量子点
激发
物理
光子学
相干控制
极化(电化学)
光电子学
束缚态
半导体
自发辐射
量子
泄漏(经济)
光谱学
受激发射
辐射传输
光学物理学
荧光
光抽运
安德森本地化
工作(物理)
量子点激光器
原子系统
连贯性(哲学赌博策略)
纳米技术
放大器
光放大器
量子传感器
塞尔效应
等离子体子
材料科学
作者
Leyang Liu,Seemesh Bhaskar,Narendra Reddy,Brian T. Cunningham
出处
期刊:ACS Nano
[American Chemical Society]
日期:2026-03-18
卷期号:20 (12): 10223-10235
标识
DOI:10.1021/acsnano.6c01584
摘要
Fluorescence enhancement lies at the heart of many optical biosensing and diagnostic technologies, yet most photonic approaches still rely on intrinsically bright emitters or fabrication-intensive nanoresonators. Here, we introduce an unconventional strategy that turns a nominally "weak" photonic mode into a powerful resource. Through simple, frugal interface engineering, we show that leaky guided-mode resonances (GMRs), often regarded as optical loss channels, can be harnessed to amplify the excitation of two orthogonally polarized bound states in the continuum (BICs) within a one-dimensional photonic crystal. This synergistic interaction enables deterministic control of quantum dot (QD) photoluminescence, yielding wavelength-specific emission enhancement up to 691× for semiconductor QDs and 206× for biomass-derived carbon QDs, while achieving degrees of polarization up to 96% and angular divergences as small as 1.3°. Angle-resolved spectroscopy and back-focal-plane imaging, corroborated by time-resolved fluorescence decay analysis, reveal the mechanistic interplay between GMR-assisted excitation and BIC-mediated radiative extraction. By reimagining leaky modes as excitation amplifiers rather than parasitic losses, this work establishes a physically transparent, sustainable, and scalable route to polarization-encoded on-chip light sources and fluorescence-based diagnostic technologies.
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