Analysis of Giant Reflectance Tuning Enabled by Unidirectional Guided Resonance With Embedded Absorber

Analysis of Giant Reflectance Tuning Enabled by Unidirectional Guided Resonance With Embedded Absorber

Achieving giant reflectance tuning is essential for various applications, including optical communication, switching, processing, and sensing. While optical resonances effectively enhance light-matter interactions, their inherent dispersive nature limits the maximum achievable reflectance tunability...

Full description

Saved in:
Bibliographic Details
Main Authors: Yuefeng Hu, Zixuan Zhang, Chenxingyu Huang, Qian Li, H. Y. Fu, Chao Peng
Format: Article
Language:English
Published: IEEE 2025-01-01
Series:IEEE Photonics Journal
Subjects:
Giant reflectance tuning
unidirectional guided resonances (UGRs)
embedded absorber
epsilon-near-zero (ENZ)
Online Access:https://ieeexplore.ieee.org/document/11091360/
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:Achieving giant reflectance tuning is essential for various applications, including optical communication, switching, processing, and sensing. While optical resonances effectively enhance light-matter interactions, their inherent dispersive nature limits the maximum achievable reflectance tunability at the resonant frequency. To overcome this challenge, we propose utilizing unidirectional guided resonances (UGRs) to deterministically close leaky channels, thereby concentrating energy flow in the desired direction. Through systematic analysis, we compare the reflectance response of UGRs with conventional guided resonances incorporating embedded absorbers, demonstrating that reflectance tunability can theoretically approach unity under ideal conditions. Furthermore, we introduce a realistic design incorporating electrically controlled indium tin oxide (ITO) with the epsilon-near-zero (ENZ) effect as an embedded absorber. Despite the absorbing layer being thinner than <inline-formula><tex-math notation="LaTeX">$1\,\text{nm}$</tex-math></inline-formula>, the theory and simulation show that our design can support a reflectance tunability of 0.76 under a driving voltage of <inline-formula><tex-math notation="LaTeX">$3\,\text{V}$</tex-math></inline-formula>. This approach presents a promising strategy for expanding the range of reflectance variations, enabling advancements in optical communication, computing, and beyond.
ISSN:1943-0655

Similar Items