Fe 纳米薄片表面包覆 SiO2 纳米壳后吸波性能增强。

Enhanced microwave absorption of Fe nanoflakes after coating with SiO2 nanoshell.

机构信息

Institute of Applied Magnetics, Key Laboratory for Magnetism and Magnetic Materials of Ministry of Education, Lanzhou University, Lanzhou, People's Republic of China.

出版信息

Nanotechnology. 2010 Mar 5;21(9):095708. doi: 10.1088/0957-4484/21/9/095708. Epub 2010 Feb 8.

DOI:10.1088/0957-4484/21/9/095708

PMID:20139492

Abstract

Fe nanoflakes were prepared by the ball-milling technique, and then were coated with 20 nm-thick SiO(2) to prepare Fe/SiO(2) core-shell nanoflakes. Compared with the uncoated Fe nanoflakes, the permittivity of Fe/SiO(2) nanoflakes decreases dramatically, while the permeability decreases slightly. Consequently, reflection losses exceeding - 20 dB of Fe/SiO(2) nanoflakes are obtained in the frequency range of 3.8-7.3 GHz for absorber thicknesses of 2.2-3.6 mm, while the reflection loss of uncoated Fe nanoflakes almost cannot reach - 10 dB in the same thickness range. The enhanced microwave absorption of Fe/SiO(2) nanoflakes can be attributed to the combination of the proper electromagnetic impedance match due to the decrease of permittivity and large magnetic loss due to strong and broadband natural resonance. The key to the combination is the coexistence of the nanoshell microstructure and the nanoflake morphology.

摘要

采用球磨技术制备了 Fe 纳米薄片，并在其表面包覆了 20nm 厚的 SiO2，得到了 Fe/SiO2 核壳纳米薄片。与未包覆的 Fe 纳米薄片相比，Fe/SiO2 纳米薄片的介电常数显著降低，而磁导率略有降低。因此，对于吸收体厚度为 2.2-3.6mm 的情况，在 3.8-7.3GHz 的频率范围内，Fe/SiO2 纳米薄片的反射损耗超过了-20dB，而在相同厚度范围内，未包覆的 Fe 纳米薄片的反射损耗几乎无法达到-10dB。Fe/SiO2 纳米薄片增强的微波吸收归因于介电常数降低导致的适当的电磁阻抗匹配以及强且宽频带自然共振导致的大磁损耗的结合。这种结合的关键是纳米壳微结构和纳米片形态的共存。

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Fe 纳米薄片表面包覆 SiO2 纳米壳后吸波性能增强。

Enhanced microwave absorption of Fe nanoflakes after coating with SiO2 nanoshell.

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