Plasmonic Nanolasers: Pursuing Extreme Lasing Conditions on Nanoscale

Wu, Hao; Gao, Yixiao; Xu, Peizhen; Guo, Xin; Wang, Pan; Dai, Daoxin; Tong, Limin

doi:10.1002/adom.201900334

Cited by 44 publications

(28 citation statements)

References 216 publications

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“…The plasmon‐based sources overcome the diffraction limit, have faster (up to THz) switching capabilities in comparison to semiconductor counterparts, exploiting stimulated recombination, [ 13 ] and are limited to switching rates of the order of GHz. The spaser‐based nanolaser is the smallest, biocompatible, and nontoxic tool, and can be incorporated in living tissues for a large number of biomedical in vivo and in vitro applications.…”

Section: Introductionmentioning

confidence: 99%

Polarized Stimulated Emission of 2D Ensembles of Plasmonic Nanolasers

Toropov

Kamalieva²,

Starovoytov

et al. 2020

Advanced Photonics Research

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Plasmonic nanolasers produce coherent light with wavelengths on a scale similar to their own or larger. In the past decade they have attracted intense interest, particularly from the emerging areas of integrated photonic circuits and biomedicine. Despite these capabilities, plasmonic nanolasers are still not completely understood, and this lack of understanding leads to confusing them with spasers and random lasers. Herein, the operation of pure spaser‐based plasmonic nanolaser arrays is presented. For this, a monolayer of silver nanoparticles (NPs) affixed to a dielectric surface and covered with a fluorescent polymethyl methacrylate (PMMA)–coumarin solid composite is investigated. The input–output characteristic measured for the composites on a bare substrate (without Ag NPs) reveals that the emission at pump pulse energies above 2.4 mJ (at 355 nm excitation wavelength) stops growing, and instead is inhibited by saturation. In contrast, in such structures with Ag NPs an additional emission band pops up over a fluorescence background. It has a spectral width order of units of nanometers and its intensity grows faster than at lower pump pulse energies, revealing a nonlinear dependence of the input–output characteristic. The spaser‐based lasing observed is completely linearly polarized and clearly directed as 45° from the substrate.

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Section: Introductionmentioning

confidence: 99%

Polarized Stimulated Emission of 2D Ensembles of Plasmonic Nanolasers

Toropov

Kamalieva²,

Starovoytov

et al. 2020

Advanced Photonics Research

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show abstract

“…Since the invention of plasmonic nanolasers, different approaches and geometries have been explored, including metallic-nanoparticle lasers [238], [312], plasmonic nanowire lasers [51], [61], coaxial nanolasers [182], metal-insulator-metal gap-mode nanolasers [311], plasmonic crystal nanolasers [313], Tamm plasmon laser [148] to name just a few. We address the interested readers to the review papers discussing the various nanolaser geometries [57], [314]. Below in this section, we discuss the problem of lasing threshold definition, various laser geometries and new active materials (2D TMDCs, perovskites, MOFs), perspective for nanolaser realizations.…”

Section: Lasingmentioning

confidence: 99%

Active Nanophotonics

Krasnok

Alù

2020

Proc. IEEE

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Recent progress in nanofabrication has led to tremendous technological developments in nanophotonics, which rely on the interaction of light with nanostructured matter. Nanophotonics has experienced a large surge of interest in recent years, from basic research to applied technology.The increased importance of extremely low-energy data processing at ultra-fast speeds has been encouraging the use of light for signal transport and processing. Energy demands and interaction time scales become smaller with the physical size of the nanostructures, hence nanophotonics opens the opportunity of integrating a large number of devices that can generate, control, modulate, sense and process light signals at ultrafast speeds and below femtojoule/bit energy levels.However, losses and diffraction pose fundamental challenges to the fundamental ability of nanophotonic structures to confine light efficiently in smaller and smaller volumes. In this framework, active nanophotonics, which combines the latest advances in nanotechnology with gain materials, has become in recent years a vital area of optics research, both from the physics, material science, and engineering standpoint. In this paper, we review recent efforts in enabling active nanodevices for lasing and optical sources, loss compensation, and to realize new optical functionalities, like -symmetry, exceptional points and nontrivial lasing based on suitably engineered distributions of gain and loss in nanostructures.

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“…In nanogaps of nearby metal nanostructures, the enhancement is extremely prominent. [1][2][3] The field enhancement effect has been used for enhancing various optical processes, such as Raman scattering, [4] fluorescence, [5][6][7] optical forces, [8,9] lasing, [10,11] and various nonlinear processes. [12][13][14] The SP resonance frequencies can be finely tuned by controlling the nanostructure geometries, and are very sensitive to the dielectric environment.…”

Section: Introductionmentioning

confidence: 99%

Plasmon–Exciton Interactions: Spontaneous Emission and Strong Coupling

Wei

Yan

Niu

et al. 2021

Adv Funct Materials

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The extraordinary optical properties of surface plasmons in metal nanostructures provide the possibilities to enhance and accelerate the spontaneous emission, and manipulate the decay and emission processes of quantum emitters. The extremely small mode volume of plasmonic nanocavities also benefits the realization of plasmon-exciton strong coupling. Here, the progress on the study of plasmon modified spontaneous emission and plasmon-exciton strong coupling are reviewed. The fundamentals of surface plasmons and quantum emitters, and the methods for assembling coupling systems of plasmonic nanostructures and quantum emitters are first introduced. Then the major aspects of plasmon modified spontaneous emission, including emission intensity, lifetime, spectral profile, direction, polarization, and energy transfer are reviewed. The coupling of quantum emitters and plasmonic waveguides is then discussed. Next, the developments of strong coupling between plasmonic structures and various quantum emitters are reviewed. Finally a few applications are highlighted followed by conclusions and outlook.

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Plasmonic Nanolasers: Pursuing Extreme Lasing Conditions on Nanoscale

Cited by 44 publications

References 216 publications

Polarized Stimulated Emission of 2D Ensembles of Plasmonic Nanolasers

Polarized Stimulated Emission of 2D Ensembles of Plasmonic Nanolasers

Active Nanophotonics

Plasmon–Exciton Interactions: Spontaneous Emission and Strong Coupling

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