Wedge Waveguides and Resonators for Quantum Plasmonics

Kress, Stephan J. P.; Antolinez, Felipe V.; Richner, Patrizia; Jayanti, Sriharsha V.; Kim, David K.; Prins, Ferry; Riedinger, Andreas; Fischer, Matthias; Meyer, Stefan; McPeak, Kevin M.; Poulikakos, Dimos; Norris, David J.

doi:10.1021/acs.nanolett.5b03051

Cited by 115 publications

(148 citation statements)

References 56 publications

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“…A bio-sensor based on a 3D plasmonic slot-waveguide has already been proposed [43], the addition of stub resonators integrated in slot waveguides can further boost the sensor's figure of merit by providing extra knobs to shape the spectral properties. The 3D double-stub resonators can further be utilized in the investigation of light-matter interactions in quantum plasmonic applications via positioning colloidal quantum dot emitters in hotspots within the DS resonator [39]. …”

Section: Discussionmentioning

confidence: 99%

Guidelines for designing 2D and 3D plasmonic stub resonators

Naghizadeh

Kocabaş

2016

J. Opt. Soc. Am. B

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In this work we compare the performance of plasmonic waveguide integrated stub resonators based on 2D metaldielectric-metal (MDM) and 3D slot-waveguide (SWG) geometries. We show that scattering matrix theory can be extended to 3D devices, and by employing scattering matrix theory we provide the guidelines for designing plasmonic 2D and 3D single-stub and double-stub resonators with a desired spectral response at the design wavelength. We provide transmission maps of 2D and 3D double-stub resonators versus stub lengths, and we specify the different regions on these maps that result in a minimum, a maximumor a plasmonically induced transparency (PIT) shape in the transmission spectrum. Radiation loss from waveguide terminations leads to a degradation of the 3D slot-waveguide based resonators. We illustrate improved waveguide terminations that boost resonator properties. We verify our results with 3D FDTD simulations.

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Section: Discussionmentioning

confidence: 99%

Guidelines for designing 2D and 3D plasmonic stub resonators

Naghizadeh

Kocabaş

2016

J. Opt. Soc. Am. B

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“…Three useful nanoparticle dispersions covering a range of applications 2,10,21 are used in this work.…”

Section: Methodsmentioning

confidence: 99%

Charge effects and nanoparticle pattern formation in electrohydrodynamic NanoDrip printing of colloids

et al. 2016

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Advancing open atmosphere printing technologies to produce features in the nanoscale range has important and broad applications ranging from electronics, to photonics, plasmonics and biology. [1][2][3][4] Recently an electrohydrodynamic printing regime has been demonstrated in a rapid dripping mode (termed NanoDrip), where the ejected colloidal droplets from nozzles of diameters of O(1 µm) can controllably reach sizes an order of magnitude smaller than the nozzle and can generate planar and out-of-plane structures of similar sizes.1 Despite demonstrated capabilities, our fundamental understanding of important aspects of the physics of NanoDrip printing needs further improvement.Here we address the topics of charge content and transport in NanoDrip printing. We employ quantum dot and gold nanoparticle dispersions in combination with a specially designed, auxiliary, asymmetric electric field, targeting the understanding of charge locality (particles vs. solvent) and particle distribution in the deposits as indicated by the dried nanoparticle patterns (footprints) on the substrate. We show that droplets of alternating charge can be spatially separated when applying an ac field to the nozzle. The nanoparticles within a droplet are distributed asymmetrically under the influence of the auxiliary lateral electric field, indicating that they are the main carriers. We alsoshow that the ligand length of the nanoparticles in the colloid affects their mobility after deposition (in the sessile droplet state).2

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“…For instance, metal nanowires does not present a cut-off and the lateral mode confinement is not diffraction limited but given by the nanowire cross-section [123]. Therefore, we expect high coupling efficiency of a dipolar emitter to a metal nanowire [124,125,126,127,128,129,130]. Metal nanowires define 1D plasmonic waveguides with a great potential for integrated optical routing [131].…”

Section: Purcell Factor Near a Plasmonic Waveguidementioning

confidence: 99%

Plasmonic Purcell factor and coupling efficiency to surface plasmons. Implications for addressing and controlling optical nanosources

Francs

Barthès

Bouhélier

et al. 2016

J. Opt.

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Abstract. The Purcell factor Fp is a key quantity in cavity quantum electrodynamics (cQED) that quantifies the coupling rate between a dipolar emitter and a cavity mode. Its simple form Fp ∝ Q/V unravels the possible strategies to enhance and control light-matter interaction. Practically, efficient light-matter interaction is achieved thanks to either i) high quality factor Q at the basis of cQED or ii) low modal volume V at the basis of nanophotonics and plasmonics. In the last decade, strong efforts have been done to derive a plasmonic Purcell factor in order to transpose cQED concepts to the nanocale, in a scale-law approach. In this work, we discuss the plasmonic Purcell factor for both delocalized (SPP) and localized (LSP) surface-plasmon-polaritons and briefly summarize the expected applications for nanophotonics. On the basis of the SPP resonance shape (Lorentzian or Fano profile), we derive closed form expression for the coupling rate to delocalized plasmons. The quality factor factor and modal confinement of both SPP and LSP are quantified, demonstrating their strongly subwavelength behaviour.

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Wedge Waveguides and Resonators for Quantum Plasmonics

Cited by 115 publications

References 56 publications

Guidelines for designing 2D and 3D plasmonic stub resonators

Guidelines for designing 2D and 3D plasmonic stub resonators

Charge effects and nanoparticle pattern formation in electrohydrodynamic NanoDrip printing of colloids

Plasmonic Purcell factor and coupling efficiency to surface plasmons. Implications for addressing and controlling optical nanosources

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