Quasicrystalline tilings with nematic colloidal platelets

Complex nematic fluids have the remarkable capability for self-assembling regular colloidal structures of various symmetries and dimensionality according to their micromolecular orientational order. Colloidal chains, clusters, and crystals were demonstrated recently, exhibiting soft-matter functiona...

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Bibliographic Details
Published in:Proceedings of the National Academy of Sciences - PNAS 2014-02, Vol.111 (7), p.2464-2469
Main Authors: Dontabhaktuni, Jayasri, Ravnik, Miha, Žumer, Slobodan
Format: Article
Language:English
Subjects:
Boats
Chemical Engineering - methods
Colloids - chemistry
Crystal lattices
Crystal structure
Crystals
Free energy
Liquid crystals
Liquid Crystals - chemistry
mathematical models
Mathematical surfaces
memory
Molecules
Nanoparticles - chemistry
Optics and Photonics - methods
photonics
Physical Sciences
Platelets
Symmetry
Tessellations
Tiles
Tiling
Topology
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Summary:Complex nematic fluids have the remarkable capability for self-assembling regular colloidal structures of various symmetries and dimensionality according to their micromolecular orientational order. Colloidal chains, clusters, and crystals were demonstrated recently, exhibiting soft-matter functionalities of robust binding, spontaneous chiral symmetry breaking, entanglement, shape-driven and topological driven assembly, and even memory imprinting. However, no quasicrystalline structures were found. Here, we show with numerical modeling that quasicrystalline colloidal lattices can be achieved in the form of original Penrose P1 tiling by using pentagonal colloidal platelets in layers of nematic liquid crystals. The tilings are energetically stabilized with binding energies up to 2500 k BT for micrometer-sized platelets and further allow for hierarchical substitution tiling, i.e., hierarchical pentagulation. Quasicrystalline structures are constructed bottom-up by assembling the boat, rhombus, and star maximum density clusters, thus avoiding other (nonquasicrystalline) stable or metastable configurations of platelets. Central to our design of the quasicrystalline tilings is the symmetry breaking imposed by the platelet shape and the surface anchoring conditions at the colloidal platelets, which are misaligning and asymmetric over two perpendicular mirror planes. Finally, the design of the quasicrystalline tilings as platelets in nematic liquid crystals is inherently capable of a continuous variety of length scales of the tiling, ranging over three orders of magnitude in the typical length (from [Formula] to [Formula]), which could allow for the design of quasicrystalline photonics at multiple frequency ranges.
ISSN:0027-8424
1091-6490
DOI:10.1073/pnas.1312670111