Scalable seeded growth of tungsten oxide nanowires for energy applications

2014 11th Annual High Capacity Optical Networks and Emerging/Enabling Technologies (Photonics for Energy) Pub Date : 2014-12-01 DOI:10.1109/HONET.2014.7029395

Tao Sheng, Haitao Zhang

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Abstract

Based on the vapor-solid mechanism, a seeded growth method was developed for the growth of tungsten oxide (WO3) nanowires. In this approach, beside the tungsten source heat at high temperature, additional tungsten seed particles were dispersed on the substrate to promote the growth of nanowires. The surface oxidation of the tungsten seed particles induced the local growth of nanowire seeds, which were further developed into dense and long nanowire arrays by the vapor transport from the tungsten source. Systematic study on the oxidization of tungsten particles was performed and optimal conditions for the seed formation were analyzed by the comprehensive consideration of growth parameters (e.g., growth temperature, particle size, and oxygen flow rate). The WO3 nanowires specimens were characterized using scanning electron microscopy, energy dispersive X-ray spectroscopy, and X-ray diffraction. The seeded growth can enhance the growth of WO3 nanowires with controllable dimensions, providing a facile and scalable method for the growth of nanowires with large yield.

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用于能源应用的氧化钨纳米线的可扩展种子生长

基于气固机制，提出了一种用于氧化钨纳米线生长的种子生长方法。在该方法中，除了高温钨源加热外，在衬底上分散额外的钨籽颗粒，以促进纳米线的生长。钨籽粒子的表面氧化诱导纳米线粒子局部生长，并通过钨源的蒸气输送进一步发育成致密的长纳米线阵列。对钨颗粒的氧化过程进行了系统的研究，综合考虑生长参数(如生长温度、粒径、氧流量)，分析了钨颗粒形成种子的最佳条件。采用扫描电镜、x射线能谱和x射线衍射对WO3纳米线样品进行了表征。种子生长可以促进WO3纳米线的生长，尺寸可控，为大产量纳米线的生长提供了一种简便、可扩展的方法。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

2014 11th Annual High Capacity Optical Networks and Emerging/Enabling Technologies (Photonics for Energy)

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