New type flashing-speed dynamic calcination technology is used for the production of active nano-ZnO.
采用新型闪速动态煅烧技术装备,在活性纳米氧化锌生产中应用。
Different prepared conditions, microstructure and morphology of nano-ZnO were investigated by means of XRD and TEM.
借助于XRD、TEM等测试手段,对纳米氧化锌粉体的制备条件和其对粒度、形貌的影响进行了分析研究。
The influence of the mixing temperature, mixer and processing technology on the dispersibility of nano-ZnO in BR compound was investigated.
研究不同的加工温度、混炼设备、加工工艺对纳米氧化锌在BR胶料中分散性的影响。
The experimental results proved that the direct addition of nano-ZnO to LDPE facilitated good combined properties for the composites by using StZn as the dispersing agent and other suitable materials.
实验结果表明:可使用硬脂酸锌作为分散剂,与其他物质配合,保证一定的量,将纳米氧化锌直接添加进低密度聚乙烯中可使复合材料表现良好的综合性能。
Effects of particle sizes on kinetic parameters were studied by the reaction of nano ZnO with solution of sodium bisulfate.
以纳米氧化锌与硫酸氢钠溶液的反应为模型体系,研究了反应物粒度对动力学参数的影响规律。
This paper introduces the current situation of several nano-powder material in commercials production , including nano - TiO2 , nano - ZnO, nano - CaCO3 , nano - Ni powder.
介绍了纳米二氧化钛、纳米氧化锌、纳米碳酸钙和纳米镍粉几种纳米粉体材料的生产现状。
The ZnO nanorod arrays grow firstly on FTO glass through a hydrothermal process and then act as templates for the fabrication of rod-in-tube nano-architectures during ultrasonication.
氧化锌纳米棒阵列最初是在FTO玻璃上通过水热法制备出基体后通过超声波生长出棒中筒纳米结构。
Netlike nano ZnO and nano TiO2 were compared on the photodegradation of dye solutions in the same conditions. The results show that self-regulating nano ZnO was better than nano TiO2 obviously.
本文还比较了自制网络状纳米氧化锌与纳米二氧化钛对有机染料的降解性能,氧化锌的降解效果明显优于二氧化钛。
Vertically aligned hierarchical ZnO rod-in-tube nano-architecture arrays are produced via a two-step process including an initial hydrothermal reaction followed by ultrasonication growth.
垂直排列的氧化锌棒中筒纳米结构阵列是通过两个步骤制备而得的,其中包括一个初始水热反应以及超声增长反应。
Vertically aligned hierarchical ZnO rod-in-tube nano-architecture arrays are produced via a two-step process including an initial hydrothermal reaction followed by ultrasonication growth.
垂直排列的氧化锌棒中筒纳米结构阵列是通过两个步骤制备而得的,其中包括一个初始水热反应以及超声增长反应。
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