High energy ion beam irradiation on titanium substrate in a pulsed plasma device operating with methane
We report the investigation of high energy ion beam irradiation on titanium (Ti) substrates at room temperature using a low energy plasma focus (PF) device operating in methane gas. The surface modifications induced by the ion beam using two different anode materials, graphite and copper, are charac...
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todo:paper_00223727_v42_n20_p_Bhuyan2023-10-03T14:32:24Z High energy ion beam irradiation on titanium substrate in a pulsed plasma device operating with methane Bhuyan, H. Favre, M. Valderrama, E. Henriquez, A. Vogel, G. Chuaqui, H. Wyndham, E. Cabrera, A. Ramos-Moore, E. Ñez, P.A. Kelly, H. Grondona, D. Goyanes, S. Anode material Carbon Nanostructures Carbon structures Characteristic energy Diagnostic tools Gradient layers Graphite anode High energy Ion beam irradiation Irradiated surface Low-energy plasma Methane gas Operational conditions Pulsed plasma Room temperature Surface modification Surface science Titanium substrates Anodes Beam plasma interactions Chemical modification Graphite Ion beams Ion bombardment Ions Methane Plasma devices Raman spectroscopy Scanning electron microscopy Substrates Surface treatment Titanium Titanium carbide X ray diffraction analysis Auger electron spectroscopy We report the investigation of high energy ion beam irradiation on titanium (Ti) substrates at room temperature using a low energy plasma focus (PF) device operating in methane gas. The surface modifications induced by the ion beam using two different anode materials, graphite and copper, are characterized using standard surface science diagnostic tools, such as x-ray diffraction, scanning electron microscopy, energy-dispersive x-ray analysis, Raman spectroscopy and Auger electron spectroscopy. It has been found that the interaction of the pulsed PF ion beams, with characteristic energy in the 15-300 keV range, with the Ti surface, results in the formation of nanocomposite carbon structures. It is observed that the resulting ion irradiated surface morphologies are different, depending on the different anode materials, under otherwise identical operational conditions. In the case of the graphite anode the interaction of PF ion beams followed by the anode vapour with the Ti surface results in the formation of gradient layers of TiC with embedded carbon nanostructures. © 2009 IOP Publishing Ltd. Fil:Kelly, H. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. Fil:Grondona, D. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. Fil:Goyanes, S. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. JOUR info:eu-repo/semantics/openAccess http://creativecommons.org/licenses/by/2.5/ar http://hdl.handle.net/20.500.12110/paper_00223727_v42_n20_p_Bhuyan |
institution |
Universidad de Buenos Aires |
institution_str |
I-28 |
repository_str |
R-134 |
collection |
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) |
topic |
Anode material Carbon Nanostructures Carbon structures Characteristic energy Diagnostic tools Gradient layers Graphite anode High energy Ion beam irradiation Irradiated surface Low-energy plasma Methane gas Operational conditions Pulsed plasma Room temperature Surface modification Surface science Titanium substrates Anodes Beam plasma interactions Chemical modification Graphite Ion beams Ion bombardment Ions Methane Plasma devices Raman spectroscopy Scanning electron microscopy Substrates Surface treatment Titanium Titanium carbide X ray diffraction analysis Auger electron spectroscopy |
spellingShingle |
Anode material Carbon Nanostructures Carbon structures Characteristic energy Diagnostic tools Gradient layers Graphite anode High energy Ion beam irradiation Irradiated surface Low-energy plasma Methane gas Operational conditions Pulsed plasma Room temperature Surface modification Surface science Titanium substrates Anodes Beam plasma interactions Chemical modification Graphite Ion beams Ion bombardment Ions Methane Plasma devices Raman spectroscopy Scanning electron microscopy Substrates Surface treatment Titanium Titanium carbide X ray diffraction analysis Auger electron spectroscopy Bhuyan, H. Favre, M. Valderrama, E. Henriquez, A. Vogel, G. Chuaqui, H. Wyndham, E. Cabrera, A. Ramos-Moore, E. Ñez, P.A. Kelly, H. Grondona, D. Goyanes, S. High energy ion beam irradiation on titanium substrate in a pulsed plasma device operating with methane |
topic_facet |
Anode material Carbon Nanostructures Carbon structures Characteristic energy Diagnostic tools Gradient layers Graphite anode High energy Ion beam irradiation Irradiated surface Low-energy plasma Methane gas Operational conditions Pulsed plasma Room temperature Surface modification Surface science Titanium substrates Anodes Beam plasma interactions Chemical modification Graphite Ion beams Ion bombardment Ions Methane Plasma devices Raman spectroscopy Scanning electron microscopy Substrates Surface treatment Titanium Titanium carbide X ray diffraction analysis Auger electron spectroscopy |
description |
We report the investigation of high energy ion beam irradiation on titanium (Ti) substrates at room temperature using a low energy plasma focus (PF) device operating in methane gas. The surface modifications induced by the ion beam using two different anode materials, graphite and copper, are characterized using standard surface science diagnostic tools, such as x-ray diffraction, scanning electron microscopy, energy-dispersive x-ray analysis, Raman spectroscopy and Auger electron spectroscopy. It has been found that the interaction of the pulsed PF ion beams, with characteristic energy in the 15-300 keV range, with the Ti surface, results in the formation of nanocomposite carbon structures. It is observed that the resulting ion irradiated surface morphologies are different, depending on the different anode materials, under otherwise identical operational conditions. In the case of the graphite anode the interaction of PF ion beams followed by the anode vapour with the Ti surface results in the formation of gradient layers of TiC with embedded carbon nanostructures. © 2009 IOP Publishing Ltd. |
format |
JOUR |
author |
Bhuyan, H. Favre, M. Valderrama, E. Henriquez, A. Vogel, G. Chuaqui, H. Wyndham, E. Cabrera, A. Ramos-Moore, E. Ñez, P.A. Kelly, H. Grondona, D. Goyanes, S. |
author_facet |
Bhuyan, H. Favre, M. Valderrama, E. Henriquez, A. Vogel, G. Chuaqui, H. Wyndham, E. Cabrera, A. Ramos-Moore, E. Ñez, P.A. Kelly, H. Grondona, D. Goyanes, S. |
author_sort |
Bhuyan, H. |
title |
High energy ion beam irradiation on titanium substrate in a pulsed plasma device operating with methane |
title_short |
High energy ion beam irradiation on titanium substrate in a pulsed plasma device operating with methane |
title_full |
High energy ion beam irradiation on titanium substrate in a pulsed plasma device operating with methane |
title_fullStr |
High energy ion beam irradiation on titanium substrate in a pulsed plasma device operating with methane |
title_full_unstemmed |
High energy ion beam irradiation on titanium substrate in a pulsed plasma device operating with methane |
title_sort |
high energy ion beam irradiation on titanium substrate in a pulsed plasma device operating with methane |
url |
http://hdl.handle.net/20.500.12110/paper_00223727_v42_n20_p_Bhuyan |
work_keys_str_mv |
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