Abstract
Nanostructured electrodes and their flexible integrated systems have great potential for many applications, including electrochemical energy storage, electrocatalysis and solid-state memory devices, given their ability to improve faradaic reaction sites by large surface area. Although many processing techniques have been employed to fabricate nanostructured electrodes onto flexible substrates, these present limitations in terms of achieving flexible electrodes with high mechanical stability. In this study, the adhesion, mechanical properties and flexibility of TiN nanotube arrays on a Pt substrate were improved using a Ti interlayer. Highly ordered and well-aligned TiN nanotube arrays were fabricated on a Pt substrate using a template-assisted method with an anodic aluminum oxide (AAO) template and atomic layer deposition (ALD) system. We show that with the use of a Ti interlayer between the TiN nanotube arrays and Pt substrate, the TiN nanotube arrays could perfectly attach to the Pt substrate without delamination and faceted phenomena. Furthermore, the I-V curve measurements confirmed that the electric contact between the TiN nanotube arrays and substrate for use as an electrode was excellent, and its flexibility was also good for use in flexible electronic devices. Future efforts will be directed toward the fabrication of embedded electrodes in flexible plastic substrates by employing the concepts demonstrated in this study.
Highlights
Nanostructured metals and semiconductors can offer synergetic effects by maximizing combined surface and bulk properties
Template-directed fabrication is one of the most common techniques in the formation of vertically aligned nanotube arrays and could allow for precise control over the physical dimensions, such as diameter, length and interpore distance [29,30,31,32]. Nanomaterials such as nanotube arrays created by templated fabrication need additional supporting substrates
Alumina templates grown directly on a Si substrate have been proposed [33], uniformly removing the thin barrier layers of anodic aluminum oxide (AAO) remains elusive. Another method is to deposit a metal layer on the top surface of nanotube (NT)/AAO composites; in this case, adhesion between the nanotubes (NTs) and supporting substrate is essential because the mechanical stability and electrical contact determine the resulting performance and further applications, including flexible integrated energy systems
Summary
Nanostructured metals and semiconductors can offer synergetic effects by maximizing combined surface and bulk properties. Nanomaterials such as nanotube arrays created by templated fabrication need additional supporting substrates.
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