采用交叉耦合结构技术的新型交叉耦合谐振器在双微环谐振器中诱导移位吸收

IF 1.2 4区 物理与天体物理 Q4 OPTICS
B. Dingel, Bo Ye
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引用次数: 2

摘要

据我们所知,我们首次报道了一种在级联微环谐振器(mrr)中采用“交叉耦合结构”的技术,以带来量子相干现象的新光学类似物。新的配置类似于标准的双谐振器(SDR),但使用基于交叉耦合的定向耦合器(dc),而不是典型的基于直接耦合的定向耦合器。它的一个独特之处是没有典型的SDR的标志性量子相干模拟效应,如耦合谐振腔诱导透明(CRIT)或耦合谐振腔诱导吸收(CRIA)。相反,它在单通相移θ =−π/2处产生了一个新的非常窄的反射倾角,我们称之为交叉耦合谐振器诱导位移吸收(CRISA)。我们将CRISA的特征与SDR中发现的CRIT、CRIA和Autler-Townes分裂(ATS)进行了广泛的比较。该技术开辟了具有更丰富光学行为的新配置,可以找到潜在的尚未开发的应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
New cross-coupled resonator induced shifted absorption (CRISA) in double microring resonators using a cross-coupling-structure technique
We report, for the first time to the best of our knowledge, a technique that employs ′cross-coupling structure’ in the cascaded microring resonators (MRRs) to bring new optical analogues of quantum coherence phenomena. The new configuration resembles a standard double resonator (SDR) but uses cross-coupled–based directional couplers (DCs) instead of the typical direct-coupled–based DCs. One of its unique features is that it does not exhibit the typical SDR’s signature quantum coherence analogue effects like coupled-resonator induced transparency (CRIT) or coupled-resonator induced absorption (CRIA). On the contrary, it produces a new very narrow reflection dip positioned at single-pass phase shift θ = − π/2 which we refer to as cross-coupled resonator induced shifted absorption (CRISA). We compare extensively CRISA’s characteristics with the CRIT, CRIA, and Autler-Townes splitting (ATS) found in SDR. The technique opens up new configurations with richer optical behaviours that could find potentially still unexplored applications.
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来源期刊
Journal of Modern Optics
Journal of Modern Optics 物理-光学
CiteScore
2.90
自引率
0.00%
发文量
90
审稿时长
2.6 months
期刊介绍: The journal (under its former title Optica Acta) was founded in 1953 - some years before the advent of the laser - as an international journal of optics. Since then optical research has changed greatly; fresh areas of inquiry have been explored, different techniques have been employed and the range of application has greatly increased. The journal has continued to reflect these advances as part of its steadily widening scope. Journal of Modern Optics aims to publish original and timely contributions to optical knowledge from educational institutions, government establishments and industrial R&D groups world-wide. The whole field of classical and quantum optics is covered. Papers may deal with the applications of fundamentals of modern optics, considering both experimental and theoretical aspects of contemporary research. In addition to regular papers, there are topical and tutorial reviews, and special issues on highlighted areas. All manuscript submissions are subject to initial appraisal by the Editor, and, if found suitable for further consideration, to peer review by independent, anonymous expert referees. General topics covered include: • Optical and photonic materials (inc. metamaterials) • Plasmonics and nanophotonics • Quantum optics (inc. quantum information) • Optical instrumentation and technology (inc. detectors, metrology, sensors, lasers) • Coherence, propagation, polarization and manipulation (classical optics) • Scattering and holography (diffractive optics) • Optical fibres and optical communications (inc. integrated optics, amplifiers) • Vision science and applications • Medical and biomedical optics • Nonlinear and ultrafast optics (inc. harmonic generation, multiphoton spectroscopy) • Imaging and Image processing
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