Lattice Resonances Excited by Finite-Width Light Beams

Zundel, Lauren; Deop-Ruano, Juan R.; Martı́nez-Herrero, R.; Manjavacas, Alejandro

doi:10.1021/acsomega.2c03847

Cited by 21 publications

(28 citation statements)

References 90 publications

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“…On the other hand, once the light beam is wide enough to fully excite the lattice resonance, the response of the array does not improve by further increasing w inc . At this point, the system reaches the limiting case of plane-wave excitation, as we have shown recently . For this reason, we can understand the collectiveness of a lattice resonance from the way that the optical response of the array evolves with w inc .…”

Section: Resultsmentioning

confidence: 63%

“…In this situation, a significant asymmetry appears, with the slice along the y -axis becoming remarkably wider than the one along the x -axis. The explanation for this behavior is that, as we have recently shown in ref , when w inc is not large enough for the response of the array to be converged to the plane-wave excitation limit, the spatial extension of the lattice resonance exceeds that of the incident light beam. However, this only happens along the direction of propagation of the lattice resonance, which is always perpendicular to the polarization of the light beam that excites it.…”

Section: Resultsmentioning

confidence: 82%

“…As a consequence, Re{α –1 } takes increasingly large positive values, thus forcing the cancellation condition to shift closer to the Rayleigh anomaly, where Re { G xx false( boldk ∥ false) } is also increasingly large. Since the lattice sum represents the strength of the interactions between the nanoparticles of the array, a larger value corresponds to a lattice resonance for which these interactions play a bigger role and, therefore, is more collective in nature …”

Section: Resultsmentioning

confidence: 99%

“…Importantly, as a lattice resonance becomes more collective, it demands that a larger number of nanoparticles be uniformly excited in order to sustain it. This means that, if the light beam that is used to excite the array is not wide enough to uniformly illuminate a sufficiently large number of nanoparticles, the lattice resonance will not be efficiently excited, thus resulting in a weaker absorbance than could otherwise be obtained . On the other hand, once the light beam is wide enough to fully excite the lattice resonance, the response of the array does not improve by further increasing w inc .…”

Section: Resultsmentioning

confidence: 99%

“…We assume the arrays to be excited by a mainly x -polarized beam of finite width and a Gaussian spatial profile. The electric field of this beam at position R i is given by boldE i = 1 4 π 2 ∫ false| boldk ∥ false| ≤ n k normald boldk ∥ boldE ( k ∥ ) e i boldk ∥ · boldR i where E ( k ∥ ) = E inc [ x̂ – ẑ k x / k z ] f (| k ∥ |), f (| k ∥ |) = 2π w inc 2 exp[− w inc 2 | k ∥ | 2 /2], E inc is a constant, and w inc is a parameter that controls the width of the beam. Note that, for E i to satisfy Maxwell’s equations, E ( k ∥ ) · [ k ∥ + k z ẑ ] = 0, where k z = n 2 k 2 − false| boldk ∥ false| 2 .…”

Section: Methodsmentioning

confidence: 99%

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Lattice Resonances for Thermoplasmonics

et al. 2022

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Thanks to their ability to support localized surface plasmons, metallic nanostructures have emerged as ideal tools to transduce light into heat at the nanoscale, giving birth to the field of thermoplasmonics. When arranged in a periodic array, the localized plasmons of metallic nanostructures can interact coherently to generate a collective mode known as a lattice resonance. This collective mode, whose wavelength is controlled by the periodicity of the array, produces a stronger and more spectrally narrow optical response than that of the localized plasmons supported by the individual nanostructures. Motivated by the exceptional properties of the lattice resonances of periodic arrays of metallic nanoparticles, here, we investigate their use for applications in thermoplasmonics. Through a comprehensive analysis based on a coupled dipole model, we show that arrays supporting a lattice resonance absorb more energy per nanoparticle, and thus achieve a much larger increase in temperature under pulsed illumination conditions, than those that do not support such a mode. On the contrary, for continuous wave illumination conditions, we find that the temperature increase is mostly independent of the array period for the systems under consideration. Furthermore, by analyzing arrays with two nanoparticles per unit cell, we show that it is possible to engineer their lattice resonances to selectively absorb light in one of the nanoparticles without exciting the other. The results of this work pave the way for the development of thermoplasmonics applications exploiting the exceptional optical response and tunability provided by lattice resonances.

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Section: Resultsmentioning

confidence: 63%

Section: Resultsmentioning

confidence: 82%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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Lattice Resonances for Thermoplasmonics

et al. 2022

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Perfect Absorption with Independent Electric and Magnetic Lattice Resonances in Metallo‐Dielectric Arrays

Cerdán,

Deop‐Ruano,

Alvarez‐Serrano

et al. 2024

Advanced Optical Materials

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Lattice resonances are collective modes supported by periodic arrays of nanostructures. They originate from the coherent interaction between the localized modes of the individual constituents of the array, which, for systems made of metallic nanostructures, usually correspond to the electric dipole plasmon. Unfortunately, fundamental symmetry reasons preclude a two‐dimensional (2D) arrangement of electric dipoles from absorbing more than half the incident power, thus imposing a strong limitation on the performance of conventional lattice resonances. This work introduces an innovative solution to overcome this constraint, which is based on using an array made of a unit cell containing one metallic and one dielectric nanostructure. Using a rigorous coupled dipole model, it is shown that this system can support two independent lattice resonances associated, respectively, with the electric and magnetic dipole modes of the nanostructures. By adjusting the geometrical characteristics of the array, these two lattice resonances can be meticulously aligned in the spectral domain, leading to the total absorption of the incident power. The results of this work provide clear, yet general, guidelines for the rational design of arrays sustaining lattice resonances capable of producing perfect absorption, thus leveraging the potential of these modes for applications requiring an efficient absorption of light.

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Ultra-narrow bandwidth mid-infrared thermal emitters achieved with all-dielectric metasurfaces

Sun

et al. 2023

International Communications in Heat and Mass Transfer

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Lattice Resonances Excited by Finite-Width Light Beams

Cited by 21 publications

References 90 publications

Lattice Resonances for Thermoplasmonics

Lattice Resonances for Thermoplasmonics

Perfect Absorption with Independent Electric and Magnetic Lattice Resonances in Metallo‐Dielectric Arrays

Ultra-narrow bandwidth mid-infrared thermal emitters achieved with all-dielectric metasurfaces

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