posted on 2012-06-19, 00:00authored byRuben Esteban, Richard W. Taylor, Jeremy
J. Baumberg, Javier Aizpurua
Self-assembled clusters of metallic nanoparticles separated
by
nanometric gaps generate strong plasmonic modes that support both
intense and localized near fields. These find use in many ultrasensitive
chemical and biological sensing applications through surface enhanced
Raman scattering (SERS). The inability to control at the nanoscale
the structure of the clusters on which the optical response crucially
depends, has led to the development of general descriptions to model
the various morphologies fabricated. Here, we use rigorous electrodynamic
calculations to study clusters formed by a hundred nanospheres that
are separated by ∼1 nm distance, set by the dimensions of the
macrocyclic molecular linker employed experimentally. Three-dimensional
(3D) cluster structures of moderate compactness are of special interest
since they resemble self-assembled clusters grown under typical diffusion-limited
aggregation conditions. We find very good agreement between the simulated
and measured far-field extinction spectra, supporting the equivalence
of the assumed and experimental morphologies. From these results we
argue that the main features of the optical response of two- and three-dimensional
clusters can be understood in terms of the excitation of simple units
composed of different length resonant chains. Notably, we observe
a qualitative difference between short- and long-chain modes in both
spectral response and spatial distribution: dimer and short-chain
modes are observed in the periphery of the cluster at higher energies,
whereas inside the structure longer chain excitation occurs at lower
energies. We study in detail different configurations of isolated
one-dimensional chains as prototypical building blocks for large clusters,
showing that the optical response of the chains is robust to disorder.
This study provides an intuitive understanding of the behavior of
very complex aggregates and may be generalized to other types of aggregates
and systems formed by large numbers of strongly interacting particles.