Comparative Simulation Study of Colloidal Gels And Glasses
Open Access
- 19 February 2002
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review Letters
- Vol. 88 (9) , 098301
- https://doi.org/10.1103/physrevlett.88.098301
Abstract
Using computer simulations, we identify the mechanisms causing aggregation and structural arrest of colloidal suspensions interacting with a short-ranged attraction at moderate and high densities. Two different nonergodicity transitions are observed. As the density is increased, a glass transition takes place, driven by excluded volume effects. In contrast, at moderate densities, gelation is approached as the strength of the attraction increases. At high density and interaction strength, both transitions merge, and a logarithmic decay in the correlation function is observed. All of these features are correctly predicted by mode coupling theory.Keywords
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This publication has 21 references indexed in Scilit:
- Glasslike Kinetic Arrest at the Colloidal-Gelation TransitionPhysical Review Letters, 2001
- Kinetic Glass Transition in a Micellar System with Short-Range Attractive InteractionPhysical Review Letters, 2000
- Nonergodicity transitions in colloidal suspensions with attractive interactionsPhysical Review E, 1999
- Delayed sedimentation of transient gels in colloid–polymer mixtures: dark-field observation, rheology and dynamic light scattering studiesFaraday Discussions, 1999
- Rheology of suspensions of weakly attractive particles: Approach to gelationJournal of Rheology, 1998
- Measurement of the self-intermediate scattering function of suspensions of hard spherical particles near the glass transitionPhysical Review E, 1998
- Mesoscopic structure formation in colloidal aggregation and gelationAdvances in Colloid and Interface Science, 1997
- Phase Diagram of a Model Adhesive Hard-Sphere DispersionJournal of Colloid and Interface Science, 1995
- Volume-fraction dependence of elastic moduli and transition temperatures for colloidal silica gelsPhysical Review E, 1993
- Colloidal DispersionsPublished by Cambridge University Press (CUP) ,1989