Abstract
Carbon nanotubes are hybridized with metal crystals to impart multifunctionality into the nanohybrids (NHs). Simple but effective synthesis techniques are desired to form both zero-valent and oxides of different metal species on carbon nanotube surfaces. Sol-gel technique brings in significant advantages and is a viable technique for such synthesis. This study probes the efficacy of sol-gel process and aims to identify underlying mechanisms of crystal formation. Standard electron potential (SEP) is used as a guiding parameter to choose the metal species; i.e., highly negative SEP (e.g., Zn) with oxide crystal tendency, highly positive SEP (e.g., Ag) with zero-valent crystal-tendency, and intermediate range SEP (e.g., Cu) to probe the oxidation tendency in crystal formation are chosen. Transmission electron microscopy and X-ray diffraction are used to evaluate the synthesized NHs. Results indicate that SEP can be a reliable guide for the resulting crystalline phase of a certain metal species, particularly when the magnitude of this parameter is relatively high. However, for intermediate range SEP-metals, mix phase crystals can be expected. For example, Cu will form Cu2O and zero-valent Cu crystals, unless the synthesis is performed in a reducing environment.
Highlights
Carbon nanotube–metal nanohybrids (NHs) are being considered for large scale use as electroand photo-catalysts [1] and are studied for electronics [2], gas sensing [3], biosensing [4], and laser [5] applications
1 mL of the samples was placed in the Oxidation-Reduction Potentials (ORPs) measurement chamber separately and the ORP was recorded
Physical Morphwoerleohgeyateadntdo 7C0 °oCmfopro1shi.tAioftner calibrating the ultrameter, 1 mL of the samples was placed in the ORP measurement chamber separately and the ORP was recorded
Summary
Carbon nanotube–metal nanohybrids (NHs) are being considered for large scale use as electroand photo-catalysts [1] and are studied for electronics [2], gas sensing [3], biosensing [4], and laser [5] applications. A simple sol-gel technique can be a viable process that can produce 100s of mg of multiwalled carbon nanotube (MWNT)–metal NHs [6]. Both zero-valent and oxides of metals can be formed on MWNT surfaces. The choice of the metal and its inherent electronic properties will dictate the resulting crystalline phases. Since preserving the oxidation state of the metal crystals is crucial to render their reactive properties [7,8], understanding the mechanism of nanocrystal formation with a particular crystal phase is necessitated
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