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Jamming phase diagram for attractive particles

Author

Listed:
  • V. Trappe

    (Harvard University
    University of Fribourg)

  • V. Prasad

    (Harvard University)

  • Luca Cipelletti

    (Harvard University
    University of Montpellier)

  • P. N. Segre

    (Harvard University
    NASA, Marshall Space Flight Center)

  • D. A. Weitz

    (Harvard University)

Abstract

A wide variety of systems, including granular media, colloidal suspensions and molecular systems, exhibit non-equilibrium transitions from a fluid-like to a solid-like state, characterized solely by the sudden arrest of their dynamics. Crowding or jamming of the constituent particles traps them kinetically, precluding further exploration of the phase space1. The disordered fluid-like structure remains essentially unchanged at the transition. The jammed solid can be refluidized by thermalization, through temperature or vibration, or by an applied stress. The generality of the jamming transition led to the proposal2 of a unifying description, based on a jamming phase diagram. It was further postulated that attractive interactions might have the same effect in jamming the system as a confining pressure, and thus could be incorporated into the generalized description. Here we study experimentally the fluid-to-solid transition of weakly attractive colloidal particles, which undergo markedly similar gelation behaviour with increasing concentration and decreasing thermalization or stress. Our results support the concept of a jamming phase diagram for attractive colloidal particles, providing a unifying link between the glass transition3, gelation4,5 and aggregation6,7,8.

Suggested Citation

  • V. Trappe & V. Prasad & Luca Cipelletti & P. N. Segre & D. A. Weitz, 2001. "Jamming phase diagram for attractive particles," Nature, Nature, vol. 411(6839), pages 772-775, June.
    • Handle: RePEc:nat:nature:v:411:y:2001:i:6839:d:10.1038_35081021
    DOI: 10.1038/35081021
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    Cited by:

    1. Céline Dinet & Alejandro Torres-Sánchez & Roberta Lanfranco & Lorenzo Michele & Marino Arroyo & Margarita Staykova, 2023. "Patterning and dynamics of membrane adhesion under hydraulic stress," Nature Communications, Nature, vol. 14(1), pages 1-11, December.
    2. Mohammad Nabizadeh & Safa Jamali, 2021. "Life and death of colloidal bonds control the rate-dependent rheology of gels," Nature Communications, Nature, vol. 12(1), pages 1-9, December.

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