材料科学
宽带
光子晶体
极化(电化学)
反向
纳米光子学
光学
光电子学
计算机科学
拓扑优化
带宽(计算)
光子学
拓扑(电路)
电子工程
电信
电气工程
物理
工程类
有限元法
几何学
物理化学
化学
热力学
数学
作者
Ruhuan Deng,Xinhao Wang,Yi Zuo,Zhen Liu,Feifan Wang,Chao Peng,Tongyu Li,Wenzhe Liu,Xiaohan Liu,Lei Shi
标识
DOI:10.1002/adom.202303218
摘要
Abstract Polarization is a crucial characteristic of electromagnetic fields, and the ability to fully control it has many useful applications. While novel nanophotonic devices have been designed to achieve unprecedented capability to manipulate light on demand, their usage in the complete control of polarization states for the transmitted light has been relatively limited, and traditional design methods always produce devices with narrow operation bandwidths. In this work, a two‐phase topology optimization strategy is proposed in conjunction with adjoint method to inverse design photonic crystal slabs capable of complete polarization control. It successfully produces devices operating over a broad bandwidth that is significantly larger than the current state‐of‐the‐art designs, and their performances are also robust to material loss. This is also find that the C 2 v symmetry of the structure can regularize the problem, so that less simulation time and faster convergence can be obtained without compromising performance. This study demonstrates the power of the inverse design method, which can be further applied to achieve more complex polarization control and beyond.
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