Research on antennas based on nanophotonic materials

Abstract

In this study, the performance of bilayer graphene and its dual-frequency reconfigurable antenna structure on SiO2/Si substrates was explored. The research underscores that when compared to traditional radio frequency and microwave antennas, the performance of nano-optical antennas is strongly contingent on their size and shape. It is also intimately related to their intrinsic material properties, highlighting the unique physical attributes and scaling behavior of nano-photonic antennas. A salient feature of bilayer graphene is its ability to dynamically adjust its conductivity by applying an external voltage between the two layers, offering new prospects for its application in micro-nano electronics and photonics. Through a comparative analysis of radiation decay rates and quantum efficiency, it was determined that metallic materials exhibit much higher non-radiative losses than nano-optical materials. This research provides a foundational theoretical framework for future experiments and paves the way for creating secure information networks. However, the study acknowledges the potential challenges in the real-world application and production of nano-photonic antennas, suggesting further exploration in optimizing their structure to enhance efficiency.