Wavefront shaping for reconfigurable beam steering in lithium niobate multimode waveguide

AbstractMetasurfaces have paved the way for high performance wavefront shaping and beam steering applications. Phase-gradient metasurfaces (PGM) are of high importance owing to the powerful and relatively systematic tool they offer for manipulating electromagnetic wave fronts and achieving various functionalities. Herein, we numerically present a novel unit cell known as bipodal cylinders (BPC), made of Silicon (Si) and placed on a Silicon dioxide (SiO2) substrate to be compatible with CMOS fabrication techniques and to avoid field leakage into a high index substrate. Owing to its geometrical structure, the BPC structure provides a promising unit cell for electromagnetic wave manipulation. We show that BPC offers a way to shift the electric dipole mode to a frequency higher than that of the magnetic dipole mode. We investigate the effect of varying different geometrical parameters on the performance of such unit cell. Building on that, a metasurface is then presented that can achieve efficient electromagnetic beam steering with high transmission of 0.84 and steering angle of 15.2°; with very good agreement with the theoretically predicted angle covering the whole phase range from 0 to 2$$\pi$$ π .

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Beam Formation and Vernier Steering Off of a Rough Surface

Micromachines ◽

10.3390/mi12080871 ◽

2021 ◽

Vol 12 (8) ◽

pp. 871

Author(s):

Eric K. Nagamine ◽

Kenneth W. Burgi ◽

Samuel D. Butler

Keyword(s):

Rough Surface ◽

Beam Steering ◽

Superior Performance ◽

Line Of Sight ◽

Beam Formation ◽

Wavefront Shaping ◽

Inverse Diffusion ◽

Scanning Range ◽

Iterative Feedback ◽

Illumination Source

Wavefront shaping can refocus light after it reflects from an optically rough surface. One proposed use case of this effect is in indirect imaging; if any rough surface could be turned into an illumination source, objects out of the direct line of sight could be illuminated. In this paper, we demonstrate the superior performance of a genetic algorithm compared to other iterative feedback-based wavefront shaping algorithms in achieving reflective inverse diffusion for a focal plane system. Next, the ability to control the pointing direction of the refocused beam with high precision over a narrow angular range is demonstrated, though the challenge of increasing the overall scanning range of the refocused beam remains. The method of beam steering demonstrated in this paper could act as a vernier adjustment to a coarse adjustment offered by another method.

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High Q Resonant Sb2S3-Lithium Niobate Metasurface for Active Nanophotonics

Nanomaterials ◽

10.3390/nano11092373 ◽

2021 ◽

Vol 11 (9) ◽

pp. 2373

Author(s):

Qi Meng ◽

Xingqiao Chen ◽

Wei Xu ◽

Zhihong Zhu ◽

Xiaodong Yuan ◽

...

Keyword(s):

Lithium Niobate ◽

Phase Change ◽

Optical Switching ◽

Phase Change Materials ◽

Beam Steering ◽

Light Modulation ◽

Low Loss ◽

High Q ◽

Nonlinear Properties ◽

Nanophotonic Devices

Phase change materials (PCMs) are attracting more and more attentions as enabling materials for tunable nanophotonics. They can be processed into functional photonic devices through customized laser writing, providing great flexibility for fabrication and reconfiguration. Lithium Niobate (LN) has excellent nonlinear and electro-optical properties, but is difficult to process, which limits its application in nanophotonic devices. In this paper, we combine the emerging low-loss phase change material Sb2S3 with LN and propose a new type of high Q resonant metasurface. Simulation results show that the Sb2S3-LN metasurface has extremely narrow linewidth of 0.096 nm and high quality (Q) factor of 15,964. With LN as the waveguide layer, strong nonlinear properties are observed in the hybrid metasurface, which can be employed for optical switches and isolators. By adding a pair of Au electrodes on both sides of the LN, we can realize dynamic electro-optical control of the resonant metasurface. The ultra-low loss of Sb2S3, and its combination with LN, makes it possible to realize a new family of high Q resonant metasurfaces for actively tunable nanophotonic devices with widespread applications including optical switching, light modulation, dynamic beam steering, optical phased array and so on.

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