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Main Authors: Muravitskaya, Alina, Movsesyan, Artur, Avalos-Ovando, Oscar, Lorca, Veronica A. Bahamondes, Correa-Duarte, Miguel A., Besteiro, Lucas V., Liedl, Tim, Yu, Peng, Wang, Zhiming, Markovich, Gil, Govorov, Alexander O.
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2401.00944
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author Muravitskaya, Alina
Movsesyan, Artur
Avalos-Ovando, Oscar
Lorca, Veronica A. Bahamondes
Correa-Duarte, Miguel A.
Besteiro, Lucas V.
Liedl, Tim
Yu, Peng
Wang, Zhiming
Markovich, Gil
Govorov, Alexander O.
author_facet Muravitskaya, Alina
Movsesyan, Artur
Avalos-Ovando, Oscar
Lorca, Veronica A. Bahamondes
Correa-Duarte, Miguel A.
Besteiro, Lucas V.
Liedl, Tim
Yu, Peng
Wang, Zhiming
Markovich, Gil
Govorov, Alexander O.
contents Energetic and optical properties of plasmonic nanocrystals strongly depend on their sizes, shapes, and composition. Whereas using plasmonic nanoparticles in biotesting has become routine, applications of plasmonics in energy are still early in development. Here, we investigate hot electron (HE) generation and related electromagnetic effects in both mono- and bi-metallic nanorods (NRs) and focus on one promising type of bi-metallic nanocrystals - core-shell Au-Ag nanorods. The spectra of the NRs are broadband, highly tunable with their geometry, and have few plasmon resonances. In this work, we provide a new quantum formalism describing the HE generation in bi-metallic nanostructures. Interestingly, we observe that the HE generation rate at the UV plasmon resonance of Au-Ag NRs appears to be very high. These HEs are highly energetic and suitable for carbon-fuel reactions. Simultaneously, the HE generation at the longitudinal plasmon (L-plasmon) peaks, which can be tuned from the yellow to near-IR, depends on the near-field and electromagnetic Mie effects, limiting the HE efficiencies for the long and large NRs. These properties of the L-plasmon relate to all kinds of NRs (Au, Ag, and Au-Ag). We also consider the generation of the interband d-holes in Au and Ag, since the involvement of the d-band is crucial for the energetic properties of UV plasmons. The proposed formalism is an important development for the description of bi-metallic (or tri-metallic, or more complex) nanostructures, and it paves the way to the efficient application of the plasmonic HEs and hot holes in sensing, nanotechnology, photocatalysis, and electrophotochemistry.
format Preprint
id arxiv_https___arxiv_org_abs_2401_00944
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Hot electrons and electromagnetic effects in the broadband Au, Ag, and Ag-Au nanocrystals: The UV, visible, and NIR plasmons
Muravitskaya, Alina
Movsesyan, Artur
Avalos-Ovando, Oscar
Lorca, Veronica A. Bahamondes
Correa-Duarte, Miguel A.
Besteiro, Lucas V.
Liedl, Tim
Yu, Peng
Wang, Zhiming
Markovich, Gil
Govorov, Alexander O.
Mesoscale and Nanoscale Physics
Computational Physics
Energetic and optical properties of plasmonic nanocrystals strongly depend on their sizes, shapes, and composition. Whereas using plasmonic nanoparticles in biotesting has become routine, applications of plasmonics in energy are still early in development. Here, we investigate hot electron (HE) generation and related electromagnetic effects in both mono- and bi-metallic nanorods (NRs) and focus on one promising type of bi-metallic nanocrystals - core-shell Au-Ag nanorods. The spectra of the NRs are broadband, highly tunable with their geometry, and have few plasmon resonances. In this work, we provide a new quantum formalism describing the HE generation in bi-metallic nanostructures. Interestingly, we observe that the HE generation rate at the UV plasmon resonance of Au-Ag NRs appears to be very high. These HEs are highly energetic and suitable for carbon-fuel reactions. Simultaneously, the HE generation at the longitudinal plasmon (L-plasmon) peaks, which can be tuned from the yellow to near-IR, depends on the near-field and electromagnetic Mie effects, limiting the HE efficiencies for the long and large NRs. These properties of the L-plasmon relate to all kinds of NRs (Au, Ag, and Au-Ag). We also consider the generation of the interband d-holes in Au and Ag, since the involvement of the d-band is crucial for the energetic properties of UV plasmons. The proposed formalism is an important development for the description of bi-metallic (or tri-metallic, or more complex) nanostructures, and it paves the way to the efficient application of the plasmonic HEs and hot holes in sensing, nanotechnology, photocatalysis, and electrophotochemistry.
title Hot electrons and electromagnetic effects in the broadband Au, Ag, and Ag-Au nanocrystals: The UV, visible, and NIR plasmons
topic Mesoscale and Nanoscale Physics
Computational Physics
url https://arxiv.org/abs/2401.00944