Design of DNA Origami Diamond Photonic Crystals

Authors
Park, S.H.Park, H.Hur, K.Lee, S.
Issue Date
2020-01
Publisher
American Chemical Society
Citation
ACS Applied Bio Materials, v.3, no.1, pp.747 - 756
Abstract
Self-assembled photonic crystals have proven to be a fascinating class of photonic materials for nonabsorbing structural colorizations over large areas and in diverse relevant applications, including tools for on-chip spectrometers and biosensors, platforms for reflective displays, and templates for energy devices. The most prevalent building blocks for the self-assembly of photonic crystals are spherical colloids and block copolymers (BCPs) because of the generic appeal of these materials, which can be crafted into large-area 3D lattices. However, because of the intrinsic limitations of these structures, these two building blocks are difficult to assemble into a direct rod-connected diamond lattice, which is considered to be a champion photonic crystal. Here, we present a DNA origami-route for a direct rod-connected diamond photonic crystal exhibiting a complete photonic bandgap (PBG) in the visible regime. Using a combination of electromagnetic, phononic, and mechanical numerical analyses, we identify (i) the structural constraints of the 50 megadalton-scale giant DNA origami building blocks that could self-assemble into a direct rod-connected diamond lattice with high accuracy, and (ii) the elastic moduli that are essentials for maintaining lattice integrity in a buffer solution. A solution molding process could enable the transformation of the as-assembled DNA origami lattice into a porous silicon- or germanium-coated composite crystal with enhanced refractive index contrast, in that a champion relative bandwidth for the photonic bandgap (i.e., 0.29) could become possible even for a relatively low volume fraction (i.e., 16 vol %). Copyright ? 2019 American Chemical Society.
Keywords
Block copolymers; Crystal lattices; Diamonds; Display devices; DNA; Elastic moduli; Energy gap; Porous silicon; Refractive index; Sols; Spontaneous emission; Diamond lattices; Diamond photonic crystals; Dna origamis; Effective elastic modulus; On-chip spectrometers; Photonic bandgap (PBG); Self assembled photonic crystals; Structural constraints; Photonic crystals; diamond lattice; DNA origami; effective elastic moduli; photonic bandgap (PBG); photonic crystals
ISSN
2576-6422
URI
https://pubs.kist.re.kr/handle/201004/119178
DOI
10.1021/acsabm.9b01171
Appears in Collections:
KIST Article > 2020
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