Spectrally reconfigurable magnetoplasmonic nanoantenna arrays.

We have successfully integrated a rare-earth-transition metal (RE-TM) ferrimagnetic alloy, Tb$_{18}$Co$_{82}$, with strong out-of-plane magnetic anisotropy, within a gold truncated cone-shaped plasmonic nanoantenna. These hybrid three-dimensional magnetoplasmonic nanoantennas are patterned as extended arrays, resulting in a narrow Fano-type resonance, referred to as a surface lattice mode which arises through the interference of a Rayleigh anomaly and the localized surface plasmon, resulting in abrupt spectral features for which the Faraday ellipticity is amplified and changes sign in a narrow ($\approx$ 10 nm) spectral window. This magneto-optical surface lattice mode exhibits significant angular dispersion, and we demonstrate and explain using Maxwell-theory simulations, how its spectral position can be tuned by simply varying the angle of incidence. The design concepts presented here can be utilized for the design of a new generation of magnetoplasmonic angle sensors, as well as for the building blocks of magnetoplasmonic nanoantennas suitable for enhancing the light-matter interaction for all-optical switching of the magnetization in RE-TM ferrimagnetic alloys.