TY - JOUR
T1 - Structure, stability, and formation pathways of colloidal gels in systems with short-range attraction and long-range repulsion
AU - van Schooneveld, M.M.
AU - de Villeneuve, V.W.A.
AU - Dullens, R.P.A.
AU - Aarts, D.G.
AU - Leunissen, M.E.
AU - Kegel, W.K.
PY - 2009
Y1 - 2009
N2 - We study colloidal gels formed upon centrifugation of dilute suspensions of spherical colloids (radius 446
nm) that interact through a long-range electrostatic repulsion (Debye length ≈ 850 nm) and a short-range
depletion attraction (∼12.5 nm), by means of confocal scanning laser microscopy (CSLM). In these systems,
at low colloid densities, colloidal clusters are stable. Upon increasing the density by centrifugation, at different
stages of cluster formation, we show that colloidal gels are formed that significantly differ in structure. While
significant single-particle displacements do not occur on the hour time scale, the different gels slowly evolve
within several weeks to a similar structure that is at least stable for over a year. Furthermore, while reference
systems without long-range repulsion collapse into dense glassy states, the repulsive colloidal gels are able
to support external stress in the form of a centrifugal field of at least 9g.
AB - We study colloidal gels formed upon centrifugation of dilute suspensions of spherical colloids (radius 446
nm) that interact through a long-range electrostatic repulsion (Debye length ≈ 850 nm) and a short-range
depletion attraction (∼12.5 nm), by means of confocal scanning laser microscopy (CSLM). In these systems,
at low colloid densities, colloidal clusters are stable. Upon increasing the density by centrifugation, at different
stages of cluster formation, we show that colloidal gels are formed that significantly differ in structure. While
significant single-particle displacements do not occur on the hour time scale, the different gels slowly evolve
within several weeks to a similar structure that is at least stable for over a year. Furthermore, while reference
systems without long-range repulsion collapse into dense glassy states, the repulsive colloidal gels are able
to support external stress in the form of a centrifugal field of at least 9g.
M3 - Article
SN - 1520-6106
VL - 113
SP - 4560
EP - 4564
JO - Journal of Physical Chemistry. B
JF - Journal of Physical Chemistry. B
IS - 14
ER -