Coupling single quantum dots to plasmonic nanocones: optical properties

Meixner, Alfred J.; Jäger, Regina; Jäger, Sebastian; Bräuer, Annika; Scherzinger, Kerstin; Fulmes, Julia; Krockhaus, Sven zur Oven; Gollmer, Dominik A.; Kern, D. P.; Fleischer, Monika

doi:10.1039/c5fd00074b

Cited by 24 publications

(30 citation statements)

References 64 publications

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“…4. Due to the modification of the local density of optical states by the plasmon resonance and the antenna properties of the plasmonic nanostructures, the fluorescence in the hybrid system appears to be increased [4,5,7,37,38]. For the wires with 63 and 74 nm widths, the left shoulder of the broad fluorescence curve of DIP at around 630 nm is most strongly enhanced (Fig.…”

Section: Resultsmentioning

confidence: 98%

“…Several mechanisms can lead to the fluorescence enhancement in the hybrid system: the increase of light absorption by the DIP molecules due to the enhanced near-field at the surface of the plasmonic nanostructures, changes of the radiative and non-radiative transition rates induced by the metal nanostructures, and/or the coupling of the nanostructures' near-field to the far-field [6,7,37,38]. Because of the unpolarized excitation in the fluorescence setup, a potential absorption effect should be visible in both the TE-and TM-polarized emission data (Fig.…”

Section: Resultsmentioning

confidence: 99%

“…In further experiments, time and polarization-dependent measurements could be used for further investigation of the change of the transition rates and decay channels due to the metallic grating [7,38]. With such measurements, the lifetime modification due to the change of the local electromagnetic density of states can be investigated.…”

Section: Resultsmentioning

confidence: 99%

“…Through this associated near-field, localized surface plasmons can couple to adjacent materials and vice versa [4,5]. Thus, in hybrid systems with fluorescent molecules or quantum dots, plasmonic nanostructures can enhance and spectrally shape the spontaneous emission [5][6][7][8]. For quantum dots or fluorophores, the polarizability and directionality of the fluorescence emission by plasmonic nanoantennas has been demonstrated [9][10][11].…”

Section: Introductionmentioning

confidence: 99%

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Shaping and polarizing fluorescence emission of a polycrystalline organic semiconductor film by plasmonic nanogratings

et al. 2019

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The fluorescence emission properties of hybrid systems consisting of a one-dimensional gold nanowire grating and an evaporated thin film of the small molecule organic semiconductor diindenoperylene (DIP) are investigated. The optical properties of the metallic systems are dominated by their plasmonic resonances. The spectral positions of the resonances are tuned through the width of the single nanowires. Additionally, the plasmonic gratings show a strong polarization dependency due to their one-dimensionality. In contrast, the pure organic system has a polarization-independent emission between 570 and 900 nm when excited with blue light, whereas no photoluminescence can be detected from the bare plasmonic system for the same illumination conditions. For the hybrid system, the intensity, the shape of the emission spectrum, and the polarization of the emission clearly correlate with the optical properties of the plasmonic nanowires. Depending on the optical properties of the plasmonic system, different emission bands of the organic thin film can be enhanced.

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Section: Resultsmentioning

confidence: 98%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Shaping and polarizing fluorescence emission of a polycrystalline organic semiconductor film by plasmonic nanogratings

et al. 2019

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“…Because of these intriguing characteristics, CVBs are used as novel probes for imaging the orientation of molecules or nanostructures. 29 − 33 Owing to the tensorial character of nonlinear interactions, CVBs are also used to improve the orientation sensitivity of nonlinear microscopy techniques. 34 − 39 In the context of oligomer studies, focused CVBs have been shown to excite collective dark modes (with zero net dipole moment), which cannot be accessed using linear polarization under normal incidence.…”

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confidence: 99%

Collective Effects in Second-Harmonic Generation from Plasmonic Oligomers

et al. 2018

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We investigate collective effects in plasmonic oligomers of different symmetries using second-harmonic generation (SHG) microscopy with cylindrical vector beams (CVBs). The oligomers consist of gold nanorods that have a longitudinal plasmon resonance close to the fundamental wavelength that is used for SHG excitation and whose long axes are arranged locally such that they follow the distribution of the transverse component of the electric field of radially or azimuthally polarized CVBs in the focal plane. We observe that SHG from such rotationally symmetric oligomers is strongly modified by the interplay between the polarization properties of the CVB and interparticle coupling. We find that the oligomers with radially oriented nanorods exhibit small coupling effects. In contrast, we find that the oligomers with azimuthally oriented nanorods exhibit large coupling effects that lead to silencing of SHG from the whole structure. Our experimental results are in very good agreement with numerical calculations based on the boundary element method. The work describes a new route for studying coupling effects in complex arrangements of nano-objects and thereby for tailoring the efficiency of nonlinear optical effects in such structures.

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Mechanically Tunable Nanogap Antennas: Single‐Structure Effects and Multi‐Structure Applications

Laible

Horneber

Fleischer

2021

Advanced Optical Materials

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By mechanically changing the width of a nanometer gap between two optical antennas, the coupling condition for the antennas can be seamlessly modified. This leads to a shift in the antenna's localized surface plasmon resonance wavelength, and a modification of the intensity in the antenna hotspot, which can reach extraordinarily high values for nanometer gaps. Such systems have in recent years been realized, for example, by using flexible polymers as substrates that are mechanically stretched or bent, or by combining break junctions with plasmonic antennas. Applications can be found, amongst others, in plasmonic strain sensing via color shift sensors, or tunable surface‐enhanced Raman spectroscopy platforms. In this article an overview is given over recent work on mechanically tunable gap antennas, with a specific focus on studies at the single‐nanostructure level. Different techniques used for mechanical tuning, optical read‐out signals that are influenced by the gap width, and potential applications of the resulting structures are presented. Plasmonic break junctions offer a new perspective that allows for added functionalities. The mechanical activation is discussed within the context of single nanoantenna gap tuning by using alternative stimuli.

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Coupling single quantum dots to plasmonic nanocones: optical properties

Cited by 24 publications

References 64 publications

Shaping and polarizing fluorescence emission of a polycrystalline organic semiconductor film by plasmonic nanogratings

Shaping and polarizing fluorescence emission of a polycrystalline organic semiconductor film by plasmonic nanogratings

Collective Effects in Second-Harmonic Generation from Plasmonic Oligomers

Mechanically Tunable Nanogap Antennas: Single‐Structure Effects and Multi‐Structure Applications

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