Metamaterial-enhanced vibrational absorption spectroscopy for the detection of protein molecules

Bui, Tung S.; Dao, Thang Duy; Dang, Luu H.; Vu, Lam Dinh; Ohi, Akihiko; Nabatame, Toshihide; Lee, YoungPak; Nagao, Tadaaki; Hoang, Chung Vu

doi:10.1038/srep32123

Cited by 70 publications

(33 citation statements)

References 39 publications

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“…Due to these characteristics, the biological-related THz research activity has spread throughout the world covering a wide variety of fields such as diagnosis of diseases, [70] detection of protein concentrations, [71,72] DNA sequencing, [73,74] detection of cancer cells and tumors, [17,70] or detection of microorganisms, [75,76] among others. This is mainly because THz radiation has proven to be a non-invasive, contactless, and non-ionizing technique innocuous to living organisms exposed to it.…”

Section: Introduction To Thz Biosensingmentioning

confidence: 99%

Terahertz Sensing Based on Metasurfaces

Beruete

Jáuregui-López

2019

Advanced Optical Materials

236

113

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The terahertz (THz) band has very attractive characteristics for sensing and biosensing applications, due to some interesting features such as being a non‐ionizing radiation, very sensitive to weak interactions, thus, complementing typical spectroscopy systems in the infrared. However, a fundamental drawback is its relatively long wavelength (10–1000 µm) which makes it blind to small features, hindering seriously both thin‐film and biological sensing. Recently, new ways to overcome this limitation have become possible thanks to the advent of metasurfaces. These artificial structures are planar screens usually made of periodic metallic resonators and whose electromagnetic response can be controlled at will by design. This design freedom allows metasurfaces to surpass the restrictions of classical THz spectroscopy, by creating fine details comparable to the size of the thin films or microorganisms under test. The strong field concentration near these small metasurface details at resonance makes them highly sensitive to tiny variations in the nearby environment, allowing for an enhanced detection more accurate than classical THz spectroscopy. The main advances in THz metasurface sensors from a historical as well as application‐oriented perspective are summarized. The focus is put mainly on thin‐film and biological sensors, with an aim to cover the most recent advances in the topic.

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Section: Introduction To Thz Biosensingmentioning

confidence: 99%

Terahertz Sensing Based on Metasurfaces

Beruete

Jáuregui-López

2019

Advanced Optical Materials

236

113

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“…The terahertz (THz) spectral range of electromagnetic waves (0.1–10 THz), lying between the microwave and optical regions, is of great interest, primarily due to the fact that in this band of the electromagnetic spectrum reside the frequencies of some elementary excitations in semiconductors and dielectrics , as well as rotational and vibrational resonances of complex, including biological, molecules . As a result, THz waves have a tremendous number of applications in areas ranging from the detection of dangerous or illicit substances and biological sensing to diagnosis and treatment of diseases in medicine . Moreover, this frequency band is of special importance for spectroscopy in astrophysics because many astrophysical objects emit in the THz range of the spectrum.…”

Section: Introductionmentioning

confidence: 99%

Enhancement of terahertz photoconductive antenna operation by optical nanoantennas

Lepeshov

Gorodetsky

Krasnok

et al. 2016

Laser & Photonics Reviews

137

121

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Photoconductive antennas are promising sources of terahertz radiation that is widely used for spectroscopy, characterization, and imaging of biological objects, deep space studies, scanning of surfaces, and detection of potentially hazardous substances. These antennas are compact and allow for generation of both ultrabroadband pulses and tunable continuous wave terahertz signals at room temperatures, with no need for high‐power optical sources. However, such antennas have relatively low energy conversion efficiency of femtosecond laser pulses or two close pump wavelengths (photomixers) into the pulsed and continuous terahertz radiation, correspondingly. Recently, an approach to solving this problem that involves known methods of nanophotonics applied to terahertz photoconductive antennas and photomixers has been proposed. This approach comprises the use of optical nanoantennas for enhancing the absorption of pump laser radiation in the antenna gap, reducing the lifetime of photoexcited carriers, and improving the antenna thermal efficiency. This Review is intended to systematize the main results obtained by researchers in this promising field of hybrid optical‐to‐terahertz photoconductive antennas and photomixers. We summarize the main results on hybrid THz antennas, compare the approaches to their implementation, and offer further perspectives of their development including an application of all‐dielectric nanoantennas instead of plasmonic ones.

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“…Such electronic materials are garnering more and more attraction. Especially, broadband MPAs in GHz and THz regions possess many important technological applications in imaging 21 , sensing 22,23 , energy harvesting 24 or in micro antenna communication 25,26 , which need perfect absorbers to efficiently collect electromagnetic energy. Many efforts to optimize broadband MPAs have been made, such as multi metal-insulator layers 27 , multi resonance mode combination 28 , super unit cell structure 29 .…”

Section: Introductionmentioning

confidence: 99%

Controlled Defect Based Ultra Broadband Full-sized Metamaterial Absorber

Tran

Hai

et al. 2018

Sci Rep

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Metamaterial full-sized absorber structures are numerically and experimentally investigated in GHz region and then examined in THz frequency. By manipulating monitoring the number and the position of the defect elements in conventional unit cells, the optimal integrative absorber structures are generated. The proposed structures provide an ultra-broadband absorbance in the operating frequency. The good agreement between simulation, measurement and theoretical analysis is observed with a 5 GHz-bandwidth corresponding to the absorption of 95%. In particular, we extrapolate the concept to THz region and demonstrate that, the method can be applied to increase the bandwidth of the metamaterial absorber to 5 THz, while maintaining the other characteristics. This structure can be applied to improve the performance of telecommunication systems such as micro-antenna, micro-electromagnetic transmitters and apply to imaging and sensing fields.

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Metamaterial-enhanced vibrational absorption spectroscopy for the detection of protein molecules

Cited by 70 publications

References 39 publications

Terahertz Sensing Based on Metasurfaces

Terahertz Sensing Based on Metasurfaces

Enhancement of terahertz photoconductive antenna operation by optical nanoantennas

Controlled Defect Based Ultra Broadband Full-sized Metamaterial Absorber

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