Please use this identifier to cite or link to this item: http://hdl.handle.net/1783.1/6138

Geometric frustration in buckled colloidal monolayers

Authors Han, Yilong
Shokef, Yair
Alsayed, Ahmed M.
Yunker, Peter
Lubensky, Tom C.
Yodh, Arjun G.
Issue Date 2008
Source Nature, v. 456, (7224), 2008, DEC 18, p. 898-903
Summary Geometric frustration arises when lattice structure prevents simultaneous minimization of local interaction energies. It leads to highly degenerate ground states and, subsequently, to complex phases of matter, such as water ice, spin ice, and frustrated magnetic materials. Here we report a simple geometrically frustrated system composed of closely packed colloidal spheres confined between parallel walls. Diameter- tunable microgel spheres are self- assembled into a buckled triangular lattice with either up or down displacements, analogous to an antiferromagnetic Ising model on a triangular lattice. Experiment and theory reveal single- particle dynamics governed by in- plane lattice distortions that partially relieve frustration and produce ground states with zigzagging stripes and subextensive entropy, rather than the more random configurations and extensive entropy of the antiferromagnetic Ising model. This tunable soft- matter system provides a means to directly visualize the dynamics of frustration, thermal excitations and defects.
Subjects
ISSN 0028-0836
Rights The journal's website is located at http://www. nature.com/nature/
Language English
Format Article
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