A magnetoactive metamaterial based on a structured ferrite

S. Polevoy, G. Kharchenko, S. Tarapov, O. Kravchuk, K. Kuršelis, B. Chichkov, N. Slipchenko
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Abstract

Subject and Purpose. The use of spatially structured ferromagnets is promising for designing materials with unique predetermined electromagnetic properties welcome to the development of magnetically controlled microwave and optical devices. The paper addresses the electromagnetic properties of structured ferrite samples of a different shape (spatial geometry) and is devoted to their research by the method of electron spin resonance (ESR). Methods and methodology. The research into magnetic properties of structured ferrite samples was performed by the ESR method. The measurements of transmission coefficient spectra were carried out inside a rectangular waveguide with an external magnetic field applied. Results. We have experimentally shown that over a range of external magnetic field strengths, the frequency of the ferromagnetic resonance (FMR) of grooved ferrite samples (groove type spatial geometry) increases with the groove depth. The FMR frequency depends also on the groove orientation relative to the long side of the sample. We have shown that as the external static magnetic field approaches the saturation field of the ferrite, the FMR frequency dependence on the external static magnetic field demonstrates "jump-like" behavior. And as the magnetic field exceeds the ferrite saturation field, the FMR frequency dependence on the groove depth gets a monotonic character and rises with the further growth of the field strength. Conclusion. We have shown that the use of structured ferrites as microwave electronics components becomes reasonable at magnetic field strengths exceeding the saturation field of the ferrite. At these fields, such a ferrite offers a monotonically increasing dependence of the resonant frequency on the external magnetic field and on the depth of grooves on the ferrite surface. Structured ferrites are promising in the microwave range as components of controlled filters, polarizers, anisotropic ferrite resonators since they can provide predetermined effective permeability and anisotropy
一种基于结构铁氧体的磁活性超材料
主题和目的。利用空间结构的铁磁体设计具有独特预定电磁特性的材料是有希望的,这对磁控微波和光学器件的发展是有欢迎的。本文讨论了不同形状(空间几何)结构铁氧体样品的电磁特性,并利用电子自旋共振(ESR)方法对其进行了研究。方法和方法论。采用ESR法对结构铁氧体样品的磁性能进行了研究。透射系数光谱的测量在外加磁场作用下的矩形波导内进行。结果。我们的实验表明,在一定的外磁场强度范围内,沟槽铁氧体样品(沟槽型空间几何)的铁磁共振频率(FMR)随着沟槽深度的增加而增加。FMR频率还取决于相对于样品长边的凹槽方向。我们已经证明,当外部静态磁场接近铁氧体的饱和场时,FMR频率对外部静态磁场的依赖表现出“跳变”行为。当磁场超过铁氧体饱和场时,FMR频率对沟槽深度的依赖呈现单调特征,并随着磁场强度的进一步增大而增大。结论。我们已经证明,当磁场强度超过铁氧体的饱和场时,使用结构铁氧体作为微波电子元件是合理的。在这些磁场下,这种铁氧体的谐振频率随外加磁场和铁氧体表面凹槽深度的变化呈单调递增的趋势。结构铁氧体可以提供预定的有效磁导率和各向异性,在微波范围内作为可控滤波器、极化器、各向异性铁氧体谐振器的组成部分是有前途的
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