Popis: |
Collective diffusion, characterised by the collective diffusion coefficient $D_\mathrm{coll}$, is a key quantity for describing the macroscopic transport properties of soft matter systems. However, measuring $D_\mathrm{coll}$ is a fundamental experimental and numerical challenge, as it either relies on nonequilibrium techniques that are hard to interpret or on Fourier-based approaches at equilibrium which are fraught with difficulties associated with Fourier transforms. In this work, we present a novel approach to measure collective diffusion properties by analysing the statistics of particle number counts $N(t)$ in virtual observation boxes of an image at equilibrium, a method we term the "Countoscope". By investigating the equilibrium diffusive dynamics of a 2D colloidal suspension experimentally and numerically, we demonstrate this method can accurately measure $D_\mathrm{coll}$. We validate our results against Fourier-based approaches and establish best practices for measuring $D_\mathrm{coll}$ using fluctuating counts. Remarkably, Fourier techniques struggle with long-range collective measurements because of the non-periodic nature of an experimental image, yet counting fully exploits this property by deliberately using finite observation windows. Finally, we discuss the potential of our method to advance our understanding of collective properties in suspensions, particularly the role of hydrodynamic interactions. |