posted on 2017-10-05, 00:00authored byGeorg Haberfehlner, Franz-Philipp Schmidt, Gernot Schaffernak, Anton Hörl, Andreas Trügler, Andreas Hohenau, Ferdinand Hofer, Joachim R. Krenn, Ulrich Hohenester, Gerald Kothleitner
Plasmonic
gap modes provide the ultimate confinement of optical
fields. Demanding high spatial resolution, the direct imaging of these
modes was only recently achieved by electron energy loss spectroscopy
(EELS) in a scanning transmission electron microscope (STEM). However,
conventional 2D STEM-EELS is only sensitive to components of the photonic
local density of states (LDOS) parallel to the electron trajectory.
It is thus insensitive to specific gap modes, a restriction that was
lifted with the introduction of tomographic 3D EELS imaging. Here,
we show that by 3D EELS tomography the gap mode LDOS of a vertically
stacked nanotriangle dimer can be fully imaged. Besides probing the
complete mode spectrum, we demonstrate that the tomographic approach
allows disentangling the signal contributions from the two nanotriangles
that superimpose in a single measurement with a fixed electron trajectory.
Generally, vertically coupled nanoparticles enable the tailoring of
3D plasmonic fields, and their full characterization will thus aid
the development of complex nanophotonic devices.