Optimized wide-angle metamaterial bandpass filters with multi-layer design and 1D photonic crystal integration

Baidong Wu; Liyang Yue; Zengbo (James ) Wang

doi:10.1016/j.optcom.2025.132185

Optimized wide-angle metamaterial bandpass filters with multi-layer design and 1D photonic crystal integration

School of Computer Science & Engineering

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

Abstract

We present a wide-angle, incident-insensitive metamaterial bandpass filter integrating gold-coated silicon nanospheres (SiNS) with a 1D photonic crystal (1D-PC) edge filter. This hybrid design leverages localized surface plasmon resonance (LSPR) and photonic bandgap engineering to achieve high optical density (OD ≈ 2.31) in stopbands while maintaining strong passband transmission (peak T≈ 80%). Unlike conventional thin-film filters, it minimizes blue-shift effects and ensures angle- stable performance up to 60◦ incidence. These results demonstrate a promising approach for high-performance optical filters in imaging, sensing, and laser protection applications.

Original language	English
Article number	132185
Journal	Optics Communications
Volume	591
Early online date	1 Jul 2025
DOIs	https://doi.org/10.1016/j.optcom.2025.132185
Publication status	Published - 1 Oct 2025

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title = "Optimized wide-angle metamaterial bandpass filters with multi-layer design and 1D photonic crystal integration",

abstract = "We present a wide-angle, incident-insensitive metamaterial bandpass filter integrating gold-coated silicon nanospheres (SiNS) with a 1D photonic crystal (1D-PC) edge filter. This hybrid design leverages localized surface plasmon resonance (LSPR) and photonic bandgap engineering to achieve high optical density (OD ≈ 2.31) in stopbands while maintaining strong passband transmission (peak T≈ 80\%). Unlike conventional thin-film filters, it minimizes blue-shift effects and ensures angle- stable performance up to 60◦ incidence. These results demonstrate a promising approach for high-performance optical filters in imaging, sensing, and laser protection applications.",

author = "Baidong Wu and Liyang Yue and Wang, \{Zengbo (James )\}",

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doi = "10.1016/j.optcom.2025.132185",

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AU - Wu, Baidong

AU - Yue, Liyang

AU - Wang, Zengbo (James )

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Y1 - 2025/10/1

N2 - We present a wide-angle, incident-insensitive metamaterial bandpass filter integrating gold-coated silicon nanospheres (SiNS) with a 1D photonic crystal (1D-PC) edge filter. This hybrid design leverages localized surface plasmon resonance (LSPR) and photonic bandgap engineering to achieve high optical density (OD ≈ 2.31) in stopbands while maintaining strong passband transmission (peak T≈ 80%). Unlike conventional thin-film filters, it minimizes blue-shift effects and ensures angle- stable performance up to 60◦ incidence. These results demonstrate a promising approach for high-performance optical filters in imaging, sensing, and laser protection applications.

AB - We present a wide-angle, incident-insensitive metamaterial bandpass filter integrating gold-coated silicon nanospheres (SiNS) with a 1D photonic crystal (1D-PC) edge filter. This hybrid design leverages localized surface plasmon resonance (LSPR) and photonic bandgap engineering to achieve high optical density (OD ≈ 2.31) in stopbands while maintaining strong passband transmission (peak T≈ 80%). Unlike conventional thin-film filters, it minimizes blue-shift effects and ensures angle- stable performance up to 60◦ incidence. These results demonstrate a promising approach for high-performance optical filters in imaging, sensing, and laser protection applications.

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DO - 10.1016/j.optcom.2025.132185

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VL - 591

JO - Optics Communications

JF - Optics Communications

M1 - 132185

ER -

Optimized wide-angle metamaterial bandpass filters with multi-layer design and 1D photonic crystal integration

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