Colorimetric and Near-Absolute Polarization-Insensitive Refractive-Index Sensing in All-Dielectric Guided-Mode Resonance Based Metasurface

Yıldırım, Deniz Umut; Ghobadi, Amir; Soydan, Mahmut Can; Gokbayrak, Murat; Toprak, Ahmet; Bütün, Bayram; Özbay, Ekmel

doi:10.1021/acs.jpcc.9b04748

Cited by 45 publications

(36 citation statements)

References 75 publications

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“…These devices are ideally designed to perfectly absorb and harvest light in a narrow or broad frequency range [8][9][10][11][12][13][14][15][16][17][18][19][20][21][22][23]. These perfect metamaterial absorbers have a wide range of applications including sensing [24][25][26], filtering [27,28], coherent emission [29][30][31][32], photovoltaics and thermal photovoltaics [33][34][35][36][37][38], photodetection [39][40][41], solar vapor generation [42], and photochemistry [43][44][45]. Among these applications, photochemistry and photoelectrochemical water splitting has become a promising technology to supply the future clean energy demand, and it is thought to be the "holy grail" of energy conversion and storage revolution.…”

Section: Introductionmentioning

confidence: 99%

Highly Efficient Semiconductor-Based Metasurface for Photoelectrochemical Water Splitting: Broadband Light Perfect Absorption with Dimensions Smaller than the Diffusion Length

Ghobadi

Karadaş

et al. 2019

Plasmonics

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In this paper, we demonstrate a highly efficient light trapping design that is made of a metal-oxide-semiconductor-semiconductor (nanograting/nanopatch) (MOSS g/p) four-layer design to absorb light in a broad wavelength regime in dimensions smaller than the hole diffusion length of the active layer. For this aim, we first adopt a modeling approach based on the transfer matrix method (TMM) to find out the absorption bandwidth (BW) limits of a simple hematite (α-Fe 2 O 3)-based metal-oxide-semiconductor (MOS) cavity design. Our modeling findings show that this design architecture can provide near-perfect absorption in shorter wavelengths. To extend the absorption toward longer wavelengths, a nanostructured semiconductor is placed on top of this MOS design. This nanostructure supports the Mie resonance and adds a new resonance in longer wavelengths without disrupting the lower wavelength absorption capability of MOS cavity. By this way, a polarization-insensitive absorption above 0.8 can be acquired up to λ=565 nm. Moreover, to have a better qualitative comparison, the water-splitting photocurrent of this design has been estimated. Our calculations show that a photocurrent as high as 10.6 mA cm −2 can be achieved with this design that is quite close to the theoretical limit of 12.5 mA cm −2 for hematite-based water-splitting photoanode. This paper proposes a design approach in which the superposition of cavity modes and Mie resonances can lead to a broadband, polarization-insensitive, and omnidirectional near-perfect light absorption in dimensions smaller than the carrier's diffusion length. This can be considered as a winning strategy to design highly efficient and ultrathin optoelectronic designs in a variety of applications including photoelectrochemical water splitting and photovoltaics.

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Section: Introductionmentioning

confidence: 99%

Highly Efficient Semiconductor-Based Metasurface for Photoelectrochemical Water Splitting: Broadband Light Perfect Absorption with Dimensions Smaller than the Diffusion Length

Ghobadi

Karadaş

et al. 2019

Plasmonics

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“…This single layer guided-mode resonant sensor in [35] features with a high FoM of 690 RIU −1 . In [36], the performance of the proposed sensor is not outstanding, however, it is insensitive to the incident wave polarization. In [37][38][39], the sensors come with good sensitivity but relatively low FoM.…”

Section: Performance Comparisonmentioning

confidence: 94%

Spectrometer-Free Graphene Plasmonics Based Refractive Index Sensor

Zhang

Farhat

Salama

2020

Sensors

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We propose a spectrometer-free refractive index sensor based on a graphene plasmonic structure. The spectrometer-free feature of the device is realized thanks to the dynamic tunability of graphene’s chemical potential, through electrostatic biasing. The proposed sensor exhibits a 1566 nm/RIU sensitivity, a 250.6 RIU−1 figure of merit in the optical mode of operation and a 713.2 meV/RIU sensitivity, a 246.8 RIU−1 figure of merit in the electrical mode of operation. This performance outlines the optimized operation of this spectrometer-free sensor that simplifies its design and can bring terahertz sensing one step closer to its practical realization, with promising applications in biosensing and/or gas sensing.

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“…In contrast to the broadband absorbers, some studies aim to design narrowband absorbers that have an absorbance peak at single resonance wavelength. Many different nanopattern configurations were employed for achieving narrowband absorbers that are highly sensitive to the changes in the dielectric properties of their surroundings . Liu et al designed an MIM nanodisk narrowband perfect absorber with a sensitivity of 400 nm RIU −1 (refractive index unit) .…”

Section: Introductionmentioning

confidence: 99%

Lithography‐Free Random Bismuth Nanostructures for Full Solar Spectrum Harvesting and Mid‐Infrared Sensing

Soydan

Ghobadi

Yıldırım

et al. 2019

Advanced Optical Materials

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A lithography‐free, double‐functional single bismuth (Bi) metal nanostructure is designed, fabricated, and characterized for ultrabroadband absorption in the visible (vis) and near‐infrared (NIR) ranges, and for a narrowband response with ultrahigh refractive index sensitivity in the mid‐infrared (MIR) range. To achieve a large‐scale fabrication of the design in a lithography‐free route, the oblique‐angle deposition approach is used to obtain densely packed and randomly spaced/oriented Bi nanostructures. It is shown that this fabrication technique can provide a bottom‐up approach to controlling the length and spacing of the design. The characterization findings reveal a broadband absorbance above 0.8 in vis and NIR, and a narrowband absorbance centered around 6.54 µm. Dense architecture and extraordinary permittivity of Bi provide strong field confinement in ultrasmall gaps between nanostructures, and this can be utilized for a sensing application. An ultrahigh sensitivity of 2151 nm refractive‐index unit (RIU–1) is acquired, which is, as far as it is known, the experimentally highest sensitivity attained so far. The simple and large‐scale compatible fabrication route of the design together with the extraordinary optical response of Bi coating makes this design promising for many optoelectronic and sensing applications.

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Colorimetric and Near-Absolute Polarization-Insensitive Refractive-Index Sensing in All-Dielectric Guided-Mode Resonance Based Metasurface

Cited by 45 publications

References 75 publications

Highly Efficient Semiconductor-Based Metasurface for Photoelectrochemical Water Splitting: Broadband Light Perfect Absorption with Dimensions Smaller than the Diffusion Length

Highly Efficient Semiconductor-Based Metasurface for Photoelectrochemical Water Splitting: Broadband Light Perfect Absorption with Dimensions Smaller than the Diffusion Length

Spectrometer-Free Graphene Plasmonics Based Refractive Index Sensor

Lithography‐Free Random Bismuth Nanostructures for Full Solar Spectrum Harvesting and Mid‐Infrared Sensing

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