Single-nanoparticle detection using quasi-bound states in the continuum supported by silicon metasurfaces

TL;DR

This paper demonstrates a silicon metasurface sensor capable of detecting single nanoparticles by exploiting quasi-bound states in the continuum, achieving high sensitivity and enabling single-molecule biosensing.

Contribution

The authors introduce low-contrast BIC metasurfaces that enable single-nanoparticle detection with high Q-factors, overcoming previous limitations in local refractive index sensing.

Findings

Achieved a Q factor of 4.5 x 10^4 in heavy water.

Detected step-like resonance shifts from 100 nm nanoparticles.

Modified resonance linewidth and amplitude for single-particle sensitivity.

Abstract

The detection of single particles or molecules represents a critical milestone in the development of biosensing technologies. Recently developed optical sensors based on quasi-bound states in the continuum (qBICs) have primarily focused on detecting global refractive index changes, aiming to simultaneously enhance both refractive index sensitivity and quality ($Q$) factors. However, sensors capable of resolving local refractive index perturbations, such as the binding of a nanometer-sized molecule on a surface, remain elusive and have not yet been demonstrated in BIC geometries due to the limited $Q$ factors and relatively large mode volumes. Here, we demonstrate low-contrast BIC metasurfaces that can perform sensing with a virus-sized single-nanoparticle resolution. The qBIC resonance operating at the critical coupling condition exhibits an experimental $Q$ factor of 4.5 x 10$^4$ in heavy water. The strong interaction between the localized electric field and polystyrene nanoparticles with a diameter of 100 nm enable the experimental observation of step-like resonance wavelength shifts, serving as signatures of individual particle binding events. Furthermore, binding-induced modifications to the qBIC resonance alter the optical confinement and asymmetry factor, inducing changes not only in the resonance wavelength but also in the linewidth and amplitude with single-particle sensitivity. Combined with position-insensitive response and free-space accessible features, low-contrast BIC metasurfaces provide a user-friendly platform for next-generation single-molecule sensing integrated with microfluidic systems.