posted on 2016-01-26, 00:00authored byJana Olson, Alejandro Manjavacas, Tiyash Basu, Da Huang, Andrea E. Schlather, Bob Zheng, Naomi J. Halas, Peter Nordlander, Stephan Link
Chromatic devices
such as flat panel displays could, in principle,
be substantially improved by incorporating aluminum plasmonic nanostructures
instead of conventional chromophores that are susceptible to photobleaching.
In nanostructure form, aluminum is capable of producing colors that
span the visible region of the spectrum while contributing exceptional
robustness, low cost, and streamlined manufacturability compatible
with semiconductor manufacturing technology. However, individual aluminum
nanostructures alone lack the vivid chromaticity of currently available
chromophores because of the strong damping of the aluminum plasmon
resonance in the visible region of the spectrum. In recent work, we
showed that pixels formed by periodic arrays of Al nanostructures
yield far more vivid coloration than the individual nanostructures.
This progress was achieved by exploiting far-field diffractive coupling,
which significantly suppresses the scattering response on the long-wavelength
side of plasmonic pixel resonances. In the present work, we show that
by utilizing another collective coupling effect, Fano interference,
it is possible to substantially narrow the short-wavelength side of the pixel spectral response. Together, these two complementary
effects provide unprecedented control of plasmonic pixel spectral
line shape, resulting in aluminum pixels with far more vivid, monochromatic
coloration across the entire RGB color gamut than previously attainable.
We further demonstrate that pixels designed in this manner can be
used directly as switchable elements in liquid crystal displays and
determine the minimum and optimal numbers of nanorods required in
an array to achieve good color quality and intensity.