Self-induced transparency in a perfectly absorbing chiral second-harmonic generator

Hou, Jiankun; Lin, Jintian; Zhu, Jiefu; Zhao, Guolin; Chen, Yao; Zhang, Fangxing; Zheng, Yuanlin; Chen, Xianfeng; Cheng, Ya; Li, Ge; Wan, Wenjie

doi:10.1186/s43074-022-00068-y

Cited by 17 publications

(6 citation statements)

References 41 publications

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“…( 9 ) and ( 10 ) are similar with the temporal coupled-mode theory used in Refs. 43 , 44 . After solving these equations in the steady-state regime and considering the case of , we plot in Fig.…”

Section: Light Intensitymentioning

confidence: 99%

Light squeezing enhancement by coupling nonlinear optical cavities

Jabri,

Eleuch

2024

Sci Rep

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In this paper, we explore the squeezing effect generated by two coupled optical cavities. Each cavity contains a second-order nonlinear material and coherently pumped by a laser. Our results show that light intensity is strongly improved due to the presence of the nonlinearities and mainly depends on the detunings between external laser frequencies and cavity modes. More interestingly, the proposed scheme could enhance light squeezing for moderate coupling between cavities : the squeezing generated by one cavity is enhanced by the other one. For resonant interaction, highest squeezing effect is obtained near resonance. When fields are non resonant, squeezing increases near resonance of the considered cavity, but decreases for large detunings relative to the second cavity. Further, when the dissipation rate of the second cavity is smaller than the first, the squeezing could be improved, attaining nearly the perfect squeezing. While the temperature elevation has a negative impact overall on the nonclassical light, squeezing shows an appreciable resistance against thermal baths for appropriate parameter sets.

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Section: Light Intensitymentioning

confidence: 99%

Light squeezing enhancement by coupling nonlinear optical cavities

Jabri,

Eleuch

2024

Sci Rep

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“…In the early stage of implementing EPs, the optical gain and loss were integrated as non-conservative components in a simple one-dimensional transmission system to achieve Eps 18 , 19 , while the optical gain often leads to complex and unstable systems. EPs can also be observed by designing complex permittivity in all-passive systems, which inspires the study of EP-related phenomena 20 , for instance, the one-way cloaking 21 – 23 . However, one-dimensional transmission systems have limited capabilities in controlling lightwaves 24 – 28 .…”

Section: Introductionmentioning

confidence: 99%

Scattering exceptional point in the visible

He,

Zhang,

Zhu

et al. 2023

Light Sci Appl

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Exceptional point (EP) is a special degeneracy of non-Hermitian systems. One-dimensional transmission systems operating at EPs are widely studied and applied to chiral conversion and sensing. Lately, two-dimensional systems at EPs have been exploited for their exotic scattering features, yet so far been limited to only the non-visible waveband. Here, we report a universal paradigm for achieving a high-efficiency EP in the visible by leveraging interlayer loss to accurately control the interplay between the lossy structure and scattering lightwaves. A bilayer framework is demonstrated to reflect back the incident light from the left side ( | r−1 | >0.999) and absorb the incident light from the right side ( | r+1 | < 10–4). As a proof of concept, a bilayer metasurface is demonstrated to reflect and absorb the incident light with experimental efficiencies of 88% and 85%, respectively, at 532 nm. Our results open the way for a new class of nanoscale devices and power up new opportunities for EP physics.

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“…Due to the high quality ( Q ) factor and small mode volume, whispering-gallery-mode (WGM) optical microresonators provide a prominent platform for various applications, such as ultralow-threshold lasers, − highly sensitive sensors, − nonlinear optics, − and optomechanics. − Recently, there has been a great deal of interest in chiral optical states of WGM microresonators. In a WGM microresonator, light fields in the clockwise (CW) and counterclockwise (CCW) directions are coupled with each other due to the backscattering, which originates from the imperfections in the microresonator. , Generally, chiral optical states of WGM microresonators appear when the chiral symmetry of the CW and CCW light propagation is broken, which can be realized by asymmetrical scattering, − deformed resonators, − and spontaneous symmetry breaking based on optical nonlinearity. − Chiral optical states are important and can be used to manipulate the propagating direction of a light field, − which is crucial for the realization of novel functional devices, such as unidirectional lasers, ,, gyroscopes, , and single-nanoparticle sensors …”

Section: Introductionmentioning

confidence: 99%

Backscattering-Induced Chiral Absorption in Optical Microresonators

Ren,

Yuan,

Zhu

et al. 2023

ACS Photonics

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Chirality in micro- and nanophotonic structures is crucial for both fundamental research and applied technology. Here, we experimentally demonstrate chiral absorption via backscattering in a single whispering-gallery microresonator under simultaneous excitation from both ports. Remarkably, this scheme does not rely on any nonlinear effects or the breaking of parity or time-reversal symmetry. These intriguing phenomena occur due to the interference between the clockwise- and counterclockwise-propagating light fields induced by the backscattering. Furthermore, we also achieve the chiral optical states in a coupled-microresonator system, which can be utilized to manipulate the electromagnetically induced transparency or absorption effect. Our work proposes a linear and all-optical scheme to realize chiral optical states, which can help control the light flow in photonic systems with a high operation rate.

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Self-induced transparency in a perfectly absorbing chiral second-harmonic generator

Cited by 17 publications

References 41 publications

Light squeezing enhancement by coupling nonlinear optical cavities

Light squeezing enhancement by coupling nonlinear optical cavities

Scattering exceptional point in the visible

Backscattering-Induced Chiral Absorption in Optical Microresonators

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