Affordable Access

Publisher Website

Yielding, thixotropy, and strain stiffening of aqueous carbon black suspensions

Authors
  • N'GOUAMBA, Elie Merveille
  • GOYON, Julie
  • TOCQUER, Laurent
  • OERTHER, Thomas
  • COUSSOT, Philippe
Publication Date
Jan 01, 2020
Identifiers
DOI: 10.1122/8.0000028
OAI: oai:cadic-ifsttar-oai.fr:hal-03249736
Source
Portail Documentaire MADIS
Keywords
License
Unknown
External links

Abstract

We study experimentally the rheological behavior of carbon black (CB) suspensions in water, at different ionic strengths and concentrations. We show by means of standard rheometry completed by local MRI-rheometry that these suspensions first appear to be thixotropic yield stress fluids: they exhibit a yield stress increasing with the time of rest, their apparent viscosity decreases under shear, and a viscosity bifurcation occurs around the yield stress, the fluid evolving either towards stoppage or to steady flow at a large shear rate for a small stress change. Then an original effect appears when we follow the mechanical state of the material in the solid regime by measuring its apparent elastic modulus at small deformation during a creep test under various stresses. In contrast with various other yield stress fluids for which the elastic modulus under small deformation appear to be constant for any deformation in the solid regime, for CB suspensions this modulus widely increases while deformation increases up to yielding. We suggest that this strain stiffening effect finds its origin in the specificities of the (van der Waals) interactions and of the (rough) structure (aggregates) of the particles: the slight relative rotation of particles in contact due to deformation would on average tend to increase the net area of contact between particles, which stiffens the whole material structure. This is supported by the observation that the relative increase of elastic modulus is approximately proportional to sample deformation whatever the material characteristics (ionic force, concentration) and whatever the deformation history.

Report this publication

Statistics

Seen <100 times