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Arrested fluid-fluid phase separation in depletion systems: Implications of the characteristic length on gel formation and rheology

  • Conrad, J. C. Department of Physics and SEAS, Harvard University, Cambridge, USA - Department of Chemical and Biomolecular Engineering, University of Houston, USA
  • Wyss, H. M. Department of Physics and SEAS, Harvard University, Cambridge, USA - Eindhoven University of Technology, ICMS & WTB, Eindhoven, the Netherlands
  • Trappe, Véronique Department of Physics, University of Fribourg, Switzerland
  • Manley, S. Department of Physics and SEAS, Harvard University, Cambridge, USA - Institute of Physics of Biological Systems, EPFL, Lausanne, Switzerland
  • Miyazaki, K. Department of Chemistry, Columbia University, New York, USA - Institute of Physics, University of Tsukuba, Japan
  • Kaufman, L. J. Department of Chemistry, Columbia University, New York, USA
  • Schofield, A. B. Department of Physics, University of Edinburgh, Edinburgh United Kingdom
  • Reichman, D. R. Department of Chemistry, Columbia University, New York, USA
  • Weitz, D. A. Department of Physics and SEAS, Harvard University, Cambridge, USA
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    12.04.2010
Published in:
  • Journal of Rheology. - 2010, vol. 54, no. 2, p. 421-438
Colloids
Phase separation
Polymer blends
Polymer gels
Quenching (thermal)
Rheology
Shear modulus
English We investigate the structural, dynamical, and rheological properties of colloid-polymer mixtures in a volume fraction range of Φ=0.15–0.35. Our systems are density-matched, residual charges are screened, and the polymer-colloid size ratio is ~0.37. For these systems, the transition to kinetically arrested states, including disconnected clusters and gels, coincides with the fluid-fluid phase separation boundary. Structural investigations reveal that the characteristic length, L, of the networks is a strong function of the quench depth: for shallow quenches, L is significantly larger than that obtained for deep quenches. By contrast, L is for a given quench depth almost independent of Φ; this indicates that the strand thickness increases with Φ. The strand thickness determines the linear rheology: the final relaxation time exhibits a strong dependence on Φ, whereas the high frequency modulus does not. We present a simple model based on estimates of the strand breaking time and shear modulus that semiquantitatively describes the observed behavior.
Faculty
Faculté des sciences et de médecine
Department
Département de Physique
Language
  • English
Classification
Physics
License
License undefined
Identifiers
Persistent URL
https://folia.unifr.ch/unifr/documents/301521
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