单独调控石墨烯微结构材料等离激元的近场耦合或者远场交换相互作用近年来受到科学界的广泛关注。然而，在许多石墨烯微结构材料的实际体系中，石墨烯等离激元的近场耦合和远场交换同时存在。我们拟通过调节石墨烯的费米能级和微结构尺度来研究需要同时考虑近场耦合和远场交换的物理体系，研究两种耦合机制共同作用下的干涉的新奇现象、物理机制以及应用，解释杂化系统的干涉行为。我们预计，在这种杂化系统中，可以实现如亚波长尺度的“零耦合”等单独耦合机制无法实现的现象。进一步，我们还准备将这个干涉行为和现象拓展到石墨烯微结构等离激元和金属人工微结构等离激元的耦合体系。研究结果将为新功能器件的设计和制备提供指导。该项目研究将可拓宽等离激元材料的物理调控手段，解释新的干涉现象，对石墨烯微结构材料的各种潜在应用如宽频、多频吸收，慢波和可调频滤波等相关光电器件具有指导意义。

Interactions that mediated separately by plasmons in graphene microstructures with near or far field coupling have drawn considerable attention in various scientific fields. However, in many actual graphene microstructures， both near and far field coupling of plasmons in graphene microstructures play important roles at the same time. Here, by tuning the Fermi energies and scales of graphene microstructures, we investigate the system in which near and far field coupling are equally important, study the new phenomena, physical mechanisms and applications of mediated interference, and explain the behaviors in these hybrid systems. As we expect, the phenomenon such as “zero coupling”at subwavelength scale which cannot appear in either of two couplings is achieved. Furthermore, these plasmons mediated interference phenomena and behaviors can be extended to the systems which are composed of graphene microstructures and artificial metal microstructures. The results will provide the guidance for design and preparation of new function devices. The researches of this project can widen the mediated method of plasmons, give explanation to the new interference phenomena, and have significance for the potential applications of graphene microstructures such as broadband and multiband absorption, slow light, and tunable filters.