Topology Optimization of Chiral Phoxonic Crystals with Simultaneously Large Phononic and Photonic Bandgaps

Hao Wen Dong; Yue Sheng Wang; Chuanzeng Zhang

doi:10.1109/JPHOT.2017.2665700

Topology Optimization of Chiral Phoxonic Crystals with Simultaneously Large Phononic and Photonic Bandgaps

Hao Wen Dong, Yue Sheng Wang^*, Chuanzeng Zhang

^*Corresponding author for this work

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

29 Citations (Scopus)

Abstract

We study theoretically the simultaneous existence of large phononic and photonic bandgaps in chiral phoxonic crystals by topology optimization. By analyzing the effect of the chiral symmetry with different material orientations in both the square and triangular lattices, we discuss the most suitable structural properties for opening large phononic and photonic bandgap widths simultaneously and demonstrate the key role of the chiral topological feature. We also present the sensitivity analysis on the optimized phoxonic crystals and suggest the relatively robust structures. It will be shown that topology optimization can discover novel types of simple structures, offering new degrees of freedom to the beneficial design of phoxonic crystals for manipulating photons with phonons.

Original language	English
Article number	7847421
Journal	IEEE Photonics Journal
Volume	9
Issue number	2
DOIs	https://doi.org/10.1109/JPHOT.2017.2665700
Publication status	Published - Apr 2017
Externally published	Yes

Keywords

Photonic bandgap structures
photonic crystals
theory and design

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10.1109/JPHOT.2017.2665700

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title = "Topology Optimization of Chiral Phoxonic Crystals with Simultaneously Large Phononic and Photonic Bandgaps",

abstract = "We study theoretically the simultaneous existence of large phononic and photonic bandgaps in chiral phoxonic crystals by topology optimization. By analyzing the effect of the chiral symmetry with different material orientations in both the square and triangular lattices, we discuss the most suitable structural properties for opening large phononic and photonic bandgap widths simultaneously and demonstrate the key role of the chiral topological feature. We also present the sensitivity analysis on the optimized phoxonic crystals and suggest the relatively robust structures. It will be shown that topology optimization can discover novel types of simple structures, offering new degrees of freedom to the beneficial design of phoxonic crystals for manipulating photons with phonons.",

keywords = "Photonic bandgap structures, photonic crystals, theory and design",

author = "Dong, {Hao Wen} and Wang, {Yue Sheng} and Chuanzeng Zhang",

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year = "2017",

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AU - Dong, Hao Wen

AU - Wang, Yue Sheng

AU - Zhang, Chuanzeng

PY - 2017/4

Y1 - 2017/4

N2 - We study theoretically the simultaneous existence of large phononic and photonic bandgaps in chiral phoxonic crystals by topology optimization. By analyzing the effect of the chiral symmetry with different material orientations in both the square and triangular lattices, we discuss the most suitable structural properties for opening large phononic and photonic bandgap widths simultaneously and demonstrate the key role of the chiral topological feature. We also present the sensitivity analysis on the optimized phoxonic crystals and suggest the relatively robust structures. It will be shown that topology optimization can discover novel types of simple structures, offering new degrees of freedom to the beneficial design of phoxonic crystals for manipulating photons with phonons.

AB - We study theoretically the simultaneous existence of large phononic and photonic bandgaps in chiral phoxonic crystals by topology optimization. By analyzing the effect of the chiral symmetry with different material orientations in both the square and triangular lattices, we discuss the most suitable structural properties for opening large phononic and photonic bandgap widths simultaneously and demonstrate the key role of the chiral topological feature. We also present the sensitivity analysis on the optimized phoxonic crystals and suggest the relatively robust structures. It will be shown that topology optimization can discover novel types of simple structures, offering new degrees of freedom to the beneficial design of phoxonic crystals for manipulating photons with phonons.

KW - Photonic bandgap structures

KW - photonic crystals

KW - theory and design

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Topology Optimization of Chiral Phoxonic Crystals with Simultaneously Large Phononic and Photonic Bandgaps

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Keywords

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