High-Q localized states in finite arrays of subwavelength resonators

Abstract

We introduce a novel physical mechanism for achieving giant quality factors (Q-factors) in finite-length periodic arrays of subwavelength optical resonators. The underlying physics is based on interference between the band-edge mode and another standing mode in the array, and the formation of spatially localized states with dramatically suppressed radiative losses. We demonstrate this concept for an array of N dipoles with simultaneous cancellation of multipoles up to N-th order and the Q factor growing as Q Nα, where α 6.88. Based on this finding, we propose a realistic array of Mie-resonant nanoparticles (N 29) with a dramatic enhancement of the Purcell factor (up to 3400) achieved by tuning of the array parameters.