Journal article

Crossover between entropic and interfacial elasticity and osmotic pressure in uniform disordered emulsions

  • Mason, Thomas G. Department of Physics and Astronomy, University of California-Los Angeles, Los Angeles, USA - Department of Chemistry and Biochemistry, University of California-Los Angeles, Los Angeles, USA
  • Scheffold, Frank Department of Physics, University of Fribourg, Switzerland
    20.08.2014
Published in:
  • Soft Matter. - 2014, vol. 10, no. 36, p. 7109–7116
English We develop a simple predictive model of the osmotic pressure Π and linear shear elastic modulus Gp of uniform disordered emulsions that includes energetic contributions from entropy and interfacial deformation. This model yields a smooth crossover between an entropically dominated GpkBT/a³ for droplet volume fractions ϕ below a jamming threshold for spheres, ϕc, and an interfacially dominated Gpσ/a for ϕ above ϕc, where a and σ are the undeformed radius and interfacial tension, respectively, of a droplet and T is the temperature. We show that this model reduces to the known ϕ-dependent jamming behavior Gp(ϕ) ∼ (σ/a)ϕ(ϕϕc) as T → 0 for ϕ > ϕc of disordered uniform emulsions, and it also produces the known divergence for disordered hard spheres Gp(ϕ) ∼ (kBT/a³)ϕ/(ϕcϕ) for ϕ < ϕc when σ → ∞. We compare predictions of this model to data for disordered uniform microscale emulsion droplets, corrected for electrostatic repulsions. The smooth crossover captures the observed trends in Gp and Π below ϕc better than existing analytic models of disordered emulsions, which do not make predictions below ϕc. Moreover, the model predicts that entropic contributions to the shear modulus can become more significant for nanoemulsions as compared to microscale emulsions.LaMnO₃
Faculty
Faculté des sciences et de médecine
Department
Département de Physique
Language
  • English
Classification
Physics
License
License undefined
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Persistent URL
https://folia.unifr.ch/unifr/documents/303844
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