Irene Natalia scite author profile

SynopsisWeak attractive interactions lead to a substantial broadening of the fluid-crystalline coexistence region of crystalline, colloidal hard-sphere dispersions. Here, we demonstrate that a weak depletion attraction introduced by nonadsorbing polymer added to the continuous phase results in a strong decrease of the low shear viscosity even at particle concentrations up to U ¼ 0.65 analogous to the re-entry phenomenon in highly concentrated glassy systems. This promotes flow in macroscopic channels but the scenario changes in confined, microfluidic geometries. Pure crystalline suspensions exhibit flow induced melting in the region of highest shear rates close to the wall, and this promotes flow through microchannels (<100 lm). In contrast, weak attractive interactions fortify preferential crystallization at the channel walls finally resulting in channel clogging and cessation of flow. This wall crystallization phenomenon particularly impairs viscosity determination from classical parallel plate rotational rheometry if the gap width is set too low. These findings may find application in the important biotechnological field of protein preparation and crystallization.

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Particle contact dynamics as the origin for noninteger power expansion rheology in attractive suspension networks

Natalia

Ewoldt

Koos

2021

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In medium amplitude oscillatory shear (MAOS), the cubic scaling of the leading order nonlinear shear stress (σ3 ∼ γ m 3 0 , m3 = 3) is the typical expectation. Expanding on the work by Natalia et al. [J. Rheol., 64(3): 625 (2020)], we report non-cubical, non-integer power law scalings m3 for particle suspensions in two immiscible fluids with a capillary attractive interaction, known as capillary suspensions. Here, we show that distinct power law exponents are found for the storage and loss moduli and these non-integer scalings occur at every secondary fluid concentration for two different contact angles. These compelling results indicate that the non-integer scalings are related to the underlying microstructure of capillary suspensions. Weshow that the magnitude of the third harmonic elastic stress scaling m 3,elastic originates from Hertzian-like contacts in combination with the attractive capillary force. The related third harmonic viscous stress scaling m3,viscous is, therefore, associated with adhesive controlled friction. These observations, conducted for a wide range of compositions, can help explain previous reports of non-integer scaling for materials involving particle contacts and offers a new opportunity to study the importance of the particle bonds and friction in the rheological response under low deformation instead of at very high shear rates.

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Negative normal stress differencesN₁–N₂in a low concentration capillary suspension

et al. 2018

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Here, negative normal stress differences are reported in capillary suspensions, i.e. particle suspensions in a two-fluid system that creates strong capillary attractions, at a solid concentration of 25%, and a volume fraction that has heretofore been considered too low to show such normal stress differences. Such capillary suspensions have strong particle networks and are shear thinning for the entire range of shear rates studied. Capillary suspensions exist in two states: a pendular state when the secondary fluid preferentially wets the particles, and a capillary state when the bulk fluid is preferentially wetting. In the pendular state, the system undergoes a transition from a positive normal stress difference at high shear rates to a negative stress difference at low shear rates. These results are an indication of flexible flocs in the pendular state that are able to rotate to reorientate in the vorticity direction under shear. Analogous experiments were also conducted for the capillary state, where only a negative normal stress difference occurs. The capillary state system forms more network contacts due to droplet breakup at higher shear rates, which enhances the importance of hydrodynamic interactions in the non-colloidal suspension.

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Irene Natalia

Questioning a fundamental assumption of rheology: Observation of noninteger power expansions

Effect of weak attractive interactions on flow behavior of highly concentrated crystalline suspensions

Particle contact dynamics as the origin for noninteger power expansion rheology in attractive suspension networks

Negative normal stress differencesN₁–N₂in a low concentration capillary suspension

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Irene Natalia

Questioning a fundamental assumption of rheology: Observation of noninteger power expansions

Effect of weak attractive interactions on flow behavior of highly concentrated crystalline suspensions

Particle contact dynamics as the origin for noninteger power expansion rheology in attractive suspension networks

Negative normal stress differencesN1–N2in a low concentration capillary suspension

Contact Info

Product

Resources

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Negative normal stress differencesN₁–N₂in a low concentration capillary suspension