The simplest plasmonic molecules: Metal nanoparticle dimers and trimers

•The simplest plasmonic molecule (PM) is a cluster of 2–3 metal particles.•PMs can be generated by solution chemistry or nanofabrication.•Electromagnetic hot spots in their gaps enhance Raman scattering or fluorescence.•Symmetry of a PM affects its excitations, which can be classified by group theor...

Full description

Saved in:
Bibliographic Details
Published in:Journal of photochemistry and photobiology. C, Photochemistry reviews Photochemistry reviews, 2014-12, Vol.21, p.26-39
Main Authors: Zohar, Nir, Chuntonov, Lev, Haran, Gilad
Format: Article
Language:English
Subjects:
Nanofabrication
Plasmon modes
Surface plasmon resonance
Surface-enhanced Raman
Symmetry breaking
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:•The simplest plasmonic molecule (PM) is a cluster of 2–3 metal particles.•PMs can be generated by solution chemistry or nanofabrication.•Electromagnetic hot spots in their gaps enhance Raman scattering or fluorescence.•Symmetry of a PM affects its excitations, which can be classified by group theory.•PMs can serve as antennas, sensors or quantum cavities interacting with molecules. This review discusses research on the plasmonic properties of small clusters of metal nanoparticles, with two and three particles. These are the simplest examples of ‘plasmonic molecules’. Coupling between two particles leads to new surface plasmon resonances and to the creation of a hot spot of a strong electric field in the gap between the particles. Such a hot spot can be used to enhance Raman scattering or fluorescence, making plasmonic dimers useful for applications in spectroscopy and sensing. Trimers offer a richer spectrum of options for coupling between particles, which can be analyzed using group theory to obtain the plasmonic modes, in analogy to vibrational modes. Symmetry plays an important role in our understanding of the physics of plasmonic dimers and trimers, and new physical phenomena may appear when the symmetry of a dimer or a trimer is broken, including directional emission, Fano resonances, plane chirality and more. The review introduces some of these concepts, the basic physics behind them and their possible applications. Focus Point sections describing selected outstanding recent developments accompany the review.
ISSN:1389-5567
1873-2739
DOI:10.1016/j.jphotochemrev.2014.10.002