Analytical Modeling of Graphene Plasmons

Yu, Renwen; Cox, Joel D.; Saavedra, J. R. M.; Abajo, F. Javier García de

doi:10.1021/acsphotonics.7b00740

Cited by 61 publications

(85 citation statements)

References 54 publications

(105 reference statements)

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“…Notwithstanding, the vibrant field of graphene plasmonics is considerably wealthier, going well beyond the restricted subgroup of infinite, extended graphene structures. Below, we shall expand our previous considerations by discussing localized plasmons in graphene nanostructures . These are typically fabricated by patterning an otherwise continuous graphene sheet, and arguably constitute the most abundant subset of graphene‐based plasmonic structures considered in the scientific literature.…”

Section: Graphene Plasmon Polaritonsmentioning

confidence: 99%

“…Moreover, owing to the extreme subwavelength confinement promoted by GPs, the nonretarded limit (defined by the absence of retardation effects) can be taken without any loss of accuracy in nearly all the relevant scenarios. In fact, treating plasmons in graphene within a nonretarded approach often constitutes an excellent approximation, as demonstrated in a number of works . In this vein, we take the nonretarded limit (i.e., q ≫ k 0 ) of Equation , thereby obtaining the nonretarded dispersion relation of graphene plasmons

q = \frac{2 i ω ε_{0} \bar{ε}}{σ (q, ω)}

where we have introduced the quantity

\bar{ε} = (ε_{1} + ε_{2}) / 2

without loss of generality .…”

Section: Graphene Plasmon Polaritonsmentioning

confidence: 99%

“…In general, this cannot be done analytically and therefore one has to rely on numerical methods. In spite of this, it is still possible to solve Equation using semianalytical techniques . Broadly speaking, the idea behind such semianalytical methods is to expand the electric potential

ϕ ({\overset{true˜}{boldnormalr}}_{∥})

using a suitable set of basis functions.…”

Section: Graphene Plasmon Polaritonsmentioning

confidence: 99%

“…The disk's eigenmodes of dipole character, i.e., with l = 1, are of particular importance with respect to their excitation and interaction with plane‐waves, since they can couple strongly to these. Evidently, in the nonretarded limit the fundamental dipole mode {1, 1} dominates the optical response of the system under plane‐wave illumination, and whose absorption cross section has been shown to be quite substantial …”

Section: Graphene Plasmon Polaritonsmentioning

confidence: 99%

“…, which constitutes an extension of the electrostatic eigenmode expansion for the linear optical response outlined in ref. (in a way reminiscent of the framework detailed in Section ) to higher‐order processes. In this model (presented in this section in Gaussian units), the response associated with a nonlinear optical process of order n and harmonic s [e.g., n = s = 3 for third‐harmonic generation (THG)] to an external field E ext e −i ωt + c.c.…”

Section: Nonlinear Graphene Plasmonicsmentioning

confidence: 99%

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Strong Light–Matter Interactions Enabled by Polaritons in Atomically Thin Materials

Gonçalves

Stenger

Cox

et al. 2020

Advanced Optical Materials

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Polaritons, resulting from the hybridization of light with polarization charges formed at the boundaries between media with positive and negative dielectric response functions, can focus light into regions much smaller than its associated free‐space wavelength. This property is paramount for a plethora of applications in nanophotonics, ranging from biological sensing to photocatalysis to nonlinear and quantum optics. In the two‐dimensional (2D) limit, represented by atomically thin and van der Waals (vdW) materials of single‐layers bound by weak vdW attraction, polaritons are characterized by extremely small wavelengths associated with extreme optical confinement, and furthermore can exhibit long lifetimes, electrical tunability, and extreme sensitivity to their dielectric environment, among many other desirable qualities in nano‐optical device applications. Here, the fundamentals of polaritons in atomically thin materials are summarized, emphasizing plasmon and exciton polaritons, their strong light–matter interactions, and nonlinear plasmonics. More specifically, this review opens with a pedagogical discussion of plasmons in extended and nanostructured graphene, providing a classical electrodynamical model in a nonretarded theoretical framework, and the ultraconfined acoustic plasmons supported by hybrid graphene–dielectric–metal structures. In addition, the basic principles are introduced and the recent developments on nonlinear graphene plasmonics and on strong coupling physics with atomically thin transition metal dichalcogenides are reviewed. Finally, potentially new, promising research directions in the burgeoning field of 2D nanophotonics are identified.

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Section: Graphene Plasmon Polaritonsmentioning

confidence: 99%

q = \frac{2 i ω ε_{0} \bar{ε}}{σ (q, ω)}

where we have introduced the quantity

\bar{ε} = (ε_{1} + ε_{2}) / 2

without loss of generality .…”

Section: Graphene Plasmon Polaritonsmentioning

confidence: 99%

ϕ ({\overset{true˜}{boldnormalr}}_{∥})

using a suitable set of basis functions.…”

Section: Graphene Plasmon Polaritonsmentioning

confidence: 99%

Section: Graphene Plasmon Polaritonsmentioning

confidence: 99%

Section: Nonlinear Graphene Plasmonicsmentioning

confidence: 99%

See 3 more Smart Citations

Strong Light–Matter Interactions Enabled by Polaritons in Atomically Thin Materials

Gonçalves

Stenger

Cox

et al. 2020

Advanced Optical Materials

Self Cite

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Effects of Mid‐Infrared Graphene Plasmons on Photothermal Heating

Phan

Nga

Nghia

et al. 2020

Physica Rapid Research Ltrs

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Herein, the plasmonic heating of graphene‐based systems under the mid‐infrared laser irradiation is theoretically investigated, where periodic arrays of graphene plasmonic resonators are placed on dielectric thin films. Optical resonances are sensitive to structural parameters and the number of graphene layers. Under mid‐infrared laser irradiation, the steady‐state temperature gradients are calculated. It is found that graphene plasmons significantly enhance the confinement of electromagnetic fields in the system and lead to a large temperature increase compared with the case without graphene. The correlations between temperature change and the optical power, laser spot, and thermal conductivity of dielectric layer in these systems are discussed. The numerical results are in accordance with experiments.

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Tailoring Drug Mobility by Photothermal Heating of Graphene Plasmons

Phan

Ngân

Nga

et al. 2022

Physica Rapid Research Ltrs

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A theoretical approach to quantitatively determine the photothermally driven enhancement of molecular mobility of graphene‐indomethacin mixtures under infrared laser irradiation is proposed. Graphene plasmons absorb incident electromagnetic energy and dissipate them into heat. The absorbed energy depends on optical properties of graphene plasmons, which are sensitive to structural parameters, and concentration of plasmonic nanostructures. By using theoretical modelling, temperature gradients of the bulk drug with different concentrations of graphene plasmons are calculated. From these, the temperature dependence of structural molecular relaxation and diffusion of indomethacin are determined and how the heating process significantly enhances the drug mobility is found out.

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Analytical Modeling of Graphene Plasmons

Cited by 61 publications

References 54 publications

Strong Light–Matter Interactions Enabled by Polaritons in Atomically Thin Materials

Strong Light–Matter Interactions Enabled by Polaritons in Atomically Thin Materials

Effects of Mid‐Infrared Graphene Plasmons on Photothermal Heating

Tailoring Drug Mobility by Photothermal Heating of Graphene Plasmons

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