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Template-directed colloidal crystallization

Author

Listed:
  • Alfons van Blaaderen

    (FOM Institute for Atomic and Molecular Physics
    Utrecht University)

  • Rene Ruel

    (Bell Laboratories)

  • Pierre Wiltzius

    (Bell Laboratories)

Abstract

Colloidal crystals are three-dimensional periodic structures formed from small particles suspended in solution. They have important technological uses as optical filters1–3, switches4 and materials with photonic band gaps5,6, and they also provide convenient model systems for fundamental studies of crystallization and melting7–10. Unfortunately, applications of colloidal crystals are greatly restricted by practical difficulties encountered in synthesizing large single crystals with adjustable crystal orientation11. Here we show that the slow sedimentation of colloidal particles onto a patterned substrate (or template) can direct the crystallization of bulk colloidal crystals, and so permit tailoring of the lattice structure, orientation and size of the resulting crystals: we refer to this process as 'colloidal epitaxy'. We also show that, by using silica spheres synthesized with a fluorescent core12,13, the defect structures in the colloidal crystals that result from an intentional lattice mismatch of the template can be studied by confocal microscopy14. We suggest that colloidal epitaxy will open new ways to design and fabricate materials based on colloidal crystals and also allow quantitative studies of heterogeneous crystallization in real space.

Suggested Citation

  • Alfons van Blaaderen & Rene Ruel & Pierre Wiltzius, 1997. "Template-directed colloidal crystallization," Nature, Nature, vol. 385(6614), pages 321-324, January.
  • Handle: RePEc:nat:nature:v:385:y:1997:i:6614:d:10.1038_385321a0
    DOI: 10.1038/385321a0
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    Cited by:

    1. Jooyeun Chong & Changhoon Sung & Kum Seok Nam & Taewon Kang & Hyunjun Kim & Haeseung Lee & Hyunchang Park & Seongjun Park & Jiheong Kang, 2023. "Highly conductive tissue-like hydrogel interface through template-directed assembly," Nature Communications, Nature, vol. 14(1), pages 1-12, December.
    2. Ilya Svetlizky & Seongsoo Kim & David A. Weitz & Frans Spaepen, 2023. "Dislocation interactions during plastic relaxation of epitaxial colloidal crystals," Nature Communications, Nature, vol. 14(1), pages 1-10, December.

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