Magnetoplasmonics in confined geometries: Current challenges and future opportunities
Plasmonics represents a unique approach to confine and enhance electromagnetic
radiation well below the diffraction limit, bringing a huge potential for novel applications, for …
radiation well below the diffraction limit, bringing a huge potential for novel applications, for …
Magnetoplasmonics in confined geometries: Current challenges and future opportunities
N Maccaferri, A Gabbani, F Pineider… - Applied Physics …, 2023 - ui.adsabs.harvard.edu
Plasmonics represents a unique approach to confine and enhance electromagnetic
radiation well below the diffraction limit, bringing a huge potential for novel applications, for …
radiation well below the diffraction limit, bringing a huge potential for novel applications, for …
[PDF][PDF] Magnetoplasmonics in confined geometries: Current challenges and future opportunities
N Maccaferri, A Gabbani, F Pineider - 2023 - nanogune.eu
Plasmonics represents a unique approach to confine and enhance electromagnetic
radiation well below the diffraction limit, bringing a huge potential for novel applications, for …
radiation well below the diffraction limit, bringing a huge potential for novel applications, for …
Magnetoplasmonics: current challenges and future opportunities
N Maccaferri, A Gabbani, F Pineider, T Kaihara… - arXiv preprint arXiv …, 2022 - arxiv.org
Plasmonics represents a unique approach to confine and enhance electromagnetic
radiation well below the diffraction limit, bringing a huge potential for novel applications, for …
radiation well below the diffraction limit, bringing a huge potential for novel applications, for …
[PDF][PDF] Magnetoplasmonics in confined geometries: Current challenges and future opportunities
N Maccaferri, A Gabbani, F Pineider - 2023 - researchgate.net
Plasmonics represents a unique approach to confine and enhance electromagnetic
radiation well below the diffraction limit, bringing a huge potential for novel applications, for …
radiation well below the diffraction limit, bringing a huge potential for novel applications, for …
Magnetoplasmonics in confined geometries: current challenges and future opportunities
N Maccaferri, A Gabbani, F Pineider, T Kaihara… - Applied Physics …, 2023 - diva-portal.org
The ability to control materials at the nanoscale allows to confine light into subwavelength
volumes by exploiting collective electromagnetic-induced electronic excitations, known as …
volumes by exploiting collective electromagnetic-induced electronic excitations, known as …
Magnetoplasmonics: current challenges and future opportunities
N Maccaferri, A Gabbani, F Pineider, T Kaihara… - 2022 - preprints.opticaopen.org
Plasmonics represents a unique approach to confine and enhance electromagnetic
radiation well below the diffraction limit, bringing a huge potential for novel applications, for …
radiation well below the diffraction limit, bringing a huge potential for novel applications, for …
Magnetoplasmonics in confined geometries: current challenges and future opportunities
N Maccaferri, A Gabbani, F Pineider, T Kaihara… - Applied Physics …, 2023 - swepub.kb.se
Plasmonics represents a unique approach to confine and enhance electromagnetic
radiation well below the diffraction limit, bringing a huge potential for novel applications, for …
radiation well below the diffraction limit, bringing a huge potential for novel applications, for …
Magnetoplasmonics in confined geometries: Current challenges and future opportunities
N Maccaferri, A Gabbani, F Pineider, T Kaihara… - Applied Physics …, 2023 - pubs.aip.org
Plasmonics represents a unique approach to confine and enhance electromagnetic
radiation well below the diffraction limit, bringing a huge potential for novel applications, for …
radiation well below the diffraction limit, bringing a huge potential for novel applications, for …
Magnetoplasmonics in confined geometries: Current challenges and future opportunities
N Maccaferri, A Gabbani, F Pineider, T Kaihara… - APPLIED PHYSICS …, 2023 - flore.unifi.it
Plasmonics represents a unique approach to confine and enhance electromagnetic
radiation well below the diffraction limit, bringing a huge potential for novel applications, for …
radiation well below the diffraction limit, bringing a huge potential for novel applications, for …