【 摘 要 】

Metal oxide nanowires are materials of interest in number of applications such as lithium ion batteries, solar cells, catalyst support, and gas sensing due to their unique charge transport properties and short diffusion length scales. To incorporate nanowires for any applications, one would need hundreds of grams to kilograms of these nanowires. However, state-of-the-art methods for producing metal oxide nanowires are limited to producing only milligrams to a gram in a batch. Hence, there is a need to develop scalable and cost effective processes and reactors to address this challenge. Direct gas phase oxidation of zinc metal powders using a downward atmospheric microwave plasma allowed producing 50-100 grams of zinc oxide nanowires per day. The downstream plasma reactor has certain limitations in terms of scalability: short residence time and plasma instability. Thus, a more improved reactor design is needed for continuous production of nanowire materials at commercially viable production rates. In this dissertation, a fluidized bed reactor is designed and studied for scalable production. The key feature of the reactor involves feed particles being fluidized in the flame to increase residence time. The reactor is equipped with cyclone and bag house filter housing enabling efficient powder collection and allows continuous production. Experiments using fluidized bed reactor produced single crystalline nanowires of about 30-200 nm in diameter and 0.5 – 2 mm in length. The nanowire morphology could be controlled by gas flow rate, powder feeding rate and flame type. A production rate of 1.2 kg of nanowires per hour and yield of about 90% has been demonstrated. The zinc oxide nanowires prepared in this work have been tested as catalyst support for hydro-desulfurization of diesel. The sulfur content was reduced from 200 ppm to less than 1 ppm and the catalyst was active for over 100 hours. Another concept termed as solvo-plasma oxidation has been demonstrated earlier with producing nanowires of titania and related transition metals. The technique involves the synthesis of nanowires using oxidation of metal containing precursors in the presence of alkali salts. The reaction time scales were on the order of few seconds to a minute which is about 3 to 4 orders of magnitude faster than that using a hydrothermal method. Growth rates higher than 1 mm/min were obtained. Here, the concept is studied with tin oxide first to see the ability to produce nanowires and then to understand the mechanism responsible for one-dimensional growth. Experiments

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