May 24, 2023 |
(Nanowerk News) Recent technological advances have given us a remarkable ability to manipulate and control light waves, opening up numerous applications in various fields, such as optical communication, sensing, imaging, energy, and quantum computing. At the heart of this progress are photonic structures that can control light waves, either at the chip level in the form of photonic integrated circuits (PICs) or in free space as meta-optics. Combining these structures allows for the creation of compact optical systems. The PICs can be used to make subtle changes to the light wave, such as the manipulation of its phase and intensity to achieve a desired output, which can then be guided in free space by meta-optics. Such combined systems can control qubits for quantum computing and power light detection, as well as ranging systems like the ones used for autonomous vehicle navigation and mapping.
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Since PICs use nanometer-scale waveguides to confine and direct light, coupling their light to and from larger devices, such as optical fibers, is tricky. Grating couplers are commonly used for this purpose because of their grating structure that can diffract light going in or out of the PIC’s waveguides. However, these devices can only shape the light wave to a certain degree, limiting their applicability.
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In view of this shortcoming, meta-optics capable of manipulating optical wavefronts with arbitrary shapes have been suggested to couple light from PICs. Although this approach is promising, no multifunctional coupling between PIC and free space has yet been reported.
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A photonic integrated circuit guides input light received from an optical fiber to a separate meta-optics chip, which bends the light into desired shapes in free space. (© Advanced Photonics Nexus)
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Now, in a study published in Advanced Photonics Nexus (“Multifunctional interface between integrated photonics and free space”), researchers from the University of Washington, have demonstrated a chip-scale hybrid PIC/meta-optical platform consisting of a photonic integrated circuit with gratings below a separate meta-optics chip. The PIC comprises 16 identical gratings arranged in a two-dimensional array, each with an aperture size of 300 micrometers and coupled to an optical fiber with a grating coupler. These gratings serve as waveguides and direct light from the fiber to the meta-optics chip which shapes and outputs light to free space, parallel to the input light.
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“Using an array of low-loss meta-optics, we have developed a flexible and interchangeable interface between a photonic integrated circuit and free space,” says senior author Associate Professor Arka Majumdar from the University of Washington in Seattle.
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Using this platform, the researchers were able to simultaneously pass light through 14 PIC gratings and then shape the corresponding beam with 14 different meta-optics, such as meta-lenses, vortex beam generators, extended depth of focus lenses, and holograms.
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“Meta-optics has the ability to shape optical wavefronts to create a multifunctional interface between free-space optics and integrated photonics. This study exploits that. All the light beams that come out of the PIC are identical, but by placing different meta-optics on top of each grating, we were able to simultaneously manipulate the beams individually,” explains Majumdar.
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In their experiments with different meta-optics, the researchers found that the device operated with high accuracy and reliability, even without prior knowledge of the input light or the need for precise alignment between the two chips. Specifically, they achieved a diffraction limited spot of three micrometers and a holographic image with a peak signal-to-noise ratio greater than 10 decibels.
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The remarkable feature of the proposed device is its ability to change its functionality simply by replacing the meta-optics linked to the PIC. This allows for a wide range of possibilities for controlling and modifying light beams with a high degree of error tolerance. The potential applications of this interface are manifold, and include beam steering, structured light generation, optical trapping, and manipulation of cold atom qubits.
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