Multiscale transitional flow in anisotropic nanoparticle suspensions revealed by time-resolved x-ray scatter microscopy

TL;DR

This study uses advanced time-resolved x-ray microscopy to reveal how anisotropic nanoparticles behave differently from the macroscopic flow patterns in complex fluids undergoing flow transitions, highlighting multiscale dynamics.

Contribution

It introduces a novel combination of x-ray scatter microscopy and polarized light imaging to analyze nanoparticle dynamics across scales in flow stability experiments.

Findings

Platelet-like particles follow macroscopic flow patterns.

Rod-like particles exhibit high-frequency, uncorrelated motion.

Different nanoparticle shapes lead to distinct flow behaviors.

Abstract

Complex fluids transition from laminar to transitory flow above a critical control parameter, akin to their Newtonian counterparts. In a continuum mechanics sense, fluid elements follow the ensuing complex trajectories, giving rise to secondary flows in terms of macroscopic vortices and patterns thereof. However, if we replace idealized fluid elements with actual anisotropic nanoparticles, would their trajectories still reveal the same spatiotemporal behavior as the macroscopic flow field? This question is fundamental for complex fluids, where fully developed turbulence is suppressed by high viscosities and where understanding particle-flow coupling is central to transport, processing, and structure formation. To address this question, we develop small-angle x-ray scatter microscopy of unprecedented temporal resolution combined with polarized light imaging, thereby bridging seven orders of magnitude in lengtscales. Proof-of-principle is demonstrated on a classical stability problem, Taylor-Couette flow, of platelet-like graphene oxide nanoparticle and rod-like cellulose nanocrystal suspensions. The analysis shows hitherto hidden, markedly different multiscale dynamics underlying flow stability; while the platelet-like particles follow the wavy motion of the macroscopic, secondary flow field, the rod-like particles exhibit high-frequency motion that is uncorrelated with the vortex instabilities.