Slow light in mass-produced, dispersion-engineered photonic crystal ring resonators

McGarvey-Lechable, Kathleen; Hamidfar, Tabassom; Patel, David; Xu, Luhua; Plant, David V.; Bianucci, Pablo

doi:10.1364/oe.25.003916

Cited by 29 publications

(12 citation statements)

References 25 publications

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“…10(b). It can be seen that all the resonant modes show an even number of nodes in the mode profiles, which is due to the beating of two wave vectors [27], [28]. It should be noted that there are two resonant modes (C and D) possessing four nodes in the mode profiles.…”

Section: Refractive Index Sensingmentioning

confidence: 91%

Air-Mode Photonic Crystal Micro-Ring Resonator With Enhanced Quality Factor for Refractive Index Sensing

Kong

2020

IEEE Photonics J.

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Intense light-matter interaction is critical for enabling high-sensitivity refractive index sensors, high-efficiency light sources, and high-performance nonlinear devices. A bowtie-hole photonic crystal micro-ring resonator is proposed and numerically demonstrated to enhance the light-matter interaction effectively through achieving strong spatial and temporal light confinement, simultaneously. Through engineering the photonic crystal unit cell, the bowtie-hole photonic crystal is proved to possess the ability to localize light with a highly tight spatial confinement. By optimizing the bowtie-hole radius and the bowtie angle, the Q factor of the air mode in the resonator is improved to 1.42 × 10 5 , which denotes an excellent temporal confinement. With the advantages addressed, the refractive index sensing based on the high-Q air mode in the bowtie-hole photonic crystal micro-ring resonator is investigated. For the air mode in the bowtie-hole photonic crystal micro-ring resonator, the Q factor is comparable with that in the reported research, meanwhile the sensing sensitivity has a 2-fold enhancement.

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Section: Refractive Index Sensingmentioning

confidence: 91%

Air-Mode Photonic Crystal Micro-Ring Resonator With Enhanced Quality Factor for Refractive Index Sensing

Kong

2020

IEEE Photonics J.

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“…Here, the mesh accuracy in the 3D-FDTD simulation is chosen as 4, which is a good trade-off between accuracy, memory requirements and Figure 2a shows the 3D-FDTD transmission spectrum of the proposed NSMR device with the wavelength changes from 1500 to 1600 nm. Non-uniform free-spectral range (FSR) between adjacent resonances is affected by a slow-light effect [37][38][39][40]. The Q-factor of these cavities can be defined as 1/Q = P/(ω 0 U), where P is the outgoing energy, U is the electromagnetic energy localized in the cavity, ω 0 is the frequency of light around the cavity [41].…”

Section: Nanoslotted Microring Resonator Designmentioning

confidence: 99%

Nanoslotted microring resonator for high figure of merit refractive index sensing

Yang¹,

Duan²,

Zhang³

et al. 2020

Optica Applicata

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A nanoslotted microring resonator (NSMR) with enhanced light-matter interaction has been designed, which can be used for high sensitive refractive index sensing. The performance of the device is investigated theoretically based on a three-dimensional finite-difference time-domain (3D-FDTD) method. In order to achieve high figure of merit sensing, the nanoslot geometry is exploited to make the optical field strongly localized inside the low index region and overlap sufficiently with the analytes. By using the 3D-FDTD method, the proposed NSMR sensor device achieves a high Q-factor (Q > 105) and sensitivity ~100 nm/RIU (RIU – refractive index unit). Moreover, the strong light confinement introduced by the nanoslot in NSMR results in the sensor figure of merit as high as 6.73 × 103. Thus, the design we proposed is a promising platform for refractive index-based biochemical sensing and lab-on-a-chip applications.

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“…In this work, a PhC microring resonator (PhCR) [18][19][20][21] is demonstrated as a label-free biosensor for specific molecular detection with enhanced detection sensitivity due to its strong light-matter interaction that results from the localized optical mode field profiles of the PhC structure. Since a fraction of the optical field in the PhCR is located inside the air holes that are accessible for molecular attachment, the PhCR can detect the presence of analyte both inside the holes and on the top surface.…”

Section: Introductionmentioning

confidence: 99%

“…Since a fraction of the optical field in the PhCR is located inside the air holes that are accessible for molecular attachment, the PhCR can detect the presence of analyte both inside the holes and on the top surface. Importantly, in contrast to slots and multi-hole defects that also support increased light-matter interaction for sensing, the critical dimensions of PhCRs are compatible with advanced deep ultra-violet (DUV) lithography [21,22], which could lead to the production of high-volume, low-cost lab-on-a-chip biosensors. Moreover, all of the important properties of conventional microring resonators as biosensors are preserved for PhCRs while a significant challenge for sensing high concentrations of molecules is removed.…”

Section: Introductionmentioning

confidence: 99%

Photonic crystal microring resonator for label-free biosensing

Lo¹,

Hu²,

Gaur³

et al. 2017

Opt. Express

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A label-free optical biosensor based on a one-dimensional photonic crystal microring resonator with enhanced light-matter interaction is demonstrated. More than a 2-fold improvement in volumetric and surface sensing sensitivity is achieved compared to conventional microring sensors. The experimental bulk detection sensitivity is ~248nm/RIU and label-free detection of DNA and proteins is reported at the nanomolar scale. With a minimum feature size greater than 100nm, the photonic crystal microring resonator biosensor can be fabricated with the same standard lithographic techniques used to mass fabricate conventional microring resonators.

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Slow light in mass-produced, dispersion-engineered photonic crystal ring resonators

Cited by 29 publications

References 25 publications

Air-Mode Photonic Crystal Micro-Ring Resonator With Enhanced Quality Factor for Refractive Index Sensing

Air-Mode Photonic Crystal Micro-Ring Resonator With Enhanced Quality Factor for Refractive Index Sensing

Nanoslotted microring resonator for high figure of merit refractive index sensing

Photonic crystal microring resonator for label-free biosensing

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