Wu Tianwei, Li Yankun, Feng Xilin, Wu Shuang, Gao Zihe, Feng Liang
Department of Materials Science and Engineering, University of Pennsylvania, Philadelphia, Pennsylvania 19104, United States.
Department of Electrical and Systems Engineering, University of Pennsylvania, Philadelphia, Pennsylvania 19104, United States.
Nano Lett. 2023 May 10;23(9):3866-3871. doi: 10.1021/acs.nanolett.3c00474. Epub 2023 Apr 24.
Far-field optical beam steering is a fast-growing technology for communications, spatial ranging, and detections. Nonmechanical optical phased arrays based on straight waveguides have been studied recently, where the beam emission angle to the propagation axis can be scanned by conveniently tuning the wavelength. However, the dispersion of the waveguide limits the wavelength sensitivity of beam steering and the deliberately created emitters inevitably introduce in-line backscattering on-chip. To overcome these limitations, here, we report a robust and back-reflection-free topological photonic integrated circuit, where different functionalities, such as beam splitting, routing, and far-field steering, are defined by strategic arrangements of lattices with different topological modulations simply controlled by a single lattice deformation parameter. Benefiting from the robust topological scheme, an extra band flattening is applied to achieve far-field steering with high wavelength sensitivity.
远场光束转向是一种在通信、空间测距和探测领域快速发展的技术。基于直波导的非机械光学相控阵最近已得到研究,其中通过方便地调谐波长,可以扫描光束相对于传播轴的发射角度。然而,波导的色散限制了光束转向的波长灵敏度,并且特意制造的发射器不可避免地会在芯片上引入在线背向散射。为了克服这些限制,在此我们报告了一种稳健且无背反射的拓扑光子集成电路,其中诸如光束分裂、路由和远场转向等不同功能,是通过具有不同拓扑调制的晶格的策略性排列来定义的,这些排列只需通过单个晶格变形参数就能简单控制。受益于稳健的拓扑方案,应用了额外的能带平坦化来实现具有高波长灵敏度的远场转向。