required to amorphize, a high defect density is found in the PC phase, which anneals out at 500oC. The PC structure after 500oC annealing is independent of the initial implantation conditions and appears to represent a metastable and highly-ordered structure. Higher-temperature annealing causes a reduction in the degree of MRO and the structure approaches but does not reach a fully continuous random network before eventually crystallizing above 600oC. The effect of high dose implantation is to increase the defect density in the as-implanted state and the annealing of these defects is likely responsible for the large characteristic heat evolution at low temperature.
title Self-ion implantation and structural relaxation in amorphous silicon
topic Materials Science
Applied Physics
url https://arxiv.org/abs/2506.00176