Effect of external electric fields on the phase behavior of colloidal silica rods

Anke Kuijk; Thomas Troppenz; Laura Filion; Arnout Imhof; René Van Roij; Marjolein Dijkstra; Alfons Van Blaaderen

doi:10.1039/c4sm00957f

Effect of external electric fields on the phase behavior of colloidal silica rods

Anke Kuijk
, Thomas Troppenz
, Laura Filion
, Arnout Imhof
, René Van Roij
, Marjolein Dijkstra
, Alfons Van Blaaderen^*

^*Corresponding author for this work

Utrecht University

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

We examine the effect of external electric fields on the behavior of colloidal silica rods. We find that the electric fields can be used to induce para-nematic and para-smectic phases, and to reduce the number of defects in smectic phases. At high field strengths, a new crystal structure was observed that consisted of strings of rods ordered in a hexagonal pattern in which neighboring rods were shifted along their length. We also present a simple model to describe this system, which we used in computer simulations to calculate the phase diagram for rods of L/D = 6, with L the end-to-end length of the rods and D the diameter of the rods. Our theoretical predictions for the phase behavior agree well with the experimental observations. This journal is

Original language	English
Pages (from-to)	6249-6255
Number of pages	7
Journal	Soft Matter
Volume	10
Issue number	33
DOIs	https://doi.org/10.1039/c4sm00957f
Publication status	Published - 7 Sept 2014

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abstract = "We examine the effect of external electric fields on the behavior of colloidal silica rods. We find that the electric fields can be used to induce para-nematic and para-smectic phases, and to reduce the number of defects in smectic phases. At high field strengths, a new crystal structure was observed that consisted of strings of rods ordered in a hexagonal pattern in which neighboring rods were shifted along their length. We also present a simple model to describe this system, which we used in computer simulations to calculate the phase diagram for rods of L/D = 6, with L the end-to-end length of the rods and D the diameter of the rods. Our theoretical predictions for the phase behavior agree well with the experimental observations. This journal is",

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AU - Kuijk, Anke

AU - Troppenz, Thomas

AU - Filion, Laura

AU - Imhof, Arnout

AU - Van Roij, René

AU - Dijkstra, Marjolein

AU - Van Blaaderen, Alfons

PY - 2014/9/7

Y1 - 2014/9/7

N2 - We examine the effect of external electric fields on the behavior of colloidal silica rods. We find that the electric fields can be used to induce para-nematic and para-smectic phases, and to reduce the number of defects in smectic phases. At high field strengths, a new crystal structure was observed that consisted of strings of rods ordered in a hexagonal pattern in which neighboring rods were shifted along their length. We also present a simple model to describe this system, which we used in computer simulations to calculate the phase diagram for rods of L/D = 6, with L the end-to-end length of the rods and D the diameter of the rods. Our theoretical predictions for the phase behavior agree well with the experimental observations. This journal is

AB - We examine the effect of external electric fields on the behavior of colloidal silica rods. We find that the electric fields can be used to induce para-nematic and para-smectic phases, and to reduce the number of defects in smectic phases. At high field strengths, a new crystal structure was observed that consisted of strings of rods ordered in a hexagonal pattern in which neighboring rods were shifted along their length. We also present a simple model to describe this system, which we used in computer simulations to calculate the phase diagram for rods of L/D = 6, with L the end-to-end length of the rods and D the diameter of the rods. Our theoretical predictions for the phase behavior agree well with the experimental observations. This journal is

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SP - 6249

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JO - Soft Matter

JF - Soft Matter

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Effect of external electric fields on the phase behavior of colloidal silica rods

Abstract

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