TY - JOUR
T1 - Experimental Study on Localized Surface Plasmon Mode Hybridization in the Near and Mid Infrared
AU - Srajer, Johannes
AU - Schwaighofer, Andreas
AU - Ramer, Georg
AU - Frank, Pinar
AU - Lendl, Bernhard
AU - Nowak, Christoph
PY - 2014
Y1 - 2014
N2 - We investigate plasmon excitations within a regular grating of double-layered gold/insulator nanoparticles in the infrared and visible spectral region. Provided a flat gold film as substrate, strong coupling between the localized surface plasmon modes and their image-like excitations in the metal is observed. The interaction results in a strong red shift of the plasmon mode as well as the splitting of the modes into Levels of different angular momenta, often referred to as Plasmon hybridization. The diameters of the nanoparticles are designed in a way that the splitting of the resonances occurs in the
spectral region between 0.1 and 1 eV, thus being accessible using an infrared microscope. Moreover, we investigated the infrared absorption signal of gratings that contain two differently sized nanoparticles. The interaction between two autonomous localized surface plasmon excitations is investigated by analyzing their crossing behavior. In contrast to the interaction between localized surface plasmons and propagating plasmon excitations which results in pronounced anticrossing, the presented structures show no interaction between two autonomous localized surface plasmons. Finally, plasmon
excitations of the nanostructured surfaces in the visible spectral
region are demonstrated through photographs acquired at three different illumination angles. The change in color of the gratings demonstrates the complex interaction between propagating and localized surface plasmon modes.
AB - We investigate plasmon excitations within a regular grating of double-layered gold/insulator nanoparticles in the infrared and visible spectral region. Provided a flat gold film as substrate, strong coupling between the localized surface plasmon modes and their image-like excitations in the metal is observed. The interaction results in a strong red shift of the plasmon mode as well as the splitting of the modes into Levels of different angular momenta, often referred to as Plasmon hybridization. The diameters of the nanoparticles are designed in a way that the splitting of the resonances occurs in the
spectral region between 0.1 and 1 eV, thus being accessible using an infrared microscope. Moreover, we investigated the infrared absorption signal of gratings that contain two differently sized nanoparticles. The interaction between two autonomous localized surface plasmon excitations is investigated by analyzing their crossing behavior. In contrast to the interaction between localized surface plasmons and propagating plasmon excitations which results in pronounced anticrossing, the presented structures show no interaction between two autonomous localized surface plasmons. Finally, plasmon
excitations of the nanostructured surfaces in the visible spectral
region are demonstrated through photographs acquired at three different illumination angles. The change in color of the gratings demonstrates the complex interaction between propagating and localized surface plasmon modes.
KW - Surface enhancement; Plasmon excitation; Localized surface plasmon;Plasmon hybridization; IR spectroscopy
KW - Surface enhancement; Plasmon excitation; Localized surface plasmon;Plasmon hybridization; IR spectroscopy
U2 - 10.1007/s11468-014-9690-7
DO - 10.1007/s11468-014-9690-7
M3 - Article
SN - 1557-1955
VL - 9
SP - 707
EP - 713
JO - Plasmonics
JF - Plasmonics
ER -