Obtaining simultaneously high crystallinity and sub-bandgap absorption in femtosecond laser hyperdoped black silicon using ion beam etching
Aufsatz
Zusammenfassung
Femtosecond laser sulfur hyperdoped silicon (fs-hSi) is capable of absorbing photons in the infrared spectral range while simultaneously exhibiting negligible reflection. However, laser processing creates detrimental amorphous and polycrystalline silicon surface layers impairing electronic properties, especially reducing minority charge carrier lifetimes. This paper demonstrates how to selectively remove these disadvantageous layers by ion beam etching, while crystalline IR-absorbing silicon underneath is left. The increase in silicon crystallinity is quantified by laterally probing the fs-hSi samples with Raman spectroscopy.
Schlagworte
Annealing
Scanning electron microscopy
Raman spectroscopy
Semiconductors
Ion beam etching
Femtosecond-laser
Laser materials processing
Polycrystalline material
Hyperdoping
Scanning electron microscopy
Raman spectroscopy
Semiconductors
Ion beam etching
Femtosecond-laser
Laser materials processing
Polycrystalline material
Hyperdoping
DDC-Klassifikation
621 Angewandte Physik
Erschienen in
AIP Advances. American Institute of Physics (2021). 11, 075014, 8 S.. DOI: 10.1063/5.0044678
Projektförderung
Advanced defect engineering and surface passivation for improving the carrier lifetime in femtosecond laser sulfur hyperdoped silicon / DFG / 429413061
Femtosecond laser sulfur hyperdoped black silicon for infrared photonic applications (FemtoBlack) / BMBF / 03INT701AA
Femtosecond laser sulfur hyperdoped black silicon for infrared photonic applications (FemtoBlack) / BMBF / 03INT701AA
Einrichtung
Fachbereich Ingenieurwesen
Institut für Mikrosystemtechnik (IMtech)
Institut für Mikrosystemtechnik (IMtech)
Link zur Veröffentlichung
Sammlungen
- Publikationen [130]
BibTeX
@article{Paulus2021,
author={Paulus, Simon and Mc Kearney, Patrick and Völklein, Friedemann and Kontermann, Stefan},
title={Obtaining simultaneously high crystallinity and sub-bandgap absorption in femtosecond laser hyperdoped black silicon using ion beam etching},
journal={AIP Advances},
volume={11},
pages={8 S.},
month={06},
year={2021},
publisher={American Institute of Physics},
school={Hochschule RheinMain, Wiesbaden},
url={https://hlbrm.pur.hebis.de/xmlui/handle/123456789/71},
doi={10.25716/pur-50}
}
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Namensnennung 4.0 International
Namensnennung 4.0 International