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Superior electrochemical performance of CNx nanotubes using TiSi2 buffer layer on Si substrates

Biomedical Sciences Research Institute Computer Science Research Institute Environmental Sciences Research Institute Nanotechnology & Advanced Materials Research Institute

Fang, WC, Huang, JH, Sun, CL, Chen, LC, Papakonstantinou, P and Chen, KH (2006) Superior electrochemical performance of CNx nanotubes using TiSi2 buffer layer on Si substrates. JOURNAL OF VACUUM SCIENCE & TECHNOLOGY B, 24 (1). pp. 87-90. [Journal article]

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DOI: 10.1116/1.2141627

Abstract

On-chip growth of vertically aligned nitrogen-containing carbon nanotube (CNx NT) arrays was demonstrated. The nanotubes were grown by microwave plasma-enhanced chemical-vapor deposition on different types of silicon substrates (n, p, n(+),p(+)) using a few nanometer thick Fe layer as a catalyst and a Ti buffer layer. The effects of the Ti thickness on the electrochemical (EC) characteristics of the CN, NT arrays were studied. It was found that for a Ti thickness of 20 rim, while vertically aligned CNx NTs were produced on all Si substrates, an almost ideal Nerstian behavior was observed only on highly conductive n(+) and p(+) substrates. As the Ti buffer thickness increased to 200 nm, good electrical contacts were established at the bottom end of the CNx NTs and fast electron kinetics were then attainable on all kinds of Si substrates. Nevertheless, the use of thick buffer layers inhibited directional growth. Oxidation treatment of the catalyst Fe layer prior to nanotube growth proved efficient for achieving directional CNx NT formation. Pretreatment of the Ti buffer layer at a temperature of 800 degrees C, leading to the formation of TiSi2, was appropriate for achieving simultaneously enhanced current density and fast electron kinetics comparable to those of CNx NTs on bulk Ti electrodes. The Si-based micro-EC platform established in this work has superior current collection efficiency and is amenable for fundamental EC studies and energy applications. (c) 2006 American Vacuum Society.

Item Type:Journal article
Faculties and Schools:Faculty of Computing & Engineering
Faculty of Computing & Engineering > School of Engineering
Research Institutes and Groups:Engineering Research Institute
Engineering Research Institute > Nanotechnology & Integrated BioEngineering Centre (NIBEC)
ID Code:6404
Deposited By:Professor Pagona Papakonstantinou
Deposited On:13 Jan 2010 09:43
Last Modified:18 Aug 2011 11:56

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