V. Astratov, S. Ashili, A. M. Kapitonov, A. Kanaev
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引用次数: 0
摘要
本文致力于高质量低语通道模式(WGMs)微球电路的理论建模、制造和高级光谱表征。对结果的讨论基于三种球腔间光学耦合机制:(i)相同腔内WGM之间的共振耦合,(ii)离散能量态(源球中激发的真正WGM)与接收腔中可诱导的具有畸变非圆形状的准WGM态连续体之间的Fano共振,以及(iii)光子纳米射流机制。对于相同腔体的情况,我们给出了数值模拟结果,证明了良好的阻抗匹配,以及传播脉冲的可调谐纳秒延迟。实验研究了具有可控腔间分离的尺寸不匹配双球的光学耦合,并证明了基于Fano共振机制的有效性。最后,我们在极长的荧光微球链中观察到光子纳米射流,每个球的传播损失小于1 dB
Integrated Circuits of Coupled Mircospheres for Optoelectronics Applications
The paper is devoted to theoretical modeling, fabrication, and advanced spectroscopic characterization of circuits of microspheres with high quality whispering gallery modes (WGMs). The discussion of results is based on three mechanisms of optical coupling between spherical cavities: (i) resonant coupling between WGMs in identical cavities, (ii) Fano resonance between a discrete energy state (true WGM excited in the source sphere) and a continuum of quasi-WGM states with distorted noncircular shape which can be induced in the receiving cavity, and (iii) photonic nanojet mechanism. For the case of identical cavities we present numerical modeling results demonstrating a good impedance matching, and a tunable nanosecond delay for propagating pulses. We experimentally studied optical coupling in size-mismatched bispheres with controllable inter-cavity separations, and showed the validity of mechanism based on Fano resonance. Finally, we observed photonic nanojets in extremely long chains of fluorescent microspheres with propagation losses less than 1 dB per sphere
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