手征超常介质的不对称传输特性及其机理研究

项目名称： 手征超常介质的不对称传输特性及其机理研究

项目编号： No.61475079

项目类型： 面上项目

立项/批准年度： 2015

项目学科： 无线电电子学、电信技术

项目作者： 董建峰

作者单位： 宁波大学

项目金额： 82万元

中文摘要： 手征超常介质的不对称传输性质是新发现的电磁现象，而且手征超常介质具有亚波长的结构尺寸，便于小型化和集成化，为控制电磁波(光波)的传输与偏振提供了一个新的途径。本项目将通过理论分析、数值模拟优化设计、实验样品制备和测试及分析相结合的方法，系统地研究结构形状、几何参数和材料参数等对单层、双层和多层手征超常介质不对称传输特性的影响，阐明手征超常介质产生不对称传输的物理机理，特别是各向异性、手征性、损耗等对不对称传输性质的具体影响，优化设计和实际研制出具有极大不对称传输参数、在微波段和光波段实现光学二极管功能的手征超常介质，并实现不对称传输的多功能化如宽带、可调谐、多频带等，利用手征超常介质不对称传输的独特性质设计新颖的微波和光子学器件如宽带圆偏振转换器、光隔离器、滤波器等。本项目有望产生具有创新意义和自主知识产权的研究成果，对新型的微波和光子器件的设计和制作提供科学依据和研究基础。

中文关键词： 手征超常介质；不对称传输；手征性；各向异性

英文摘要： The asymmetric transmission of electromagnetic waves in the chiral metamaterial is a new electromagnetic phenomenon. The chiral metamaterial has sub-wavelength unit cell structure, thus it can be miniaturized and integrated, which promise a new route to control transmission and polarization of the electromagnetic wave (optical wave). The purpose of this project is to investigate effects of structure shape, geometrical size, and material parameters on the asymmetric transmission for single, double and multi-layer chiral metamaterials by theoretical analysis, numerical simulation and optimizing design, sample fabrication and measurement, to clarify mechanism of the asymmetric transmission of electromagnetic waves in the chiral metamaterial via anisotropy, chirality and loss. We will design and fabricate the chiral metamaterials with large asymmetric transmission parameter which can be used as optical diode operating in microwave and optical frequency regions, to realize broadband, tunable, multi-band asymmetric transmission. Take advantage of the unique properties of asymmetric transmission in the chiral metamaterial, we can design novel microwave and optical devices, such as broadband circular polarization transformer, isolator, and filter. This project would product new significant results with independent intellectual property, they provide scientific foundation for design and fabrication of novel microwave and optical devices.

英文关键词： chiral metamaterial;asymmetric transmission;chirality;anisotropy