Unveiling breathing plasmon modes in aluminum metal–insulator–metal cavities by cathodoluminescence

Li, Li; Zhao, Daping; Jiang, Fan; Huang, Rong; Wu, Wei; Ren, Mengxin; Zhang, Xinzheng; Cai, Wei; Xu, Jingyi

doi:10.1088/2040-8986/ab70f5

Cited by 3 publications

(6 citation statements)

References 25 publications

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“…Despite their optical losses due to interband transitions (for Au at ∼520 nm), 28–34 Ag or Au surfaces are often used for plasmonic devices. Aluminum (Al), on the other hand, has no transition at the UV-visible and almost perfectly fits to the Drude free electron model, with a narrow interband transition in the near-infrared.…”

Section: Introductionmentioning

confidence: 99%

Second harmonic generation from aluminum plasmonic nanocavities: from scanning to imaging

Zar

Krause

Shavit

et al. 2023

Phys. Chem. Chem. Phys.

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Section: Introductionmentioning

confidence: 99%

Second harmonic generation from aluminum plasmonic nanocavities: from scanning to imaging

Zar

Krause

Shavit

et al. 2023

Phys. Chem. Chem. Phys.

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“…[28][29][30] Plasmonic-based devices are often made of gold and therefore operate at wavelengths longer than 600 nm to avoid losses due to interband transitions that occur at about 550 nm. [31][32][33][34][35][36][37] Recently, aluminum has been recognized as the metal of choice for expanding photonic devices into the visible-UV range. [28,31,[38][39][40][41][42] Aluminum can be treated as an ideal Drude metal with no transition at the UV-visible, except a narrow interband transition at the near-infrared.…”

Section: Introductionmentioning

confidence: 99%

“…to map the local electric fields with a nanoscale resolution. [10,11,37,38,41,42,50,[60][61][62][63][64][65][66] We shall point out that far-field optical measurements are less adapted for characterizing these structures as local effects and spectral resonances are averaged resulting in a broad spectral response.…”

Section: Introductionmentioning

confidence: 99%

“…By using raster scanning, it is possible to retrieve the full spectrum from each pixel of the entire scan, and thus to map the local electric fields with a nanoscale resolution. [ 10,11,37,38,41,42,50,60–66 ] We shall point out that far‐field optical measurements are less adapted for characterizing these structures as local effects and spectral resonances are averaged resulting in a broad spectral response.…”

Section: Introductionmentioning

confidence: 99%

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Nanoscopy of Aluminum Plasmonic Cavities by Cathodoluminescence and Second Harmonic Generation

Zar

Ron

Shavit

et al. 2022

Advanced Photonics Research

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Herein, centrosymmetric aluminum plasmonic structures composed of triangular cavities are studied and their long‐range coupling by cathodoluminescence nanoscopy are visualized. Four different plasmonic structures containing the same subunit are studied. The plasmonic modes of the individual triangular subunits are localized at the triangle sides rather than at the vertices, in agreement with other studies. Yet, upon strong interaction between the cavities, a redistribution of the electromagnetic field is observed such that it delocalizes around the cavities in the form of a contour, providing a mode enhancement and a pronounced nonlinear response as observed by second harmonic generation. Comparison between plasmonic structures made of either silver or aluminum reveals that the metal dielectric function plays an important role in the interaction between the cavities. This work provides a rationale for designing plasmonic structures with enhanced nonlinear activity.

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“…By exciting an individual subwavelength nanoantenna with an electron beam, optical emissions can be effectively generated on subwavelength scales. [14,15] So far, polarization-resolved radiation, [16][17][18] angular emission, [19,20] and breathing plasmon modes [21,22] have been realized with nanoantennas. Among these previous studies, chiral emissions excited by electron beams from nanoantennas are particularly attractive.…”

mentioning

confidence: 99%

Directional Chiral Optical Emission by Electron-Beam-Excited Nano-Antenna

Xiong¹,

Zeng²,

Peng³

et al. 2023

Chinese Phys. Lett.

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Manipulating directional chiral optical emissions on a nanometer scale is significant for material science research. The electron-beam-excited nanoantenna provides a favorable platform to tune optical emissions at the deep subwavelength scale. Here we present an L-shaped electron-beam-excited nanoantenna (LENA) with two identical orthogonal arms. By selecting different electron-beam impacting sites on the LENA, either the left-handed circularly polarized (LCP) or the right-handed circularly polarized (RCP) emission can be excited. The LCP and RCP emissions possess different emission directionality, and the emission wavelength depends on the arm length of the LENA. Further, we show a combined nanoantenna with two LENAs of different arm lengths. Induced by the electron beam, LCP and RCP lights emit simultaneously from the nanoantenna with different wavelengths to different directions. This approach is suggested to be informative for investigating electron-photon interaction and electron-beam spectroscopy in nanophotonics.

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Unveiling breathing plasmon modes in aluminum metal–insulator–metal cavities by cathodoluminescence

Cited by 3 publications

References 25 publications

Second harmonic generation from aluminum plasmonic nanocavities: from scanning to imaging

Second harmonic generation from aluminum plasmonic nanocavities: from scanning to imaging

Nanoscopy of Aluminum Plasmonic Cavities by Cathodoluminescence and Second Harmonic Generation

Directional Chiral Optical Emission by Electron-Beam-Excited Nano-Antenna

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