The equivalent circuit model for electrostatic and magnetostatic biased tunable graphene as the absorption material

2016 Asia-Pacific International Symposium on Electromagnetic Compatibility (APEMC) Pub Date : 2016-05-17 DOI:10.1109/APEMC.2016.7522779

Y. S. Cao, L. J. Jiang, A. Ruehli

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Abstract

Graphene is being proposed as a new nano material for EMC shielding and absorption due to its tunable resistive characteristics. The surface conductivity of graphene can be flexibly tuned by the electrostatic and magnetostatic bias applied on the graphene surface. Hence, its absorption and radiation characteristics of graphene are changed accordingly. The static electric bias applied on the graphene patch can change the chemical potential and the surface conductivity of graphene. The static magnetic field can make the conductivity a dispersive and anisotropic tensor, which complicates most modeling methodologies. In this paper, a novel equivalent circuit model is proposed for graphene with the electrostatic and magnetostatic bias, respectively. It employs the equivalent circuit model that is derived from the electric field integral equation to analyze the wave propagation and absorption through graphene. It provides a general modeling approach for graphene's applications as the EMC materials.

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建立了静电和静磁偏置可调谐石墨烯作为吸收材料的等效电路模型

石墨烯由于其可调谐的电阻特性而被提出作为一种新的电磁兼容屏蔽和吸收纳米材料。通过施加在石墨烯表面的静电和静磁偏压，可以灵活地调节石墨烯的表面电导率。因此，石墨烯的吸收和辐射特性也发生了相应的变化。施加在石墨烯贴片上的静电偏压会改变石墨烯的化学势和表面电导率。静磁场会使电导率成为色散和各向异性张量，这使大多数建模方法变得复杂。本文提出了一种具有静电偏置和静磁偏置的石墨烯等效电路模型。采用由电场积分方程推导出的等效电路模型，分析了波在石墨烯中的传播和吸收。它为石墨烯作为电磁兼容材料的应用提供了一种通用的建模方法。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2016 Asia-Pacific International Symposium on Electromagnetic Compatibility (APEMC)

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