“
“Background The synthesis of carbon nanomaterials (CNMs) has received tremendous interest in the last two decades [1–5]. These endeavours have been driven by the need to exploit the unique chemical and physical properties associated with CNMs (e.g. strength [6, 7]), as well as the desire to develop synthetic strategies AZD2171 manufacturer that are cost-effective and non-destructive to the environment [8–10]. The synthesis of well-structured CNMs is known to require three main components: a source of energy, a source of carbon and a template or catalyst [11]. Recent publications have shown that efforts

have focused on using lower energy sources (low-temperature synthesis), natural or recyclable carbon reactants and appropriate templates [12–15]. One of the main learn more challenges in the chemical industry has been the development of low-cost, recyclable and effective substrates (catalysts) upon which well-structured CNMs can grow [16–18]. This has prompted

interest in several industrial by-products that contain components that are known to actively decompose carbon reagents into CNMs [19–22]. Of interest has been the study of the effect of coal fly ash as a catalyst for carbon nanomaterial growth. Fly ash is typically a www.selleckchem.com/products/pnd-1186-vs-4718.html by-product of several energy and power generation industries throughout the world, with an estimated 25 million tons produced annually in South Africa [23]. Currently, only a fraction of this material is utilized effectively, with the remainder proving to be environmentally hazardous due to the presence of several toxic elements like mercury, lead, etc. Teicoplanin [24–26]. It has been observed that fly ash can be effective at producing carbon nanotubes (CNTs), provided that the reaction conditions are correct (as summarised below) [13, 27, 28]. This is due mainly to the transition metal contents in certain fly ashes. Generally, fly ash consists of SiO2 (c.a. 73.6%), Al2O3 (c.a. 18.7%), Fe2O3 (c.a. 1.9%) and TiO2 (c.a. 1.4%) and can also include trace amounts of CaO, BaO, MgO, MnO, P2O5 as well as copper and

chromium oxides [29]. However, metals such as Fe/Ni, Ni, Co, Mn, Cu, V, Cr, Mo and Pd have been used in the past as catalysts for CNT and carbon nanofiber (CNF) syntheses [30–35], hence the potential of fly ash to be used as a catalyst in this reaction. In this regard, Yasui et al. [28] have used Japanese fly ash, where Fe was added to the ash to enhance its activity. Although CNTs were produced, these were of a very low yield and poor quality. Dunens et al. [36] showed that CNTs and CNFs could be produced by Australian coal fly ash using the chemical vapour deposition (CVD) method. However, in their case, multiple steps were followed, as iron (which was low in their fly ash, <2.5%) also had to be impregnated into their substrate and ethylene (an expensive carbon source) was used. This therefore resulted in the high cost of CNT and CNF production, although a recycled waste material was used as a catalyst.