Diamond-lattice photonic crystals assembled from DNA origami

Gregor Posnjak; Xin Yin; Paul Butler; Oliver Bienek; Mihir Dass; Seungwoo Lee; Ian D. Sharp; Tim Liedl

doi:10.1126/science.adl2733

Diamond-lattice photonic crystals assembled from DNA origami

Gregor Posnjak, Xin Yin, Paul Butler, Oliver Bienek, Mihir Dass, Seungwoo Lee, Ian D. Sharp, Tim Liedl

Chair of Experimental Semiconductor Physics (2017 — 2024)

Research output: Contribution to journal › Article › peer-review

40 Scopus citations

Abstract

Colloidal self-assembly allows rational design of structures on the micrometer and submicrometer scale. One architecture that can generate complete three-dimensional photonic bandgaps is the diamond cubic lattice, which has remained difficult to realize at length scales comparable with the wavelength of visible or ultraviolet light. In this work, we demonstrate three-dimensional photonic crystals self-assembled from DNA origami that act as precisely programmable patchy colloids. Our DNA-based nanoscale tetrapods crystallize into a rod-connected diamond cubic lattice with a periodicity of 170 nanometers. This structure serves as a scaffold for atomic-layer deposition of high–refractive index materials such as titanium dioxide, yielding a tunable photonic bandgap in the near-ultraviolet.

Original language	English
Pages (from-to)	781-785
Number of pages	5
Journal	Science
Volume	384
Issue number	6697
DOIs	https://doi.org/10.1126/science.adl2733
State	Published - 17 May 2024

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AU - Posnjak, Gregor

AU - Yin, Xin

AU - Butler, Paul

AU - Bienek, Oliver

AU - Dass, Mihir

AU - Lee, Seungwoo

AU - Sharp, Ian D.

AU - Liedl, Tim

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AB - Colloidal self-assembly allows rational design of structures on the micrometer and submicrometer scale. One architecture that can generate complete three-dimensional photonic bandgaps is the diamond cubic lattice, which has remained difficult to realize at length scales comparable with the wavelength of visible or ultraviolet light. In this work, we demonstrate three-dimensional photonic crystals self-assembled from DNA origami that act as precisely programmable patchy colloids. Our DNA-based nanoscale tetrapods crystallize into a rod-connected diamond cubic lattice with a periodicity of 170 nanometers. This structure serves as a scaffold for atomic-layer deposition of high–refractive index materials such as titanium dioxide, yielding a tunable photonic bandgap in the near-ultraviolet.

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Diamond-lattice photonic crystals assembled from DNA origami

Abstract

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