Organization of nanostructures on the surface of Fe/Si

Organization of nanostructures on the surface of Fe/Si

The use of Focused Ion Beam (FIB) in micromanufacturing has been prevalent since its invention in the 1970s. Nanoneedle structures were observed after ion sputtering using the FIB system on Fe deposited thin films. The surface modification of Fe deposited silicon resulted in a recent discovery of na...

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Main Author: Jiang, Zongye
Other Authors: School of Materials Science and Engineering
Format: Final Year Project
Language:English
Published: 2013
Subjects:
DRNTU::Engineering
Online Access:http://hdl.handle.net/10356/52112
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Institution: Nanyang Technological University
Language: English
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spelling sg-ntu-dr.10356-521122023-03-04T15:36:22Z Organization of nanostructures on the surface of Fe/Si Jiang, Zongye School of Materials Science and Engineering Huang Yizhong DRNTU::Engineering The use of Focused Ion Beam (FIB) in micromanufacturing has been prevalent since its invention in the 1970s. Nanoneedle structures were observed after ion sputtering using the FIB system on Fe deposited thin films. The surface modification of Fe deposited silicon resulted in a recent discovery of nanonipple structures by the bombardment of Ga+ ions. This fabrication process involved the FIB ion irradiation of Ga+ ions directed perpendicular to the substrate surface at implant energy of 30KeV. The resultant nanonipple structure consists of a crystalline silicon stub encapsulated beneath an amorphous outer layer and a nipple tip. This amorphous phase was discovered to contain a high wt% of Fe and Ga elements. Recrystallization of this amorphous layer while maintaining the geometry integrity exudes the possibility of improved magnetoelectronic properties for future applications. Recrystallization of this nanonipple structure was carried out via tube furnace annealing treatment under argon gas environment to prevent sublimation of substrate at high temperatures. Maximum annealing temperatures and dwell times were experimented to achieve suitable recrystallization parameters. Maximum annealing temperatures were narrowed down to 250°C, with the nanonipple tip kept visible under SEM observations. Electron diffraction pattern analysis using TEM ascertains the success of recrystallization in the nanonipple sidewall and recrystallization of Ga component that is attached to the nanonipple tip. Under Fast Fourier Transformation (FFT), reciprocal lattice patterns in the silicon sidewall and nanonipple tip were analysed. It was found that silicon sidewall recrystallization displayed crystalline silicon in the direction [111] while the nanonipple tip achieved a partial recrystallization. Overall, recrystallization was successfully achieved in this study at temperatures within the range 200°C - 250°C. In conclusion, nanonipple structures can be replicated under ion irradiation of Ga+ and recrystallization of these structures can provide an opportunity to improve its properties to be used in future applications. Bachelor of Engineering (Materials Engineering) 2013-04-22T08:42:44Z 2013-04-22T08:42:44Z 2013 2013 Final Year Project (FYP) http://hdl.handle.net/10356/52112 en Nanyang Technological University 49 p. application/pdf
institution Nanyang Technological University
building NTU Library
continent Asia
country Singapore
Singapore
content_provider NTU Library
collection DR-NTU
language English
topic DRNTU::Engineering
spellingShingle DRNTU::Engineering
Jiang, Zongye
Organization of nanostructures on the surface of Fe/Si
description The use of Focused Ion Beam (FIB) in micromanufacturing has been prevalent since its invention in the 1970s. Nanoneedle structures were observed after ion sputtering using the FIB system on Fe deposited thin films. The surface modification of Fe deposited silicon resulted in a recent discovery of nanonipple structures by the bombardment of Ga+ ions. This fabrication process involved the FIB ion irradiation of Ga+ ions directed perpendicular to the substrate surface at implant energy of 30KeV. The resultant nanonipple structure consists of a crystalline silicon stub encapsulated beneath an amorphous outer layer and a nipple tip. This amorphous phase was discovered to contain a high wt% of Fe and Ga elements. Recrystallization of this amorphous layer while maintaining the geometry integrity exudes the possibility of improved magnetoelectronic properties for future applications. Recrystallization of this nanonipple structure was carried out via tube furnace annealing treatment under argon gas environment to prevent sublimation of substrate at high temperatures. Maximum annealing temperatures and dwell times were experimented to achieve suitable recrystallization parameters. Maximum annealing temperatures were narrowed down to 250°C, with the nanonipple tip kept visible under SEM observations. Electron diffraction pattern analysis using TEM ascertains the success of recrystallization in the nanonipple sidewall and recrystallization of Ga component that is attached to the nanonipple tip. Under Fast Fourier Transformation (FFT), reciprocal lattice patterns in the silicon sidewall and nanonipple tip were analysed. It was found that silicon sidewall recrystallization displayed crystalline silicon in the direction [111] while the nanonipple tip achieved a partial recrystallization. Overall, recrystallization was successfully achieved in this study at temperatures within the range 200°C - 250°C. In conclusion, nanonipple structures can be replicated under ion irradiation of Ga+ and recrystallization of these structures can provide an opportunity to improve its properties to be used in future applications.
author2 School of Materials Science and Engineering
author_facet School of Materials Science and Engineering
Jiang, Zongye
format Final Year Project
author Jiang, Zongye
author_sort Jiang, Zongye
title Organization of nanostructures on the surface of Fe/Si
title_short Organization of nanostructures on the surface of Fe/Si
title_full Organization of nanostructures on the surface of Fe/Si
title_fullStr Organization of nanostructures on the surface of Fe/Si
title_full_unstemmed Organization of nanostructures on the surface of Fe/Si
title_sort organization of nanostructures on the surface of fe/si
publishDate 2013
url http://hdl.handle.net/10356/52112
_version_ 1759856460999688192

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