Q Factors Exceeding 104 in Wavelength-to-Subwavelength-Scale Free-Space Resonators

Abstract

Free-space-addressable optical resonators that combine long photon lifetimes (high Q factors) with strong spatial localization of optical fields (small mode volumes, Vm) enhance light-matter interactions with facile far-field excitation. The Purcell factor governing spontaneous emission enhancement scales as Q\,Vm-1. Periodically asymmetric resonators, in which perturbations convert bound modes into radiating modes, offer a route to free-space resonances, with the radiative Q factor tuned by the geometric and optical strength of the asymmetry-inducing perturbations. However, free-space resonators that simultaneously achieve high Q and small Vm have remained rare. This limitation arises in part because existing designs do not tailor geometric and optical asymmetries concurrently, thus limiting access to high-Q regimes. Here, we show that jointly tuning geometric and optical asymmetries unlocks a biaxial radiative landscape with iso-Q contours that connect disparate perturbations with equivalent Q factors. We demonstrate this framework with very-large-scale-integrated single-crystalline Si nanoantenna pixels (VINPix) with out-of-plane perturbations of 35-150 nm amorphous Si, SiNx, and SiO2. We experimentally establish biaxial Q factor control in air and achieve Q factors up to 76,000 at wavelength-scale mode volumes (Vm 1.7\,λ03\,neff-3) in simultaneously imaged arrays of >80 resonators in water. Furthermore, we computationally demonstrate 50-nm-wide slotted VINPix that reach Q factors of 106 at subwavelength mode volumes (Vm 0.2\,λ03\,neff-3) with 20 nm SiO2 perturbations, yielding Purcell factors as high as 5 × 105 in an all-dielectric free-space resonator.