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Optimized Wide-Angle Metamaterial Edge Filters: Enhanced Performance with Multi-Layer Designs and Anti-Reflection Coatings. / Wu, Baidong; Monks, James N.; Yue, Liyang et al.
Yn: Photonics, Cyfrol 11, Rhif 5, 446, 10.05.2025.

Allbwn ymchwil: Cyfraniad at gyfnodolynErthygladolygiad gan gymheiriaid

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Wu B, Monks JN, Yue L, Hurst A, Wang Z. Optimized Wide-Angle Metamaterial Edge Filters: Enhanced Performance with Multi-Layer Designs and Anti-Reflection Coatings. Photonics. 2025 Mai 10;11(5):446. Epub 2024 Mai 10. doi: 10.3390/photonics11050446

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TY - JOUR

T1 - Optimized Wide-Angle Metamaterial Edge Filters: Enhanced Performance with Multi-Layer Designs and Anti-Reflection Coatings

AU - Wu, Baidong

AU - Monks, James N.

AU - Yue, Liyang

AU - Hurst, Andrew

AU - Wang, Zengbo (James )

PY - 2024/5/10

Y1 - 2024/5/10

N2 - This study presents a systematic optimization of wide-angle metamaterial long-pass (LP) edge filters based on silicon nanospheres (SiNP). Multi-layered configurations incorporating SiNP-meta-films and anti-reflection coating (ARC) elements not previously considered in the literature are explored to enhance their filter performance in both stop and pass bands. This research has successfully developed an accurate model for the effective refractive index using Kramers–Kronig relations, enabling the use of classical thin-film design software for rapid device performance optimization, which is verified by full-wave numerical software. This systematic optimization has produced highly efficient, near-shift-free long-pass metamaterial filters, evidenced by their high optical density (OD = 2.55) and low spectral shift across a wide angular range (0°–60°). These advancements herald the development of high-efficiency metamaterial optical components suitable for a variety of applications that require a consistent performance across diverse angles of incidence.

AB - This study presents a systematic optimization of wide-angle metamaterial long-pass (LP) edge filters based on silicon nanospheres (SiNP). Multi-layered configurations incorporating SiNP-meta-films and anti-reflection coating (ARC) elements not previously considered in the literature are explored to enhance their filter performance in both stop and pass bands. This research has successfully developed an accurate model for the effective refractive index using Kramers–Kronig relations, enabling the use of classical thin-film design software for rapid device performance optimization, which is verified by full-wave numerical software. This systematic optimization has produced highly efficient, near-shift-free long-pass metamaterial filters, evidenced by their high optical density (OD = 2.55) and low spectral shift across a wide angular range (0°–60°). These advancements herald the development of high-efficiency metamaterial optical components suitable for a variety of applications that require a consistent performance across diverse angles of incidence.

KW - edge filters

KW - hybrid design optimization

KW - metamaterial filters

KW - wide-angle filters

U2 - 10.3390/photonics11050446

DO - 10.3390/photonics11050446

M3 - Article

VL - 11

JO - Photonics

JF - Photonics

SN - 2304-6732

IS - 5

M1 - 446

ER -