Interfering Plasmons in Coupled Nanoresonators to Boost Light Localization and SERS
Technology
field enhancement
Chemistry, Multidisciplinary
Materials Science
Materials Science, Multidisciplinary
nano-optics
02 engineering and technology
plasmon interference
Physics, Applied
MOLECULES
ENHANCEMENT
EXCITATION
TEORIA DE LA SEÑAL Y COMUNICACIONES
NANOPARTICLES
ABSORPTION
SCATTERING
remote excitation
Nanoscience & Nanotechnology
Field enhancement
Science & Technology
Chemistry, Physical
SERS
Physics
near-field
Plasmon interference
Nanocavity
Chemistry
Near-field
Physics, Condensed Matter
Nano-optics
Physical Sciences
MODES
Science & Technology - Other Topics
AU
PHOTOLUMINESCENCE
EMISSION
0210 nano-technology
Remote excitation
DOI:
10.1021/acs.nanolett.0c04987
Publication Date:
2021-03-11T18:54:51Z
AUTHORS (6)
ABSTRACT
Plasmonic self-assembled nanocavities are ideal platforms for extreme light localization as they deliver mode volumes of <50 nm3. Here we show that high-order plasmonic modes within additional micrometer-scale resonators surrounding each nanocavity can boost light localization to intensity enhancements >105. Plasmon interference in these hybrid microresonator nanocavities produces surface-enhanced Raman scattering (SERS) signals many-fold larger than in the bare plasmonic constructs. These now allow remote access to molecules inside the ultrathin gaps, avoiding direct irradiation and thus preventing molecular damage. Combining subnanometer gaps with micrometer-scale resonators places a high computational demand on simulations, so a generalized boundary element method (BEM) solver is developed which requires 100-fold less computational resources to characterize these systems. Our results on extreme near-field enhancement open new potential for single-molecule photonic circuits, mid-infrared detectors, and remote spectroscopy.
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CITATIONS (38)
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