Large scale inverse design of planar on-chip mode sorter

Giuseppe Di Domenico; Dror  Weisman; A. Panichella; Dolev  Roitman; Ady Arie

doi:10.1021/acsphotonics.1c01539

Large scale inverse design of planar on-chip mode sorter

Giuseppe Di Domenico, Dror Weisman , A. Panichella, Dolev Roitman , Ady Arie

Software Engineering

Research output: Contribution to journal › Article › Scientific › peer-review

11 Citations (Scopus)

42 Downloads (Pure)

Abstract

Spatial modes of light can be used as carriers of information in classical optical communication or as an alphabet in quantum optical communication. In order to exploit the spatial domain, it is required to (de)multiplex different modes from a shared input channel into different output ports. Mode sorters have been employed in free-space and fiber systems but to date have not been realized for planar guided waves. Here we present a general method for compact on-chip sorting of different planar beams with a micrometric footprint and nanometric thickness. The designs were generated using a linkage-tree-based genetic algorithm and were experimentally demonstrated on a surface plasmon polariton platform by sorting of Hermite-Gaussian beams. The method used here can be readily applied to optimize complex, large-scale optical devices involving beam propagation methods.

Original language	English
Pages (from-to)	378-382
Number of pages	5
Journal	ACS Photonics
Volume	9
Issue number	2
DOIs	https://doi.org/10.1021/acsphotonics.1c01539
Publication status	Published - 2022

Keywords

integrated photonics
mode (de)multiplexing
dielectric metasurface
genetic algorithms
machine learning
subwavelength grating

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10.1021/acsphotonics.1c01539

acsphotonics.1c01539Final published version, 4.73 MBLicence: CC BY

Cite this

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title = "Large scale inverse design of planar on-chip mode sorter",

abstract = "Spatial modes of light can be used as carriers of information in classical optical communication or as an alphabet in quantum optical communication. In order to exploit the spatial domain, it is required to (de)multiplex different modes from a shared input channel into different output ports. Mode sorters have been employed in free-space and fiber systems but to date have not been realized for planar guided waves. Here we present a general method for compact on-chip sorting of different planar beams with a micrometric footprint and nanometric thickness. The designs were generated using a linkage-tree-based genetic algorithm and were experimentally demonstrated on a surface plasmon polariton platform by sorting of Hermite-Gaussian beams. The method used here can be readily applied to optimize complex, large-scale optical devices involving beam propagation methods.",

keywords = "integrated photonics, mode (de)multiplexing, dielectric metasurface, genetic algorithms, machine learning, subwavelength grating",

author = "{Di Domenico}, Giuseppe and Dror Weisman and A. Panichella and Dolev Roitman and Ady Arie",

year = "2022",

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T1 - Large scale inverse design of planar on-chip mode sorter

AU - Di Domenico, Giuseppe

AU - Weisman , Dror

AU - Panichella, A.

AU - Roitman , Dolev

AU - Arie , Ady

PY - 2022

Y1 - 2022

N2 - Spatial modes of light can be used as carriers of information in classical optical communication or as an alphabet in quantum optical communication. In order to exploit the spatial domain, it is required to (de)multiplex different modes from a shared input channel into different output ports. Mode sorters have been employed in free-space and fiber systems but to date have not been realized for planar guided waves. Here we present a general method for compact on-chip sorting of different planar beams with a micrometric footprint and nanometric thickness. The designs were generated using a linkage-tree-based genetic algorithm and were experimentally demonstrated on a surface plasmon polariton platform by sorting of Hermite-Gaussian beams. The method used here can be readily applied to optimize complex, large-scale optical devices involving beam propagation methods.

AB - Spatial modes of light can be used as carriers of information in classical optical communication or as an alphabet in quantum optical communication. In order to exploit the spatial domain, it is required to (de)multiplex different modes from a shared input channel into different output ports. Mode sorters have been employed in free-space and fiber systems but to date have not been realized for planar guided waves. Here we present a general method for compact on-chip sorting of different planar beams with a micrometric footprint and nanometric thickness. The designs were generated using a linkage-tree-based genetic algorithm and were experimentally demonstrated on a surface plasmon polariton platform by sorting of Hermite-Gaussian beams. The method used here can be readily applied to optimize complex, large-scale optical devices involving beam propagation methods.

KW - integrated photonics

KW - mode (de)multiplexing

KW - dielectric metasurface

KW - genetic algorithms

KW - machine learning

KW - subwavelength grating

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Large scale inverse design of planar on-chip mode sorter

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Planar on-Chip Mode Sorter

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Large scale inverse design of planar on-chip mode sorter

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