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Ionic solids from common colloids

Author

Listed:
  • Theodore Hueckel

    (New York University)

  • Glen M. Hocky

    (New York University)

  • Jeremie Palacci

    (University of California San Diego)

  • Stefano Sacanna

    (New York University)

Abstract

From rock salt to nanoparticle superlattices, complex structure can emerge from simple building blocks that attract each other through Coulombic forces1–4. On the micrometre scale, however, colloids in water defy the intuitively simple idea of forming crystals from oppositely charged partners, instead forming non-equilibrium structures such as clusters and gels5–7. Although various systems have been engineered to grow binary crystals8–11, native surface charge in aqueous conditions has not been used to assemble crystalline materials. Here we form ionic colloidal crystals in water through an approach that we refer to as polymer-attenuated Coulombic self-assembly. The key to crystallization is the use of a neutral polymer to keep particles separated by well defined distances, allowing us to tune the attractive overlap of electrical double layers, directing particles to disperse, crystallize or become permanently fixed on demand. The nucleation and growth of macroscopic single crystals is demonstrated by using the Debye screening length to fine-tune assembly. Using a variety of colloidal particles and commercial polymers, ionic colloidal crystals isostructural to caesium chloride, sodium chloride, aluminium diboride and K4C60 are selected according to particle size ratios. Once fixed by simply diluting out solution salts, crystals are pulled out of the water for further manipulation, demonstrating an accurate translation from solution-phase assembly to dried solid structures. In contrast to other assembly approaches, in which particles must be carefully engineered to encode binding information12–18, polymer-attenuated Coulombic self-assembly enables conventional colloids to be used as model colloidal ions, primed for crystallization.

Suggested Citation

  • Theodore Hueckel & Glen M. Hocky & Jeremie Palacci & Stefano Sacanna, 2020. "Ionic solids from common colloids," Nature, Nature, vol. 580(7804), pages 487-490, April.
    • Handle: RePEc:nat:nature:v:580:y:2020:i:7804:d:10.1038_s41586-020-2205-0
    DOI: 10.1038/s41586-020-2205-0
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    Citations

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    Cited by:

    1. Wenhe Xie & Yuan Ren & Fengluan Jiang & Xin-Yu Huang & Bingjie Yu & Jianhong Liu & Jichun Li & Keyu Chen & Yidong Zou & Bingwen Hu & Yonghui Deng, 2023. "Solvent-pair surfactants enabled assembly of clusters and copolymers towards programmed mesoporous metal oxides," Nature Communications, Nature, vol. 14(1), pages 1-9, December.
    2. Yongyang Song & Jiajia Zhou & Zhongpeng Zhu & Xiaoxia Li & Yue Zhang & Xinyi Shen & Padraic O’Reilly & Xiuling Li & Xinmiao Liang & Lei Jiang & Shutao Wang, 2023. "Heterostructure particles enable omnidispersible in water and oil towards organic dye recycle," Nature Communications, Nature, vol. 14(1), pages 1-12, December.
    3. Dengping Lyu & Wei Xu & Jae Elise L. Payong & Tianran Zhang & Yufeng Wang, 2022. "Low-dimensional assemblies of metal-organic framework particles and mutually coordinated anisotropy," Nature Communications, Nature, vol. 13(1), pages 1-11, December.
    4. Fan Cui & Sophie Marbach & Jeana Aojie Zheng & Miranda Holmes-Cerfon & David J. Pine, 2022. "Comprehensive view of microscopic interactions between DNA-coated colloids," Nature Communications, Nature, vol. 13(1), pages 1-10, December.
    5. Zhihua Cheng & Matthew R. Jones, 2022. "Assembly of planar chiral superlattices from achiral building blocks," Nature Communications, Nature, vol. 13(1), pages 1-11, December.

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