Graphene-wrapped pine needle-like cobalt nanocrystals constructed by cobalt nanorods for efficient microwave absorption performance,RSC Advances

当前位置： X-MOL 学术 › RSC Adv. › 论文详情

Our official English website, www.x-mol.net, welcomes your feedback! (Note: you will need to create a separate account there.)

Graphene-wrapped pine needle-like cobalt nanocrystals constructed by cobalt nanorods for efficient microwave absorption performance
RSC Advances ( IF 3.9 ) Pub Date : 2021-09-23 , DOI: 10.1039/d1ra06050c
Shu-Qing Lv ₁ , Peng-Zhao Han ₂ , Xiao-Juan Zhang ₃ , Guang-Sheng Wang ₂

Affiliation

Magnetic metal nanocrystals tend to be advanced microwave absorption substances as they possess simultaneous dielectric and magnetic losses. In this study, the metallic cobalt (Co) nanocrystals with a pine needle-like nanostructure constructed by one-dimensional Co nanorods have been successfully prepared through the polyol approach. By regulating the amount of reduced graphene oxide (rGO), rGO/Co nanocomposites with different mass ratios were acquired. Experimental results demonstrate that the rGO/Co nanocomposites display excellent microwave attenuation capacity. The minimum reflection loss value can reach −57.8 dB at 12.43 GHz with a filler loading of 20 wt% at 1.8 mm. Moreover, the effective absorption bandwidth covers the frequency range of 4.2–15.5 GHz with an integrated thickness of 1.5–4.0 mm. The main absorption mechanisms include dielectric loss caused by dipole and interfacial polarization and magnetic loss arising from ferromagnetic resonance and eddy current loss. In addition, the special nanostructure effect is also beneficial to improve the EM wave absorption performance.

中文翻译：

石墨烯包裹的松针状钴纳米晶体由钴纳米棒构成，具有高效的微波吸收性能

磁性金属纳米晶体往往是先进的微波吸收物质，因为它们同时具有介电和磁损耗。在这项研究中，通过多元醇方法成功制备了由一维钴纳米棒构成的具有松针状纳米结构的金属钴（Co）纳米晶体。通过调节还原氧化石墨烯（rGO）的用量，得到不同质量比的rGO/Co纳米复合材料。实验结果表明，rGO/Co纳米复合材料表现出优异的微波衰减能力。最小反射损耗值在 12.43 GHz 时可以达到 -57.8 dB，在 1.8 mm 处填充量为 20 wt%。此外，有效吸收带宽覆盖了 4.2-15.5 GHz 的频率范围，集成厚度为 1.5-4.0 mm。主要吸收机制包括偶极子和界面极化引起的介电损耗以及铁磁共振和涡流损耗引起的磁损耗。此外，特殊的纳米结构效应也有利于提高电磁波吸收性能。

更新日期：2021-09-23

点击分享查看原文

点击收藏

公开下载

阅读更多本刊最新论文本刊介绍/投稿指南11