Hybrid architectures for terahertz molecular polaritonics

Jaber, Ahmed; Reitz, Michael; Singh, Avinash; Maleki, Ali; Xin, Yongbao; Sullivan, Brian T.; Dolgaleva, Ksenia; Boyd, Robert W.; Genes, Claudiu; Ménard, Jean-Michel

doi:10.1038/s41467-024-48764-6

Nat Commun

2024

DOI: 10.1038/s41467-024-48764-6

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Hybrid architectures for terahertz molecular polaritonics

Ahmed Jaber,

Michael Reitz,

Avinash Singh

et al.

Abstract: Atoms and their different arrangements into molecules are nature’s building blocks. In a regime of strong coupling, matter hybridizes with light to modify physical and chemical properties, hence creating new building blocks that can be used for avant-garde technologies. However, this regime relies on the strong confinement of the optical field, which is technically challenging to achieve, especially at terahertz frequencies in the far-infrared region. Here we demonstrate several schemes of electromagnetic fiel… Show more

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Cited by 4 publications

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Pixelated Toroidal Metasurface Sensor with Broadband Terahertz Fingerprint Enhancement for Biochemical Trace Detection

Han,

Wang,

Zhang

et al. 2024

ACS Appl. Mater. Interfaces

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Terahertz (THz) trace fingerprint detection is essential for identifying the characteristic biomolecular absorption fingerprints from inherent molecular rotational and vibrational modes. Plasmonic THz resonance shows a way to enhance the recognition of biomolecular absorption fingerprint spectra. In this research, we experimentally demonstrate a broadband THz fingerprint metasensor based on a pixelated toroidal metasurface, showcasing excellent capabilities in biochemical trace detection. The design employs mirrored asymmetric double split-ring resonators to excite the toroidal resonance with a high quality (Q) factor and strong localized field enhancement. This high Qfactor resonance exhibits exceptional spectral resolution with spectral resolution less than 50 GHz for broadband fingerprint sensing, thereby capturing characteristic information. More importantly, the design allows for linear modulation of the split-ring resonator radius, which can be extended to cover a larger spectral region by adjusting geometric parameters to meet multifingerprints detection of various biochemical analytes. Utilizing fingerprint enhancement and multiplexing technology, the metasensor precisely detects trace glucose with a high sensitivity. The introduction of the metasensor significantly enhances the absorption characteristics of glucose films, demonstrating an outstanding broadband fingerprint sensing performance. This high-performance and flexible fingerprint metasensor has potential applications in enhanced broadband THz fingerprint sensing, providing a powerful and low-cost approach for advanced biochemical trace detection.

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Pixelated Toroidal Metasurface Sensor with Broadband Terahertz Fingerprint Enhancement for Biochemical Trace Detection

Han,

Wang,

Zhang

et al. 2024

ACS Appl. Mater. Interfaces

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On chip glucose sensing using guided waves at terahertz frequencies

Haghighat,

Darcie,

Smith

2024

Sci Rep

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This paper demonstrates an on-chip anhydrous D-glucose sensor using a coplanar stripline (CPS) on a thin (1 µm) silicon nitride membrane at terahertz (THz) frequencies. A thin layer (≈ 10 µm) of D-glucose was placed in close proximity to the CPS and the transmission response was measured using a modified THz-TDS setup. The D-glucose introduces frequency-dependent changes to the effective permittivity of the CPS resulting in a modified spectral response at the receiver. Measurement results show absorption signatures at 1.42 THz and 2.07 THz corresponding to the first two significant resonances beyond 1 THz for D-glucose allowing for label-free detection. The frequency-dependent attenuation coefficient was estimated by simulation for several D-glucose layer thicknesses using a modified Lorentz model. Measurement results align with simulations and other literature that use free-space THz radiation. This work verifies on-chip THz sensing of D-glucose and presents a pathway toward on-chip sensing of other materials at THz frequencies.

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Dielectric-metal hybrid structured LSPR sensor based on graphene oxide amplification for lead ion detection

Li,

Wu,

Jin

et al. 2024

Opt. Express

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The detection of lead ions (Pb2+) is crucial due to its harmful effects on health and the environment. In this article, what we believe to be a novel dielectric-metal hybrid structure localized surface plasmon resonance (LSPR) sensor for ultra-trace detection of Pb2+ is proposed, featuring a zinc sulfide layer, silver nanodisks (Ag-disks), and graphene oxide (GO) covering the Ag-disks. The sensor works by detecting the variation of gold nanoparticles (AuNPs) on its surface when Pb2+ cleaves a substrate strand linked to a DNAzyme, causing the AuNPs modified on the substrate strand to disperse. The LSPR sensor boasts superior performance with a bulk refractive index sensitivity of 714.34 nm/RIU. It also exhibits a log-linear response to Pb2+ concentrations ranging from 10 pM to 100 nM, with a sensitivity of 3.93 nm/log(µM) and a detection limit of 10 pM. This represents a 1.25-fold increase in sensitivity and an order of magnitude lower detection limit compared to the GO-uncoated sensor. The improved performance is due to the abundant reactive groups and expansive surface area of graphene oxide, which facilitate the absorption of biochemical molecules. In addition, the sensor has good specificity and stability, holding significant potential for a variety of practical applications, and paving the way for LSPR sensors in detecting trace heavy metal ions.

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Hybrid architectures for terahertz molecular polaritonics

Cited by 4 publications

References 38 publications

Pixelated Toroidal Metasurface Sensor with Broadband Terahertz Fingerprint Enhancement for Biochemical Trace Detection

Pixelated Toroidal Metasurface Sensor with Broadband Terahertz Fingerprint Enhancement for Biochemical Trace Detection

On chip glucose sensing using guided waves at terahertz frequencies

Dielectric-metal hybrid structured LSPR sensor based on graphene oxide amplification for lead ion detection

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