TY - JOUR
T1 - Magnetic field effects on tactoids of plate-like colloids
AU - Verhoeff, A.A.
AU - Otten, R.H.J.
AU - van der Schoot, P. P. A. M.
AU - Lekkerkerker, H.N.W.
PY - 2011
Y1 - 2011
N2 - We investigate the effect of a magnetic field on the shape and director field of nematic droplets in
dispersions of sterically stabilized and charge-stabilized colloidal gibbsite platelets with a negative
diamagnetic anisotropy. Depending on the magnetic field strength and tactoid size, we observe with
polarized light microscopy several interesting structures, with different shapes and director fields
both with and without defects. In particular, our findings provide the first experimental evidence for
the existence of the split-core defect structure predicted ten years ago by Mkaddem and Gartland
[Phys. Rev. E 62, 6694 (2000)]. The split-core structure is a metastable director-field configuration
that can be stabilized by a sufficiently strong externally applied magnetic field but only if the
diamagnetic anisotropy of the particles is negative. To account for our observations, we present a
calculation of the stability regions of different shapes and director-field structures as a function of
tactoid size, anchoring conditions, surface tension, elastic constants, and magnetic field strength. By
fitting the experimental data to the theoretically predicted structures, we are able to extract values for
the splay elastic constant, interfacial tension, and anchoring strength. Remarkably, we find significant
differences between the two systems studied: for sterically stabilized gibbsite in bromotoluene
the anchoring strength is one order of magnitude larger than that of aqueous gibbsite, with the latter
exhibiting weak and the former strong anchoring of the director field to the interface. The splay elastic
constants that we obtain are in agreement with earlier experiments, simulations, and theory, while
the interfacial tension and anchoring strength are considerably larger than what was found in earlier
experiments.
AB - We investigate the effect of a magnetic field on the shape and director field of nematic droplets in
dispersions of sterically stabilized and charge-stabilized colloidal gibbsite platelets with a negative
diamagnetic anisotropy. Depending on the magnetic field strength and tactoid size, we observe with
polarized light microscopy several interesting structures, with different shapes and director fields
both with and without defects. In particular, our findings provide the first experimental evidence for
the existence of the split-core defect structure predicted ten years ago by Mkaddem and Gartland
[Phys. Rev. E 62, 6694 (2000)]. The split-core structure is a metastable director-field configuration
that can be stabilized by a sufficiently strong externally applied magnetic field but only if the
diamagnetic anisotropy of the particles is negative. To account for our observations, we present a
calculation of the stability regions of different shapes and director-field structures as a function of
tactoid size, anchoring conditions, surface tension, elastic constants, and magnetic field strength. By
fitting the experimental data to the theoretically predicted structures, we are able to extract values for
the splay elastic constant, interfacial tension, and anchoring strength. Remarkably, we find significant
differences between the two systems studied: for sterically stabilized gibbsite in bromotoluene
the anchoring strength is one order of magnitude larger than that of aqueous gibbsite, with the latter
exhibiting weak and the former strong anchoring of the director field to the interface. The splay elastic
constants that we obtain are in agreement with earlier experiments, simulations, and theory, while
the interfacial tension and anchoring strength are considerably larger than what was found in earlier
experiments.
U2 - 10.1063/1.3520389
DO - 10.1063/1.3520389
M3 - Article
SN - 0021-9606
VL - 134
SP - 044904/1-044904/14
JO - Journal of Chemical Physics
JF - Journal of Chemical Physics
ER -