Abstract
Time-resolved in situ characterization of well-defined mixing processes using small-angle X-ray scattering (SAXS) is usually challenging, especially if the process involves changes of material viscoelasticity. In specific, it can be difficult to create a continuous mixing experiment without shearing the material of interest; a desirable situation since shear flow both affects nanoscale structures and flow stability as well as resulting in unreliable time-resolved data. Here, we demonstrate a flow-focusing mixing device for in situ nanostructural characterization using scanning-SAXS. Given the interfacial tension and viscosity ratio between core and sheath fluids, the core material confined by sheath flows is completely detached from the walls and forms a zero-shear plug flow at the channel center, allowing for a trivial conversion of spatial coordinates to mixing times. With this technique, the time-resolved gel formation of dispersed cellulose nanocrystals (CNCs) was studied by mixing with a sodium chloride solution. It is observed how locally ordered regions, so called tactoids, are disrupted when the added monovalent ions affect the electrostatic interactions, which in turn leads to a loss of CNC alignment through enhanced rotary diffusion. The demonstrated flow-focusing scanning-SAXS technique can be used to unveil important kinetics during structural formation of nanocellulosic materials. However, the same technique is also applicable in many soft matter systems to provide new insights into the nanoscale dynamics during mixing.
Highlights
100 nm, which has been widely adopted in material, medical, biological and chemical sciences.[1]
The main purpose of this work is to demonstrate how timeresolved nanoscale structural transitions can be characterized by combining shear-free flow-focusing mixing and scanningSAXS
Owing to the large viscosity difference between the core and the sheath fluids, a plug flow with a uniform velocity profile is formed in the core, which allows for mixing only through diffusion without shear
Summary
100 nm, which has been widely adopted in material, medical, biological and chemical sciences.[1]. The combination of SAXS with various mixing experiments has already been seen as a powerful tool to obtain timeresolved transitions including kinetics of RNA or protein folding.[20,21,22] Resolving the structural kinetics in traditional mixing experiments using stopped-flow techniques[23] is inherently problematic because the influence of the radiation
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