Overcoming light scattering with high optical nonlinearity
Abstract
Achieving high-resolution optical imaging deep within heterogeneous and scattering media remains a fundamental challenge in biological microscopy, where conventional techniques are hindered by multiple light scattering and absorption. Here, we present a non-invasive imaging approach that harnesses the nonlinear response of luminescent labels in conjunction with the statistical and spatial properties of speckle patterns - an effect of random light interference. Using avalanching nanoparticles (ANPs) with strong photoluminescence nonlinearity, we demonstrate that random speckle illumination can be converted into a single, localized, sub-diffraction excitation spot. This spot can be scanned across the sample using the angular memory effect, enabling high-resolution imaging through a scattering layer. Our method is general, fast, and cost-effective. It requires no wavefront shaping, no feedback, and no reconstruction algorithm, offering a powerful new route to deep, high-resolution imaging through complex media.