绿色合成纳米材料的低成本微波反应器

IF 0.4 Q4 ENGINEERING, MULTIDISCIPLINARY
Leydy Tatiana Figueroa Ariza, M. Duarte Espinosa, B. A. Páez Sierra
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引用次数: 0

摘要

本论文是关于一种用于纳米材料绿色合成的低成本微波反应器。这篇论文反映了新格拉纳达军事大学NanoFab小组在纳米光子学、传感器和纳米技术领域取得的研究成果。2019年期间进行了调查和分析。问题:由于污染物试剂和副产品的产生,传统的合成过程通常会影响环境和人类健康。目的:本研究的目的是改进微波炉,以帮助绿色合成纳米材料,在国土安全中具有潜在的应用前景。方法:对一台家用微波炉进行改造。所实施的反应器具有用于减少挥发性元素的热交换单元和用于局部均质化的数字磁力搅拌器。合成开始于柠檬酸三钠溶液,在37°C下连续搅拌。接下来,将前体与硝酸银混合2分钟。然后,将混合物在微波反应器中处理20分钟。最后,纳米颗粒被回收。结果:自制的微波反应器适合制备纳米颗粒。特别是,反应物的20分钟微波暴露时间导致纳米颗粒尺寸在80-90纳米之间。为了探测反应参数,进行了阻抗谱分析。结果表明,纳米银介质的电阻为2.5欧姆,而柠檬酸钠和硝酸盐介质的电阻分别为8.8欧姆和11.8欧姆。结论:改进后的微波反应器适用于纳米材料的制备。在纳米颗粒合成过程中,需要较少的溶剂。微波合成允许绿色纳米材料的生产,对环境的影响很小。限制:反应物在固定微波腔内的均匀加热受限于波导设计;在这种情况下,多模态微波波导。原创性:用于纳米材料生产和绿色合成的低成本反应器。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Low-cost microwave reactor for green synthesis of nanomaterials
Introduction: This contribution is about a low-cost microwave reactor for green synthesis of nanomaterials. The paper reflects research results achieved at the NanoFab group of the Universidad Militar Nueva Granada, within the line of nanophotonics, sensors and nanotechnology. Investigations and analyses were carried out during 2019. Problem: Conventional synthesis processes usually affect the environment and human health, due to contaminant reagents and generation of by-products. Objective: The aim of this research is the modification of a microwave oven that assists in the green synthesis of nanomaterials with potential applications in homeland security. Methodology: In this investigation, the modification of a domestic microwave was carried out. The implemented reactor features a heat exchange unit to reduce volatile elements, and a digital magnetic stirrer for local homogenization. Synthesis begins with a trisodium-citrate solution, continuously stirred at 37 °C. Next, the precursor is mixed with silver-nitrate for 2 minutes. Then, the mixture was treated for 20 minutes in the microwave reactor. Finally, the nanoparticles are recovered. Results: The homemade microwave reactor is suitable for producing nanoparticles. Particularly, the 20-minute microwave exposure time for the reactants results in a nanoparticle size between 80-90 nm. To probe reaction parameters, impedance spectroscopy analysis is performed. Results revealed that the resistance of the medium of silver nanoparticles is 2.5 ohms, while for sodium citrate and nitrate it is 8.8 and 11.8 ohms, respectively. Conclusion: It is demonstrated that the modified microwave reactor is suitable for nanomaterial production. Lower amounts of solvent are required during nanoparticle synthesis. Microwave synthesis allows for green nanomaterials production with a minor impact on the environment. Limitation: Homogeneous heating of reactants in a stationary microwave cavity is limited to waveguide design; in this case, to a multimodal-microwave waveguide. Originality: Low-cost reactor for nanomaterial production and greener synthesis.
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来源期刊
Ingenieria Solidaria
Ingenieria Solidaria ENGINEERING, MULTIDISCIPLINARY-
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