Positional control of DNA origami based gold dimer hybrid nanostructures on pre-structured surfaces

authored by: Zhe Liu, Zunhao Wang, Jannik Guckel, Daesung Park, Birka Lalkens, Rainer Stosch, Markus Etzkorn
Abstract: This study explores important parameters for achieving a high-level positional control of DNA-nanoparticle hybrid structures by drop-casting onto a pre-structured silicon surface, in which the active adsorption sites were defined using electron beam lithography. By confining the adsorption sites to the scale of the DNA origami, we create multi-dimensional patterns and study the effect of diffusion and hybrid nanostructure concentration in the liquid on site occupation. We also propose a physical diffusion model that highlights the importance of surface diffusion in facilitating the adsorption of hybrid nanostructure onto active sites, particularly for two and one-dimensional adsorption sites. Our study shows prominent results of the hybrid nanostructure’s selective adsorption, indicating high adsorption efficiency and precise control over the position, as well as the spatial orientation. We anticipate similar results in related systems, both in terms of different surfaces and similar DNA structures. Overall, our findings offer promising prospects for the development of large-scale nanoarrays on micrometer-scale surfaces with nanometer precision and orientation control.
External Organisation(s): Technische Universität Braunschweig
Laboratory for Emerging Nanometrology Braunschweig (LENA)
National Metrology Institute of Germany (PTB)
Type: Article
Journal: NANOTECHNOLOGY
Volume: 34
ISSN: 0957-4484
Publication date: 02.08.2023
Publication status: Published
Peer reviewed: Yes
ASJC Scopus subject areas: Bioengineering, Chemistry(all), Materials Science(all), Mechanics of Materials, Mechanical Engineering, Electrical and Electronic Engineering
Electronic version(s): https://doi.org/10.1088/1361-6528/ace726 (Access: Open)

BibTeX

@article{0061880ffd51424ca9b16da06f795669,
title = "Positional control of DNA origami based gold dimer hybrid nanostructures on pre-structured surfaces",
abstract = "This study explores important parameters for achieving a high-level positional control of DNA-nanoparticle hybrid structures by drop-casting onto a pre-structured silicon surface, in which the active adsorption sites were defined using electron beam lithography. By confining the adsorption sites to the scale of the DNA origami, we create multi-dimensional patterns and study the effect of diffusion and hybrid nanostructure concentration in the liquid on site occupation. We also propose a physical diffusion model that highlights the importance of surface diffusion in facilitating the adsorption of hybrid nanostructure onto active sites, particularly for two and one-dimensional adsorption sites. Our study shows prominent results of the hybrid nanostructure{\textquoteright}s selective adsorption, indicating high adsorption efficiency and precise control over the position, as well as the spatial orientation. We anticipate similar results in related systems, both in terms of different surfaces and similar DNA structures. Overall, our findings offer promising prospects for the development of large-scale nanoarrays on micrometer-scale surfaces with nanometer precision and orientation control.",
keywords = "3D nanoarray, DNA origami nanotechnology, high-resolution lithography, plasmonic nanostructures, positional-controlled adsorption",
author = "Zhe Liu and Zunhao Wang and Jannik Guckel and Daesung Park and Birka Lalkens and Rainer Stosch and Markus Etzkorn",
note = "Funding information: This work was funded by the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) under Germany{\textquoteright}s Excellence Strategy EXC-2123 Quantum Frontiers 390837967, as well as from the state of Lower Saxony under the project QuanTec., Project ID: 76251 (ZN 3820). We acknowledge DFG funding under grant INST 188/452-1 FUGG, the Research Training Group GrK1952, Metrology for Complex Nanosystems (NanoMet), and the Braunschweig International Graduate School of Metrology (B-IGSM).",
year = "2023",
month = aug,
day = "2",
doi = "10.1088/1361-6528/ace726",
language = "English",
volume = "34",
journal = "NANOTECHNOLOGY",
issn = "0957-4484",
publisher = "IOP Publishing Ltd.",
number = "42",
}