Cavity-Amplified Scattering Spectroscopy Reveals the Dynamics of Proteins and Nanoparticles in Quasi-transparent and Miniature Samples.

Abstract

Dynamic light scattering techniques can give access to the motion spectrum of microscopic objects and are therefore routinely used for numerous industrial and research applications ranging from particle sizing to the characterization of the viscoelastic properties of materials. However, such measurements are impossible when samples do not scatter light enough, i.e., when light undergoes too few scattering events when passing through a sample, either due to excessively small scattering cross sections or due to low concentrations of scatterers. Here, we propose to amplify the light scattering efficiency by placing weakly scattering samples inside a Lambertian cavity with high-reflectance walls. When injected with laser light, the cavity produces a 3D isotropic and homogeneous light field, effectively elongates the photon scattering path length through the sample by 2-3 orders of magnitude, and leads to a dramatic increase in sensitivity. With a 104-fold increase in sensitivity compared to classical techniques, we potentially expand the applications of light scattering to miniaturized microfluidics samples and to weakly scattering samples in general. We show that we can access the short-time dynamics of low-turbidity samples and demonstrate our sensitivity gain by measuring the diffusion coefficient and, therefore, the size of particles ranging from 5 nm to 20 μm with volume fractions as low as 10-9 in volumes as low as 100 μL and in solvents with refractive index mismatches down to Δn ≈ 0.01. Beyond the realm of current applications of light scattering techniques, our cavity-amplified scattering spectroscopy method (CASS) and its high sensitivity represent a significant methodological step toward the study of short-time dynamics problems such as the ballistic limit of Brownian motion, the internal dynamics of proteins, or the dielectric dynamics of liquids.