DNA Origami Colloidal Crystals: Opportunities and Challenges

Jaewon Lee; Jangwon Kim; Gregor Posnjak; Anastasia Ershova; Daichi Hayakawa; William M. Shih; W. Benjamin Rogers; Yonggang Ke; Tim Liedl; Seungwoo Lee

doi:10.1021/acs.nanolett.4c05041

DNA Origami Colloidal Crystals: Opportunities and Challenges

Jaewon Lee, Jangwon Kim, Gregor Posnjak, Anastasia Ershova, Daichi Hayakawa, William M. Shih, W. Benjamin Rogers, Yonggang Ke, Tim Liedl, Seungwoo Lee

KU-KIST Graduate School of Converging Science and Technology

Research output: Contribution to journal › Review article › peer-review

3 Citations (Scopus)

Abstract

Over the last three decades, colloidal crystallization has provided an easy-to-craft platform for mesoscale engineering of photonic and phononic crystals. Nevertheless, the crystal lattices achieved thus far with commodity colloids are largely limited to symmetric and densely packed structures, restricting their functionalities. To obtain non-close-packed crystals and the resulting complexity of the available structures, directional binding between “patchy” colloids has been pursued. However, the conventional “patchy” colloids have been restricted to micrometer-scale spherical particles or clusters. In this Mini-Review, we argue that the time has come to widen the scope of the colloidal palette and include particles made using DNA origami. By benefiting from its unprecedented ability to control nanoscale shapes and patch placement and incorporate various nanomaterials, DNA origami enables novel engineering of colloidal crystallization, particularly for photonic and phononic applications. This mini-review summarizes the recent progress on using DNA origami for colloidal crystallization, together with its challenges and opportunities.

Original language	English
Pages (from-to)	16-27
Number of pages	12
Journal	Nano Letters
Volume	25
Issue number	1
DOIs	https://doi.org/10.1021/acs.nanolett.4c05041
Publication status	Published - 2025 Jan 8

Bibliographical note

Publisher Copyright:
© 2024 American Chemical Society.

Keywords

DNA origami
colloidal crystals
colloids
lattice engineering
self-assembly

ASJC Scopus subject areas

Bioengineering
General Chemistry
General Materials Science
Condensed Matter Physics
Mechanical Engineering

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10.1021/acs.nanolett.4c05041

Cite this

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title = "DNA Origami Colloidal Crystals: Opportunities and Challenges",

abstract = "Over the last three decades, colloidal crystallization has provided an easy-to-craft platform for mesoscale engineering of photonic and phononic crystals. Nevertheless, the crystal lattices achieved thus far with commodity colloids are largely limited to symmetric and densely packed structures, restricting their functionalities. To obtain non-close-packed crystals and the resulting complexity of the available structures, directional binding between “patchy” colloids has been pursued. However, the conventional “patchy” colloids have been restricted to micrometer-scale spherical particles or clusters. In this Mini-Review, we argue that the time has come to widen the scope of the colloidal palette and include particles made using DNA origami. By benefiting from its unprecedented ability to control nanoscale shapes and patch placement and incorporate various nanomaterials, DNA origami enables novel engineering of colloidal crystallization, particularly for photonic and phononic applications. This mini-review summarizes the recent progress on using DNA origami for colloidal crystallization, together with its challenges and opportunities.",

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AU - Lee, Jaewon

AU - Kim, Jangwon

AU - Posnjak, Gregor

AU - Ershova, Anastasia

AU - Hayakawa, Daichi

AU - Shih, William M.

AU - Rogers, W. Benjamin

AU - Ke, Yonggang

AU - Liedl, Tim

AU - Lee, Seungwoo

PY - 2025/1/8

Y1 - 2025/1/8

N2 - Over the last three decades, colloidal crystallization has provided an easy-to-craft platform for mesoscale engineering of photonic and phononic crystals. Nevertheless, the crystal lattices achieved thus far with commodity colloids are largely limited to symmetric and densely packed structures, restricting their functionalities. To obtain non-close-packed crystals and the resulting complexity of the available structures, directional binding between “patchy” colloids has been pursued. However, the conventional “patchy” colloids have been restricted to micrometer-scale spherical particles or clusters. In this Mini-Review, we argue that the time has come to widen the scope of the colloidal palette and include particles made using DNA origami. By benefiting from its unprecedented ability to control nanoscale shapes and patch placement and incorporate various nanomaterials, DNA origami enables novel engineering of colloidal crystallization, particularly for photonic and phononic applications. This mini-review summarizes the recent progress on using DNA origami for colloidal crystallization, together with its challenges and opportunities.

AB - Over the last three decades, colloidal crystallization has provided an easy-to-craft platform for mesoscale engineering of photonic and phononic crystals. Nevertheless, the crystal lattices achieved thus far with commodity colloids are largely limited to symmetric and densely packed structures, restricting their functionalities. To obtain non-close-packed crystals and the resulting complexity of the available structures, directional binding between “patchy” colloids has been pursued. However, the conventional “patchy” colloids have been restricted to micrometer-scale spherical particles or clusters. In this Mini-Review, we argue that the time has come to widen the scope of the colloidal palette and include particles made using DNA origami. By benefiting from its unprecedented ability to control nanoscale shapes and patch placement and incorporate various nanomaterials, DNA origami enables novel engineering of colloidal crystallization, particularly for photonic and phononic applications. This mini-review summarizes the recent progress on using DNA origami for colloidal crystallization, together with its challenges and opportunities.

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DNA Origami Colloidal Crystals: Opportunities and Challenges

Abstract

Bibliographical note

Keywords

ASJC Scopus subject areas

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