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DNA Origami‐Directed Self‐Assembly of Gold Nanospheres for Plasmonic Metasurfaces

Christoph Sikeler, Franziska Haslinger, Irina V. Martynenko, Tim Liedl

2024Advanced Functional Materials28 citationsDOIOpen Access PDF

Abstract

Abstract Plasmonic nanostructures are frequently utilized to create metasurfaces with a large variety of optical effects. Control over shape and positioning of the nanostructures is key to the function of such plasmonic metasurfaces. Next to lithographic means, directed self‐assembly is a viable route to create plasmonic structures on surfaces with the necessary precision. Here, a combined approach of DNA origami self‐assembly and electron beam lithography is presented for determinate positioning of gold nanospheres on a SiO 2 surface. First, DNA origami structures bind to the electron beam‐patterned substrate and subsequently, gold nanoparticles attach to a defined binding site on the DNA origami structure via DNA hybridization. A sol‐gel reaction is then used to grow a silica layer around the DNA, thereby increasing the stability of the self‐assembled metasurface. A mean yield of 74% of single gold nanospheres is achieved located at the determinate positions with a spatial position accuracy of 9 nm. Gold nanosphere dimers and trimers are achieved with a rate of 65% and 60%, respectively. The applicability of this structuring method is demonstrated by the fabrication of metasurfaces whose optical response can be tuned by the polarization of the incoming and the scattered light.

Topics & Concepts

Materials scienceDNA origamiPlasmonNanotechnologySelf-assemblyColloidal goldDNADNA nanotechnologyNanoparticleNanostructureOptoelectronicsBiologyGeneticsAdvanced biosensing and bioanalysis techniquesGold and Silver Nanoparticles Synthesis and ApplicationsPlasmonic and Surface Plasmon Research
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