Planar artificial materials possess captivating optical characteristics that arise from the activation of electric and magnetic dipole moments, which are stimulated by external electric and magnetic fields. This stimulation leads to plasmonic resonance, which occurs at specific frequencies when the materials oscillate. These phenomena offer significant advantages in achieving wide bandwidths for various components in microwave communities [1] . The goal of this article is to explore how periodic and aperiodic lattice structures impact the resonance properties of these structures. The findings indicate that both periodic and aperiodic lattice structures have minimal effects on the resonances. Instead, the resonant frequencies are primarily influenced by metamaterial properties, such as dielectric permittivity ${(}\varepsilon{)}$ and magnetic permeability ${(}{\mu}{)}$ , which exhibit resonance behavior.

中文翻译：

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周期性和非周期性晶格结构中的共振效应


平面人造材料具有迷人的光学特性，这些特性是由外部电场和磁场刺激的电偶极矩和磁偶极矩的激活产生的。这种刺激会导致等离子体共振，当材料振荡时，等离子体共振会在特定频率下发生。这些现象为微波领域的各种组件实现宽带宽提供了显着的优势[1]。本文的目的是探讨周期性和非周期性晶格结构如何影响这些结构的共振特性。研究结果表明，周期性和非周期性晶格结构对共振的影响最小。相反，谐振频率主要受超材料特性的影响，例如介电常数 ${(}\varepsilon{)}$ 和磁导率 ${(}{\mu}{)}$ ，它们表现出谐振行为。