DNA-Templated Ultracompact Optical Antennas for Unidirectional Single-Molecule Emission

Zhu, Fangjia; Sanz‐Paz, Maria; Fernández‐Domínguez, Antonio I.; Zhuo, Xiaolu; Liz‐Marzán, Luis M.; Stefani, Fernando D.; Pilo‐Pais, Mauricio; Acuna, Guillermo P.

doi:10.1021/acs.nanolett.2c02424

Cited by 12 publications

(17 citation statements)

References 38 publications

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“…We associate this effect to the dark character of the antiphase mode that governs the response of the NRDA under this particular excitation. The spectral dependence of both the F/B ratio and the radiation efficiency, explain why in the experimental conditions [38] the bandpass filter and fluorescence band of the nanoemitter are matched with the antiphase mode of the NRDA. Otherwise, the maximum directionality would be reduced (see Figure S4).…”

Section: Resultsmentioning

confidence: 90%

“…Recently, we have realized experimentally, for the first time, the directional ultracompact antenna design originally proposed by Pakizeh and Käll [38]. Here, we present a numerical study of the performance of these antennas using Finite Element Method (FEM) simulations on gold nanorods (AuNRs) of sizes and shapes in accordance with our experimental samples.…”

Section: Introductionmentioning

confidence: 79%

“…As will be discussed later, the For the initial FEM far-field simulations, we choose AuNRs with commercially available sizes and similar to the experiments in Ref. [38]: 40 nm diameter (2R), 68 nm length (L) and ideal semi-sphere caps. Distances gap1 and gap2 are set to 5 nm.…”

Section: Resultsmentioning

confidence: 99%

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Optical Ultracompact Directional Antennas Based on a Dimer Nanorod Structure

et al. 2022

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Controlling directionality of optical emitters is of utmost importance for their application in communication and biosensing devices. Metallic nanoantennas have been proven to affect both excitation and emission properties of nearby emitters, including the directionality of their emission. In this regard, optical directional nanoantennas based on a Yagi–Uda design have been demonstrated in the visible range. Despite this impressive proof of concept, their overall size (~λ2/4) and considerable number of elements represent obstacles for the exploitation of these antennas in nanophotonic applications and for their incorporation onto photonic chips. In order to address these challenges, we investigate an alternative design. In particular, we numerically study the performance of a recently demonstrated “ultracompact” optical antenna based on two parallel gold nanorods arranged as a side-to-side dimer. Our results confirm that the excitation of the antiphase mode of the antenna by a nanoemitter placed in its near-field can lead to directional emission. Furthermore, in order to verify the feasibility of this design and maximize the functionality, we study the effect on the directionality of several parameters, such as the shape of the nanorods, possible defects in the dimer assembly, and different positions and orientations of the nanoemitter. We conclude that this design is robust to structural variations, making it suitable for experimental upscaling.

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Section: Resultsmentioning

confidence: 90%

Section: Introductionmentioning

confidence: 79%

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Optical Ultracompact Directional Antennas Based on a Dimer Nanorod Structure

et al. 2022

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“…Nanoemitters transmit photons in all directions since the momentum and position of photons cannot be simultaneously determined due to Heisenberg’s uncertainty principle. This leads to one of fundamental challenges in nanophotonics, how to confine the radiation of a nanoemitter into a desired direction and improve its coupling efficiency in miniaturized photonic devices, such as light emission devices, , single photon sources , and bio/chem-sensors. , To address the above challenge, researchers borrowed the idea of an antenna in the radio frequency − and developed a variety of optical antennas to control the optical properties of nanoemitters. , Particularly, by placing a nanoemitter at the feed point of an optical antenna, one can direct its emission into predefined directions with a high efficiency. ,− …”

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confidence: 99%

Smart Magnetic Optical Antenna for Automatic Nanoalignment and Photon Beaming from Prepatterned Single Quantum Dot Nanospot

et al. 2023

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We present a unidirectional dielectric optical antenna, which can be chemically synthesized and controlled by magnetic fields. By applying magnetic fields, we successfully aligned an optical antenna on a prepatterned quantum dot nanospot with accuracy better than 40 nm. It confined the fluorescence emission into a 16-degree wide beam and enhanced the signal by 11.8 times. Moreover, the position of the antenna, and consequently the beam direction, can be controlled by simply adjusting the direction of the magnetic fields. Theoretical analyses show that this magnetic alignment technique is stable and accurate, providing a new strategy for building high-performance tunable nanophotonic devices.

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“…In addition to a high flexibility of geometric designs, DNA origami also serves as a nanometric breadboard to accommodate nanoparticles, biomolecules, and small molecules with positional and stoichiometric control. − Naturally, such a level of fine nanofabrication is finding application in many different areas, which include nanoelectronics, , drug delivery, sensing with nanopores, , and enhanced catalysis among others. Nanophotonics has been a particularly fertile field of application for DNA origami, as they were used to organize metallic nanoparticles and optically active molecules at the nanoscale, enabling nanodevices that present enhanced fluorescence, − single-molecule SERS, − artificial light harvesting, − plasmon assisted FRET, , multichromophoric FRET, − energy transfer from molecules to metal films or graphene, , molecular emission directivity, − and strong coupling at room temperature. , …”

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confidence: 99%

DNA Self-Assembly of Single Molecules with Deterministic Position and Orientation

et al. 2022

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An ideal nanofabrication method should allow the organization of nanoparticles and molecules with nanometric positional precision, stoichiometric control, and well-defined orientation. The DNA origami technique has evolved into a highly versatile bottom-up nanofabrication methodology that fulfils almost all of these features. It enables the nanometric positioning of molecules and nanoparticles with stoichiometric control, and even the orientation of asymmetrical nanoparticles along predefined directions. However, orienting individual molecules has been a standing challenge. Here, we show how single molecules, namely, Cy5 and Cy3 fluorophores, can be incorporated in a DNA origami with controlled orientation by doubly linking them to oligonucleotide strands that are hybridized while leaving unpaired bases in the scaffold. Increasing the number of bases unpaired induces a stretching of the fluorophore linkers, reducing its mobility freedom, and leaves more space for the fluorophore to accommodate and find different sites for interaction with the DNA. Particularly, we explore the effects of leaving 0, 2, 4, 6, and 8 bases unpaired and find extreme orientations for 0 and 8 unpaired bases, corresponding to the molecules being perpendicular and parallel to the DNA double-helix, respectively. We foresee that these results will expand the application field of DNA origami toward the fabrication of nanodevices involving a wide range of orientation-dependent molecular interactions, such as energy transfer, intermolecular electron transport, catalysis, exciton delocalization, or the electromagnetic coupling of a molecule to specific resonant nanoantenna modes.

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DNA-Templated Ultracompact Optical Antennas for Unidirectional Single-Molecule Emission

Cited by 12 publications

References 38 publications

Optical Ultracompact Directional Antennas Based on a Dimer Nanorod Structure

Optical Ultracompact Directional Antennas Based on a Dimer Nanorod Structure

Smart Magnetic Optical Antenna for Automatic Nanoalignment and Photon Beaming from Prepatterned Single Quantum Dot Nanospot

DNA Self-Assembly of Single Molecules with Deterministic Position and Orientation

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