Abstract
Abstract Silicon photonics is playing a key role in areas as diverse as high-speed optical communications, neural networks, supercomputing, quantum photonics, and sensing, which demand the development of highly efficient and compact light-processing devices. The lithographic segmentation of silicon waveguides at the subwavelength scale enables the synthesis of artificial materials that significantly expand the design space in silicon photonics. The optical properties of these metamaterials can be controlled by a judicious design of the subwavelength grating geometry, enhancing the performance of nanostructured devices without jeopardizing ease of fabrication and dense integration. Recently, the anisotropic nature of subwavelength gratings has begun to be exploited, yielding unprecedented capabilities and performance such as ultrabroadband behavior, engineered modal confinement, and sophisticated polarization management. Here we provide a comprehensive review of the field of subwavelength metamaterials and their applications in silicon photonics. We first provide an in-depth analysis of how the subwavelength geometry synthesizes the metamaterial and give insight into how properties like refractive index or anisotropy can be tailored. The latest applications are then reviewed in detail, with a clear focus on how subwavelength structures improve device performance. Finally, we illustrate the design of two ground-breaking devices in more detail and discuss the prospects of subwavelength gratings as a tool for the advancement of silicon photonics.
Highlights
Optical metamaterials are synthetic structures with physical properties that are not readily accessible in nature
Since the invention of silicon subwavelength grating (SWG) metamaterial waveguides at the beginning of the millennium [8,9,10,11,12,13,14,15,16], research on these structures has been growing rapidly, with many impressive devices demonstrated for a wide range of applications
The flexibility afforded by SWG metamaterial waveguides enables designers to choose the optimum material properties for each application
Summary
Optical metamaterials are synthetic structures with physical properties that are not readily accessible in nature. While the large refractive index contrast between silicon (nSi ≈ 3.5) and its native oxide (nSiO2 ≈ 1.45) enables dense integration, the scarcity of CMOS-compatible materials with intermediate refractive indices restricts the design space. This limitation can be overcome by structuring silicon waveguides at the. The optical properties of these metamaterials are instrumental in understanding how subwavelength structures are exploited to enhance each family of devices we revise in Section 3: waveguides, broadband couplers, beam expanders, polarization controllers, filters, wavelength- and mode-division multiplexing devices, fiber-chip couplers, optical antennas, and evanescent field sensors.
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