High-efficiency thermo-optic switch based on waveguide superlattices with artificial gauge field

Xuelin Zhang; Jiangbing Du; Jian Li; Yihang Li; Wenjia Zhang; Ke Xu; Zuyuan He

doi:10.1364/OE.564059

High-efficiency thermo-optic switch based on waveguide superlattices with artificial gauge field

Xuelin Zhang
, Jiangbing Du^*
, Jian Li
, Yihang Li
, Wenjia Zhang
, Ke Xu
, Zuyuan He

^*Corresponding author for this work

Shanghai Jiao Tong University
Peng Cheng Laboratory
Harbin Institute of Technology Shenzhen

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

1 Scopus citations

Abstract

Optical switches are crucial components in integrated optics, with broad applications in data communications, sensing, and computing. We experimentally demonstrate an ultra-efficient silicon thermo-optic Mach-Zehnder switch based on waveguide superlattices with artificial gauge field. A sinusoidal modulation profile is typically applied to a binary waveguide array to achieve low-crosstalk and broadband light transmission. This design achieves the lowest power consumption of 1.21 mW without extra thermal isolation. Geometric design optimization, central to this demonstration, can be utilized to develop compact and high-efficiency devices for large-scale photonic integrated circuits. This approach paves the way for significantly reducing power consumption while maintaining scalability.

Original language	English
Pages (from-to)	33093-33100
Number of pages	8
Journal	Optics Express
Volume	33
Issue number	16
DOIs	https://doi.org/10.1364/OE.564059
State	Published - 11 Aug 2025
Externally published	Yes

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title = "High-efficiency thermo-optic switch based on waveguide superlattices with artificial gauge field",

abstract = "Optical switches are crucial components in integrated optics, with broad applications in data communications, sensing, and computing. We experimentally demonstrate an ultra-efficient silicon thermo-optic Mach-Zehnder switch based on waveguide superlattices with artificial gauge field. A sinusoidal modulation profile is typically applied to a binary waveguide array to achieve low-crosstalk and broadband light transmission. This design achieves the lowest power consumption of 1.21 mW without extra thermal isolation. Geometric design optimization, central to this demonstration, can be utilized to develop compact and high-efficiency devices for large-scale photonic integrated circuits. This approach paves the way for significantly reducing power consumption while maintaining scalability.",

author = "Xuelin Zhang and Jiangbing Du and Jian Li and Yihang Li and Wenjia Zhang and Ke Xu and Zuyuan He",

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AU - Zhang, Xuelin

AU - Du, Jiangbing

AU - Li, Jian

AU - Li, Yihang

AU - Zhang, Wenjia

AU - Xu, Ke

AU - He, Zuyuan

PY - 2025/8/11

Y1 - 2025/8/11

N2 - Optical switches are crucial components in integrated optics, with broad applications in data communications, sensing, and computing. We experimentally demonstrate an ultra-efficient silicon thermo-optic Mach-Zehnder switch based on waveguide superlattices with artificial gauge field. A sinusoidal modulation profile is typically applied to a binary waveguide array to achieve low-crosstalk and broadband light transmission. This design achieves the lowest power consumption of 1.21 mW without extra thermal isolation. Geometric design optimization, central to this demonstration, can be utilized to develop compact and high-efficiency devices for large-scale photonic integrated circuits. This approach paves the way for significantly reducing power consumption while maintaining scalability.

AB - Optical switches are crucial components in integrated optics, with broad applications in data communications, sensing, and computing. We experimentally demonstrate an ultra-efficient silicon thermo-optic Mach-Zehnder switch based on waveguide superlattices with artificial gauge field. A sinusoidal modulation profile is typically applied to a binary waveguide array to achieve low-crosstalk and broadband light transmission. This design achieves the lowest power consumption of 1.21 mW without extra thermal isolation. Geometric design optimization, central to this demonstration, can be utilized to develop compact and high-efficiency devices for large-scale photonic integrated circuits. This approach paves the way for significantly reducing power consumption while maintaining scalability.

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JO - Optics Express

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ER -

High-efficiency thermo-optic switch based on waveguide superlattices with artificial gauge field

Abstract

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