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Colloid crystal self-organization and dynamics at the air/water interface

H. Hollis Wickman () and Julius N. Korley
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H. Hollis Wickman: Center for BioMolecular Science and Engineering, Naval Research Laboratory
Julius N. Korley: National Science Foundation

Nature, 1998, vol. 393, issue 6684, 445-447

Abstract: Abstract The properties of two-dimensional arrays of micrometre-sized particles are of interest in relation to a wide range of phenomena, including self-organization and phase behaviour in colloid science and condensed-matter physics1,2,3, the behaviour of dusty plasmas4 and the templating of ordered structures for photonic applications5. Most studies have used pre-existing particles such as monodisperse latex spheres, which may be manipulated with electric or magnetic fields. In contrast, we report here an inorganic solution that spontaneously precipitates a self-organized two-dimensional colloid crystal at the air/water interface. A solution of calcium hydroxide exposed to air reacts with dissolved carbon dioxide to precipitate microcrystals of calcium carbonate in the form of calcite. These aggregate at the surface to form a disordered gel mat with fractal characteristics6. We find, however, that in aged solutions a second population of charged microcrystals with the ‘dogtooth spar’ morphology appears on the surface. These crystallites, which can be observed by optical microscopy, become organized into a regular triangular lattice. The competition between electrostatic and capillary forces between particles leads to lattice spacings of the order of 125 to 175 µm, 5 to 7 times the diameter of the particles. These structures are stable for around 24 h, but eventually aggregate with the fractal gel. The mechanism of their self-organization, as yet incompletely understood, might provide some insights into similar phenomena in colloid science2,3,7,8,9.

Date: 1998
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DOI: 10.1038/30930

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