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Coherent control of plasmonic nanoantennas using optical eigenmodes

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Coherent control of plasmonic nanoantennas using optical eigenmodes. / Kosmeier, S.; De Luca, A. C.; Zolotovskaya, Svetlana et al.
In: Scientific Reports, Vol. 3, 1808, 2013.

Research output: Contribution to Journal/MagazineJournal articlepeer-review

Harvard

Kosmeier, S, De Luca, AC, Zolotovskaya, S, Di Falco, A, Dholakia, K & Mazilu, M 2013, 'Coherent control of plasmonic nanoantennas using optical eigenmodes', Scientific Reports, vol. 3, 1808. https://doi.org/10.1038/srep01808

APA

Kosmeier, S., De Luca, A. C., Zolotovskaya, S., Di Falco, A., Dholakia, K., & Mazilu, M. (2013). Coherent control of plasmonic nanoantennas using optical eigenmodes. Scientific Reports, 3, Article 1808. https://doi.org/10.1038/srep01808

Vancouver

Kosmeier S, De Luca AC, Zolotovskaya S, Di Falco A, Dholakia K, Mazilu M. Coherent control of plasmonic nanoantennas using optical eigenmodes. Scientific Reports. 2013;3:1808. Epub 2013 May 9. doi: 10.1038/srep01808

Author

Kosmeier, S. ; De Luca, A. C. ; Zolotovskaya, Svetlana et al. / Coherent control of plasmonic nanoantennas using optical eigenmodes. In: Scientific Reports. 2013 ; Vol. 3.

Bibtex

@article{d4d45e2fd1554b8ebf8821fcdab18cd3,
title = "Coherent control of plasmonic nanoantennas using optical eigenmodes",
abstract = "The last decade has seen subwavelength focusing of the electromagnetic field in the proximity of nanoplasmonic structures with various designs. However, a shared issue is the spatial confinement of the field, which is mostly inflexible and limited to fixed locations determined by the geometry of the nanostructures, which hampers many applications. Here, we coherently address numerically and experimentally single and multiple plasmonic nanostructures chosen from a given array, resorting to the principle of optical eigenmodes. By decomposing the light field into optical eigenmodes, specifically tailored to the nanostructure, we create a subwavelength, selective and dynamic control of the incident light. The coherent control of plasmonic nanoantennas using this approach shows an almost zero crosstalk. This approach is applicable even in the presence of large transmission aberrations, such as present in holographic diffusers and multimode fibres. The method presents a paradigm shift for the addressing of plasmonic nanostructures by light.",
author = "S. Kosmeier and {De Luca}, {A. C.} and Svetlana Zolotovskaya and {Di Falco}, A. and K. Dholakia and M. Mazilu",
year = "2013",
doi = "10.1038/srep01808",
language = "English",
volume = "3",
journal = "Scientific Reports",
issn = "2045-2322",
publisher = "Nature Publishing Group",

}

RIS

TY - JOUR

T1 - Coherent control of plasmonic nanoantennas using optical eigenmodes

AU - Kosmeier, S.

AU - De Luca, A. C.

AU - Zolotovskaya, Svetlana

AU - Di Falco, A.

AU - Dholakia, K.

AU - Mazilu, M.

PY - 2013

Y1 - 2013

N2 - The last decade has seen subwavelength focusing of the electromagnetic field in the proximity of nanoplasmonic structures with various designs. However, a shared issue is the spatial confinement of the field, which is mostly inflexible and limited to fixed locations determined by the geometry of the nanostructures, which hampers many applications. Here, we coherently address numerically and experimentally single and multiple plasmonic nanostructures chosen from a given array, resorting to the principle of optical eigenmodes. By decomposing the light field into optical eigenmodes, specifically tailored to the nanostructure, we create a subwavelength, selective and dynamic control of the incident light. The coherent control of plasmonic nanoantennas using this approach shows an almost zero crosstalk. This approach is applicable even in the presence of large transmission aberrations, such as present in holographic diffusers and multimode fibres. The method presents a paradigm shift for the addressing of plasmonic nanostructures by light.

AB - The last decade has seen subwavelength focusing of the electromagnetic field in the proximity of nanoplasmonic structures with various designs. However, a shared issue is the spatial confinement of the field, which is mostly inflexible and limited to fixed locations determined by the geometry of the nanostructures, which hampers many applications. Here, we coherently address numerically and experimentally single and multiple plasmonic nanostructures chosen from a given array, resorting to the principle of optical eigenmodes. By decomposing the light field into optical eigenmodes, specifically tailored to the nanostructure, we create a subwavelength, selective and dynamic control of the incident light. The coherent control of plasmonic nanoantennas using this approach shows an almost zero crosstalk. This approach is applicable even in the presence of large transmission aberrations, such as present in holographic diffusers and multimode fibres. The method presents a paradigm shift for the addressing of plasmonic nanostructures by light.

U2 - 10.1038/srep01808

DO - 10.1038/srep01808

M3 - Journal article

VL - 3

JO - Scientific Reports

JF - Scientific Reports

SN - 2045-2322

M1 - 1808

ER -