Our research focuses on studying the multipole Mie resonances
that
are excited within the antennas of transition-metal carbides and nitrides
(MXenes), particularly focusing on Ti3C2T
x
MXene as an array component. Through analytical
models, numerical simulations, and experimental characterizations,
we explore how collective resonances of the lossy nanostructures,
such as MXene or lossy metals, lead to absorption enhancement, reflection
suppression, and 2π variations of phase for the transmitted
signal. Analytical models provide insights into the nature of the
optical resonances excited in the antenna array, allowing for the
identification of the strongest multipole and designing the antenna
array accordingly. This study presents experimental measurements of
the near-infrared reflection from a titanium antenna array, highlighting
the emergence of a generalized Kerker effect due to multipole scattering
compensation. The well-pronounced and optically responsive collective
multipole resonances in nanostructured MXene enable metasurfaces with
broad bandwidth absorption, using its large permittivity and scattering
enhancement to improve light conversion efficiency in large-scale
energy-harvesting systems.