A Critical Analysis on the Sensitivity Enhancement of Surface Plasmon Resonance Sensors with Graphene

Almeida, Aline dos S.; Bahamon, D. A.; Peres, N. M. R.; Matos, Christiano J. S. de

doi:10.3390/nano12152562

Cited by 9 publications

(3 citation statements)

References 50 publications

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“…where r p∕s ij are the Fresnel reflection coefficients for p/s-polarized waves, in the boundary between layers i and j 44,45 and are given as…”

Section: Reflection Coefficients Of Tmd/graphene/tmd Heterostructurementioning

confidence: 99%

Sandwich heterostructure of transition metal dichalcogenide/graphene as tunable lateral reflection shifter

Zoghi

2023

J. Nanophoton.

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.The advent of nanotechnology has led to the inevitable need for miniaturization in optoelectronic devices. To achieve this goal, materials with low thickness, conductivity, and transparency, as well as a larger active area, must be developed. Experiments have proven that the opto-electrical properties of transition metal dichalcogenides (TMD)/graphene combinations are highly tunable. On the other hand, a notable feature of light when reflecting from an interface is its spatial and angular displacements. The “lateral shift” in the incident plane, referred to as the Goos–Hanchen (GH) shift, has garnered significant interest among researchers owing to its extensive range of applications. In our work, an atomically thin TMD/graphene/TMD sandwich heterostructure is proposed, and its spatial and angular GH shifts are investigated. The theoretical analysis includes various TMD materials such as MoSe2, MoS2, WSe2, and WS2. A detailed study of the effects of wavelength, polarization, incident angle, and number of TMD layers in symmetric and asymmetric structures suggests that this hybrid can serve as an ultrathin broadband tunable sensor in optical devices.

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“…where r p∕s ij are the Fresnel reflection coefficients for p/s-polarized waves, in the boundary between layers i and j 44,45 and are given as…”

Section: Reflection Coefficients Of Tmd/graphene/tmd Heterostructurementioning

confidence: 99%

Sandwich heterostructure of transition metal dichalcogenide/graphene as tunable lateral reflection shifter

Zoghi

2023

J. Nanophoton.

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“…Graphene, a two-dimensional material composed of carbon atoms arranged in a honeycomb lattice structure through sp 2 hybridization, has emerged as a versatile candidate for integration with metasurfaces [24,25]. A plethora of research related to graphene's interaction with SPWs has been published, covering areas such as graphene dispersion theory [26], grating excitation [27], decoders [28], sensors [29], and tunable multiband absorption [30]. One of graphene's distinctive advantages is its voltage-controllable conductivity, making it a crucial material for active SPWs control [31].…”

Section: Introductionmentioning

confidence: 99%

Active control of polarization-dependent terahertz surface plasmonic wave excitation using coupled graphene-metal hybrid metasurfaces

Su,

Li,

et al. 2024

Phys. Scr.

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Active control of terahertz surface plasmonic wave (SPW) intensity in the propagation direction holds substantial significance for advanced terahertz functional devices. In this study, we propose a graphene-metal hybrid split-ring slit resonator (SRSR) array metasurfaces and employ the concept of electromagnetically induced transparency (EIT) to achieve excitation of asymmetric SPWs under various polarization states. By individually integrating two graphene ribbons into the two split-ring slit gaps and applying different bias voltages, we observed a gradual transition in the excitation behavior of asymmetric terahertz SPWs, ultimately resembling that of a single SRSR. Near-field simulations reveal that this phenomenon is attributed to the short-connection effect of graphene. Our proposed graphene-metal active hybrid metasurface introduces a novel approach to realize active SPWs devices, holding potential applications in terahertz on-chip communication.

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“…Moreover, hybrid GO and MoS structures [ 29 , 30 ] are proven to be viable alternatives to MoS-based sensors, while their rGO-based counterparts can effectively detect chemically aggressive gases (i.e., NO

, NH

, Cl

, and NO) with typical response and recovery times of about several tens of minutes [ 31 , 32 ]. Finally, the electronic and mechanical properties of graphene enable an easier transduction of the sensing signal, turning the rGO to a very attractive candidate for the design of efficient sensing devices [ 33 , 34 , 35 ].…”

Section: Introductionmentioning

confidence: 99%

Robust FDTD Modeling of Graphene-Based Conductive Materials with Transient Features for Advanced Antenna Applications

et al. 2023

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The accurate modeling of frequency-dispersive materials is a challenging task, especially when a scheme with a transient nature is utilized, as it is the case of the finite-difference time-domain method. In this work, a novel implementation for the modeling of graphene-oriented dispersive materials via the piecewise linear recursive convolution scheme, is introduced, while the time-varying conductivity feature is, additionally, launched. The proposed algorithm is employed to design a reduced graphene-oxide antenna operating at 6 GHz. The transient response to graphene’s conductivity variations is thoroughly studied and a strategy to enhance the antenna performance by exploiting the time-varying graphene oxide is proposed. Finally, the use of the featured antenna for modern sensing applications is demonstrated through the real-time monitoring of voltage variation.

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A Critical Analysis on the Sensitivity Enhancement of Surface Plasmon Resonance Sensors with Graphene

Cited by 9 publications

References 50 publications

Sandwich heterostructure of transition metal dichalcogenide/graphene as tunable lateral reflection shifter

Sandwich heterostructure of transition metal dichalcogenide/graphene as tunable lateral reflection shifter

Active control of polarization-dependent terahertz surface plasmonic wave excitation using coupled graphene-metal hybrid metasurfaces

Robust FDTD Modeling of Graphene-Based Conductive Materials with Transient Features for Advanced Antenna Applications

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