Trilayered Gires–Tournois Resonator with Ultrasensitive Slow-Light Condition for Colorimetric Detection of Bioparticles

Kang, Jiwon; Yoo, Young Jin; Ko, Joo Hwan; Mahmud, Abdullah Al; Song, Young Min

doi:10.3390/nano13020319

Cited by 5 publications

(3 citation statements)

References 47 publications

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“…Various 3D flexible photodetectors were fabricated by the use of mechanically-guided assembly methods. ,, For example, as shown in Figure c, photodetectors in the forms of 3D domes exhibited unique structural superiorities, featuring the simultaneous measurement of both light intensity and incident angles . Specifically, given the spatially distributed photoresponsive MoS 2 films, an incident light could illuminate different MoS 2 films from both the entry and exit sites, thereby resulting in increased photocurrents in the corresponding regions.…”

Section: Applicationsmentioning

confidence: 99%

Mechanically-Guided 3D Assembly for Architected Flexible Electronics

Bo,

Xu,

Yang

et al. 2023

Chem. Rev.

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Architected flexible electronic devices with rationally designed 3D geometries have found essential applications in biology, medicine, therapeutics, sensing/imaging, energy, robotics, and daily healthcare. Mechanically-guided 3D assembly methods, exploiting mechanics principles of materials and structures to transform planar electronic devices fabricated using mature semiconductor techniques into 3D architected ones, are promising routes to such architected flexible electronic devices. Here, we comprehensively review mechanically-guided 3D assembly methods for architected flexible electronics. Mainstream methods of mechanically-guided 3D assembly are classified and discussed on the basis of their fundamental deformation modes (i.e., rolling, folding, curving, and buckling). Diverse 3D interconnects and device forms are then summarized, which correspond to the two key components of an architected flexible electronic device. Afterward, structure-induced functionalities are highlighted to provide guidelines for function-driven structural designs of flexible electronics, followed by a collective summary of their resulting applications. Finally, conclusions and outlooks are given, covering routes to achieve extreme deformations and dimensions, inverse design methods, and encapsulation strategies of architected 3D flexible electronics, as well as perspectives on future applications.

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Section: Applicationsmentioning

confidence: 99%

Mechanically-Guided 3D Assembly for Architected Flexible Electronics

Bo,

Xu,

Yang

et al. 2023

Chem. Rev.

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“…To address this, it is crucial to enhance the lightmatter interaction and introduce significant variations in light intensity (transmittance and/or reflectance) to improve the signalto-noise ratio. [36,37] In this regard, Fano resonance offers significant advantages in biosensing and imaging applications. This is primarily attributed to the fact that conventional intensity-based sensing methods often rely on substantial resonant peak shifts to achieve detectable changes in intensity at specific wavelengths.…”

Section: Enhanced Sensitivity Of Low-refractive Index Materialsmentioning

confidence: 99%

Full‐Control and Switching of Optical Fano Resonance by Continuum State Engineering

Ko,

Park,

Yoo

et al. 2023

Advanced Science

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Fano resonance, known for its unique asymmetric line shape, has gained significant attention in photonics, particularly in sensing applications. However, it remains difficult to achieve controllable Fano parameters with a simple geometric structure. Here, a novel approach of using a thin‐film optical Fano resonator with a porous layer to generate entire spectral shapes from quasi‐Lorentzian to Lorentzian to Fano is proposed and experimentally demonstrated. The glancing angle deposition technique is utilized to create a polarization‐dependent Fano resonator. By altering the linear polarization between s‐ and p‐polarization, a switchable Fano device between quasi‐Lorentz state and negative Fano state is demonstrated. This change in spectral shape is advantageous for detecting materials with a low‐refractive index. A bio‐particle sensing experiment is conducted that demonstrates an enhanced signal‐to‐noise ratio and prediction accuracy. Finally, the challenge of optimizing the film‐based Fano resonator due to intricate interplay among numerous parameters, including layer thicknesses, porosity, and materials selection, is addressed. The inverse design tool is developed based on a multilayer perceptron model that allows fast computation for all ranges of Fano parameters. The method provides improved accuracy of the mean validation factor (MVF = 0.07, q‐q') compared to the conventional exhaustive enumeration method (MVF = 0.37).

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“…Monitoring changes in environments with gases at high pressure or containing organic vapors requires a wide dynamic range to cover their highvalue refractive indices compared to the refractive index of air [15,18]. These different situations must be taken into account in the sensor design, while the characteristics of the plasmonic resonance is spatially (long-and short-range SPRs) and spectrally (narrow and wide) controlled [19,20]. Long-range spatial decay with an ultra-narrow spectral feature can sense variations with a high resolution [21][22][23].…”

Section: Introductionmentioning

confidence: 99%

Optical Sensing Using Hybrid Multilayer Grating Metasurfaces with Customized Spectral Response

Elshorbagy,

Cuadrado,

Alda

2024

Sensors

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Customized metasurfaces allow for controlling optical responses in photonic and optoelectronic devices over a broad band. For sensing applications, the spectral response of an optical device can be narrowed to a few nanometers, which enhances its capabilities to detect environmental changes that shift the spectral transmission or reflection. These nanophotonic elements are key for the new generation of plasmonic optical sensors with custom responses and custom modes of operation. In our design, the metallic top electrode of a hydrogenated amorphous silicon thin-film solar cell is combined with a metasurface fabricated as a hybrid dielectric multilayer grating. This arrangement generates a plasmonic resonance on top of the active layer of the cell, which enhances the optoelectronic response of the system over a very narrow spectral band. Then, the solar cell becomes a sensor with a response that is highly dependent on the optical properties of the medium on top of it. The maximum sensitivity and figure of merit (FOM) are SB = 36,707 (mA/W)/RIU and ≈167 RIU−1, respectively, for the 560 nm wavelength using TE polarization. The optical response and the high sensing performance of this device make it suitable for detecting very tiny changes in gas media. This is of great importance for monitoring air quality and thecomposition of gases in closed atmospheres.

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Trilayered Gires–Tournois Resonator with Ultrasensitive Slow-Light Condition for Colorimetric Detection of Bioparticles

Cited by 5 publications

References 47 publications

Mechanically-Guided 3D Assembly for Architected Flexible Electronics

Mechanically-Guided 3D Assembly for Architected Flexible Electronics

Full‐Control and Switching of Optical Fano Resonance by Continuum State Engineering

Optical Sensing Using Hybrid Multilayer Grating Metasurfaces with Customized Spectral Response

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