Microfluidic free interface diffusion: measurement of diffusion coefficients and evidence of interfacial-driven transport phenomena

TL;DR

This paper introduces a microfluidic device for precise measurement of solute diffusion coefficients in water, revealing interfacial-driven transport phenomena like diffusio-phoresis and diffusio-osmosis without affecting the accuracy of diffusion measurements.

Contribution

The study presents a novel microfluidic tool that accurately measures diffusion coefficients across a broad size range and investigates interfacial-driven transport phenomena.

Findings

Measured diffusion coefficients from $10^{-13}$ to $10^{-9}$ m$^2$/s.

Identified diffusio-phoresis and diffusio-osmosis phenomena.

Confirmed these phenomena do not bias diffusion coefficient measurements.

Abstract

We have developed a microfluidic tool to measure the diffusion coefficient $D$ of solutes in an aqueous solution, by following the temporal relaxation of an initially steep concentration gradient in a microchannel. Our chip exploits multilayer soft lithography and the opening of a pneumatic microvalve to trigger the interdiffusion of pure water and the solution initially separated in the channel by the valve, the so-called free interface diffusion technique. Another microvalve at a distance from the diffusion zone closes the channel and thus suppresses convection. Using this chip, we have measured diffusion coefficients of solutes in water with a broad size range, from small molecules to polymers and colloids, with values in the range $D \in [10^{-13}- 10^{-9}]$~m$^2$/s. The same experiments but with added colloidal tracers also revealed diffusio-phoresis and diffusio-osmosis phenomena due to the presence of the solute concentration gradient. We nevertheless show that these interfacial-driven transport phenomena do not affect the measurements of the solute diffusion coefficients in the explored concentration range.