Pleats in crystals on curved surfaces

Hexagons can easily tile a flat surface, but not a curved one. Introducing heptagons and pentagons (defects with topological charge) makes it easier to tile curved surfaces; for example, soccer balls based on the geodesic domes of Buckminster Fuller have exactly 12 pentagons (positive charges). Inte...

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Bibliographic Details
Published in:Nature (London) 2010-12, Vol.468 (7326), p.947-951
Main Authors: Irvine, William T. M, Chaikin, Paul M, Vitelli, Vincenzo
Format: Article
Language:English
Subjects:
639/301/930/328/1978
639/638/541/961
Algebraic topology
Composition
defects and impurities
Condensed matter: structure, mechanical and thermal properties
Crystal defects
Crystal structure
Crystallography
Crystals
Curvature
Curved
Dislocations
Evaluation
Exact sciences and technology
Glycerin
Glycerol
Humanities and Social Sciences
letter
Mathematical analysis
multidisciplinary
Nanotechnology
Physics
Properties
Science
Science (multidisciplinary)
Self assembly
Solid surfaces and solid-solid interfaces
Structure
Surface structure and topography
Surfaces and interfaces
thin films and whiskers (structure and nonelectronic properties)
Topology
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Summary:Hexagons can easily tile a flat surface, but not a curved one. Introducing heptagons and pentagons (defects with topological charge) makes it easier to tile curved surfaces; for example, soccer balls based on the geodesic domes of Buckminster Fuller have exactly 12 pentagons (positive charges). Interacting particles that invariably form hexagonal crystals on a plane exhibit fascinating scarred defect patterns on a sphere. Here we show that, for more general curved surfaces, curvature may be relaxed by pleats: uncharged lines of dislocations (topological dipoles) that vanish on the surface and play the same role as fabric pleats. We experimentally investigate crystal order on surfaces with spatially varying positive and negative curvature. On cylindrical capillary bridges, stretched to produce negative curvature, we observe a sequence of transitions-consistent with our energetic calculations-from no defects to isolated dislocations, which subsequently proliferate and organize into pleats; finally, scars and isolated heptagons (previously unseen) appear. This fine control of crystal order with curvature will enable explorations of general theories of defects in curved spaces. From a practical viewpoint, it may be possible to engineer structures with curvature (such as waisted nanotubes and vaulted architecture) and to develop novel methods for soft lithography and directed self-assembly.
ISSN:0028-0836
1476-4687
DOI:10.1038/nature09620