光电子学
光子学
材料科学
制作
栅栏
波导管
带宽(计算)
非线性光学
非线性光学
光学
衍射光栅
传输(电信)
辐射传输
光学材料
光开关
非线性系统
光子集成电路
纳米技术
半导体
波长
光学滤波器
导模共振
辐射能
光通信
集成光学
超材料
有机半导体
微结构光纤
折射率
能量转移
纳米光子学
作者
Do Wan Kim,Seokho Kim,Jin-Ho Choi,Jae-Hyun Lee,Yongmin Baek,Kyusang Lee,Dong-Hyuk Park,Jongchan Kim
摘要
As the demand for high bandwidth and long-distance data transmission escalates in modern computing, optical interconnects via waveguides have attracted significant attention. While conventional inorganic materials-based waveguide necessitates complex components such as grating couplers and optical amplifiers, organic semiconductor-based waveguides offer simplified systems with unique functionalities stemming from their inherent radiative properties that facilitate efficient light–matter interactions, such as exciton–polariton formation and Förster resonance energy transfer. These interactions enable active light modulation, encompassing intensity control, wavelength shift, exciton–polariton lasing, and nonlinear optical effects. Moreover, their optical properties and structural geometries can be precisely tuned through molecular design and controlled synthesis techniques. As a result, organic waveguides have been explored for a range of applications including optical-logic operations, bio-chemical sensing, and advanced photonic integration systems. In this review, we delineate the fundamental principles of organic semiconductor waveguides, as well as their fabrication and potential impact on various photonic applications.
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