碳纳米纤维超高产合成及磁性和微波吸收性能(英文) 被引量：1

Synthesis of Carbon Nanofibers in Ultrahigh Yield and Their Magnetic and Microwave Absorption Properties

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摘要利用溶胶凝胶和氢气还原的方法合成出Fe/SnO2纳米颗粒。通过催化裂解乙炔的方法,可在该纳米颗粒表面合成出高产率、高选择性的碳纳米纤维。研究表明温度对所合成碳纳米纤维的产率、尺寸和微结构有着很大的影响。获得了超高的碳纳米纤维的产率（278和445）,并且所合成的碳纳米纤维材料表现出较好的微波吸收性能。在15.29 GHz处,样品的反射损耗达到最小,其数值约为-7.28 dB,且可在3.90~18 GHz内获得低于-5 dB的反射损耗值。因此,提出了一个简单、环境友好的碳纳米纤维超高产合成路径,该路径有利于该材料的广泛使用。 Over Fe/SnO2 nanoparticles generated by a combined sol-gel and hydrogen reduction method, the high selectivity of carbon nanofibers （CNFs） were synthesized in large quantities through the catalytic decomposition of acetylene. The studies demonstrate that the temperature has a great impact on the yield, dimension and microstructure of the as-synthesized CNFs. And the ultrahigh yields （278 and 445） of the CNFs were obtained. Moreover, the as-synthesized CNF mate-rial exhibits good microwave absorption properties. The minimum reflection loss （RL） of the obtained sample is about - 7.28 dB at 15.29 GHz, and the RL below - 5 dB can be obtained in 3.90 - 18 GHz. Therefore, a simple and environment-friendly route was proposed for the synthesis of the CNFs in ultrahigh yield. The route benefits a wide use of the material.

作者祁小四顼建乐钟伟都有为

机构地区贵州大学理学院南京大学固体微结构物理国家重点实验室南京大学江苏省纳米技术重点实验室

出处《微纳电子技术》 CAS 北大核心 2015年第3期142-147,156,共7页 Micronanoelectronic Technology

基金 National Science Foundation of China(11364005,11174132) Foundation of the National Key Project for Basic Research(2010CB923402,2011CB922102) International Cooperation Project of Guizhou Province(2012-7002) National Science Foundation of Guizhou Province(2014-2059)

关键词 Fe/SnO2纳米颗粒碳纳米纤维化学气相沉积(CVD)法超高产反射损耗微波吸收性能 Fe/Sn02 nanoparticle carbon nanofiber chemical vapor decomposition （CVD）method ultrahigh yield reflection loss microwave absorption property

分类号 TB383 [一般工业技术—材料科学与工程] O482.54 [一般工业技术—材料科学与工程]

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