Hydrothermal growth: Influence of Process parameters to design TiO2 nanostructures

Abstract

Extended Abstract Over the past several decades, numerous research activities have been focused on fabrication of titanium oxide (TiO 2 ) films owing to their broad applications in various fields such as medicine [1] (cancer treatment, antimicrobial), energy [2] (water splitting, photovoltaic), environment (air and water purification), gas sensors, photocatalysis, and self-cleaning [3]. Currently, various deposition methods have been employed to develop the TiO 2 including sol gel [4], solvothermal, chemical vapor deposition, thermal oxidation and hydrothermal method [5]. When specifically compared to other methods, the hydrothermal method has many advantages: (i) the required equipment and processing conditions is easier, (ii) during crystallization processes, growing crystals/crystallites tend to reject impurities present in the growth environment, (iii) by changing the hydrothermal conditions (such as titanium precursor concentration, reaction time, reaction temperature, additives, substrate orientation, and pH of growth solution), crystalline products could be easily modified with different compositions, morphologies and structures. However, slight variations in these parameters result in significant alterations of the properties of TiO 2 . Herein, we report the formation chemistry, growth mechanism of TiO 2 nanostructures in the surface of FTO substrate. The effects of key hydrothermal experimental conditions have been discussed to understand the different obtained morphologies. Indeed, XRD and Raman analysis confirmed the formation of the rutile phase of TiO 2 . Morphological studies showed that we can obtain nanorods with