Transient dynamics of a colloidal particle driven through a viscoelastic fluid

TL;DR

This study investigates the transient recoil dynamics of a colloidal particle in viscoelastic fluids after active dragging, revealing double exponential relaxation that informs on fluid rheology at the microscale.

Contribution

It introduces a novel experimental approach to analyze transient viscoelastic responses using particle recoil dynamics, enabling microscopic rheological measurements.

Findings

Particle recoil exhibits double exponential relaxation.

Relaxation times are independent of initial velocity.

Amplitudes depend strongly on initial velocity.

Abstract

We experimentally study the transient motion of a colloidal particle actively dragged by an optical trap through different viscoelastic fluids (wormlike micelles, polymer solutions, and entangled $\lambda$-phage DNA). We observe that, after sudden removal of the moving trap, the particle recoils due to the recovery of the deformed fluid microstructure. We find that the transient dynamics of the particle proceeds via a double exponential relaxation, whose relaxation times remain independent of the initial particle velocity whereas their amplitudes strongly depend on it. While the fastest relaxation mirrors the viscous damping of the particle by the solvent, the slow relaxation results from the recovery of the strained viscoelastic matrix. We show that this transient information, which has no counterpart in Newtonian fluids, can be exploited to investigate linear and nonlinear rheological properties of the embedding fluid, thus providing a novel method to perform transient rheology at the micron-scale.