Frozen Mode in an Asymmetric Serpentine Optical Waveguide

Albert Herrero-Parareda; Ilya Vitebskiy; Jacob Scheuer; Filippo Capolino

doi:10.1002/adpr.202100377

Frozen Mode in an Asymmetric Serpentine Optical Waveguide

Albert Herrero-Parareda, Ilya Vitebskiy, Jacob Scheuer, Filippo Capolino

School of Electrical Engineering

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

Abstract

The existence of a frozen mode in a periodic serpentine waveguide with broken longitudinal symmetry is demonstrated numerically. The frozen mode is associated with a stationary inflection point (SIP) of the Bloch dispersion relation, where three Bloch eigenmodes collapse on each other, as it is an exceptional point of order three. The frozen mode regime is characterized by vanishing group velocity and enhanced field amplitude, which can be very attractive in various applications including dispersion engineering, lasers, and delay lines. Useful and simple design equations that lead to realization of the frozen mode by adjusting a few parameters are derived. The trend in group delay and quality factor with waveguide length that is peculiar of the frozen mode is shown. The symmetry conditions for the existence of exceptional points of degeneracy associated with the frozen mode are also discussed.

Original language	English
Article number	2100377
Number of pages	12
Journal	Advanced Photonics Research
Volume	3
Issue number	9
DOIs	https://doi.org/10.1002/adpr.202100377
State	Published - Sep 2022

Keywords

Frozen modes
Inflection points
Serpentine optical waveguides
Slow light
Stationary

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10.1002/adpr.202100377

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abstract = "The existence of a frozen mode in a periodic serpentine waveguide with broken longitudinal symmetry is demonstrated numerically. The frozen mode is associated with a stationary inflection point (SIP) of the Bloch dispersion relation, where three Bloch eigenmodes collapse on each other, as it is an exceptional point of order three. The frozen mode regime is characterized by vanishing group velocity and enhanced field amplitude, which can be very attractive in various applications including dispersion engineering, lasers, and delay lines. Useful and simple design equations that lead to realization of the frozen mode by adjusting a few parameters are derived. The trend in group delay and quality factor with waveguide length that is peculiar of the frozen mode is shown. The symmetry conditions for the existence of exceptional points of degeneracy associated with the frozen mode are also discussed.",

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AU - Scheuer, Jacob

AU - Capolino, Filippo

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N2 - The existence of a frozen mode in a periodic serpentine waveguide with broken longitudinal symmetry is demonstrated numerically. The frozen mode is associated with a stationary inflection point (SIP) of the Bloch dispersion relation, where three Bloch eigenmodes collapse on each other, as it is an exceptional point of order three. The frozen mode regime is characterized by vanishing group velocity and enhanced field amplitude, which can be very attractive in various applications including dispersion engineering, lasers, and delay lines. Useful and simple design equations that lead to realization of the frozen mode by adjusting a few parameters are derived. The trend in group delay and quality factor with waveguide length that is peculiar of the frozen mode is shown. The symmetry conditions for the existence of exceptional points of degeneracy associated with the frozen mode are also discussed.

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Frozen Mode in an Asymmetric Serpentine Optical Waveguide

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