Subwavelength semiconductor lasers for dense chip-scale integration

Gu, Qing; Smalley, Joseph S. T.; Nezhad, Maziar P.; Simić, Aleksandar; Lee, Jin Hyoung; Katz, Michael; Bondarenko, Olesya; Slutsky, Boris; Mizrahi, Amit; Lomakin, Vitaliy; Fainman, Yeshaiahu

doi:10.1364/aop.6.000001

Cited by 26 publications

(15 citation statements)

References 112 publications

(209 reference statements)

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“…Such fast implement of MIS structure for plasmonic laser is of extensive advantages, including relatively low ohmic losses at optical frequencies, strong mode confinement, fast decay dynamics and broad emission spectra tunability . These attractive features enable according plasmonic lasers with promising applications in photonic integration, quantum plasmonic devices and lasing‐enhanced sensing . By replacing the gain nanowire to nanosquare, the radiation loss can be suppressed effectively by adopting total internal reflection of SPP and the plasmonic laser was demonstrated at room temperature .…”

Section: Introductionmentioning

confidence: 99%

Realization of Perovskite‐Nanowire‐Based Plasmonic Lasers Capable of Mode Modulation

Ren

Wang

Chen

et al. 2019

Laser & Photonics Reviews

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Manipulating stimulated‐emission processes and overcoming the ohmic loss of metals in plasmonic lasers are of significance for the according applications in biological sensors, data storage, photolithography, and optical communications. Herein, through utilizing an electrochemical‐assisted growth method for high‐quality perovskite nanowires, plasmonic lasers based on the structure of metal/dielectric layer/perovskite nanowires are constructed. The plasmonic lasers demonstrate a threshold of 62 µJ cm−2, a high quality factor of Q ≈ 655, and a fast lasing decay time of 1.6 ps. Interestingly, the plasmonic lasers present an attractive capability in transformation from single mode to multiple modes just by adjusting the pumping energy. In addition to the broad stoichiometry‐dependent tunability of the perovskite materials, the proposed plasmonic lasers have great promise in real applications.

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Section: Introductionmentioning

confidence: 99%

Realization of Perovskite‐Nanowire‐Based Plasmonic Lasers Capable of Mode Modulation

Ren

Wang

Chen

et al. 2019

Laser & Photonics Reviews

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“…Indeed, we show in this contribution, that the spectral position of plasmonic resonances used in is sub‐optimal and requires very high gain. Related research areas are “plasmonic nano‐lasers”, where, however, at least one dimension is not truly nanoscopic , and the amplification and generation of surface plasmon polaritons .…”

Section: Introductionmentioning

confidence: 99%

Minimal spaser threshold within electrodynamic framework: Shape, size and modes

2015

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It is known (yet often ignored) from quantum mechanical or energetic considerations, that the threshold gain of the quasi‐static spaser depends only on the dielectric functions of the metal and the gain material. Here, we derive this result from the purely classical electromagnetic scattering framework. This is of great importance, because electrodynamic modelling is far simpler than quantum mechanical one. The influence of the material dispersion and spaser geometry are clearly separated; the latter influences the threshold gain only indirectly, defining the resonant wavelength. We show that the threshold gain has a minimum as a function of wavelength. A variation of nanoparticle shape, composition, or spasing mode may shift the plasmonic resonance to this optimal wavelength, but it cannot overcome the material‐imposed minimal gain. Furthermore, retardation is included straightforwardly into our framework; and the global spectral gain minimum persists beyond the quasi‐static limit. We illustrate this with two examples of widely used geometries: Silver spheroids and spherical shells embedded in and filled with gain materials.

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“…Here, we extend the concept to a sensor that simultaneously probes different properties of the desired environment. An array of five semiconductor nanolasers [73,74], each one with all spatial dimensions less than 1 μm, placed 1 μm from each other, could provide light emission in five different wavelengths on an array pitch of 10 μm. A semiconductor laser, if reversed biased, can act as photodetector, which means a similar compact array could be used for power detection.…”

Section: Advanced Photonic Technologies For Smart Citiesmentioning

confidence: 99%

Photonics for Smart Cities

Smalley¹,

Vallini²,

Amili³

et al. 2016

Smart Cities Technologies

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We review the current applications of photonic technologies to Smart Cities. Inspired by the future needs of Smart Cities, we then propose potential applications of advanced photonic technologies. We find that photonics already has a major impact on Smart Cities, in terms of smart lighting, sensing, and communication technologies. We further find that advanced photonic technologies could lead to vastly improved infrastructure, such as smart water-supply systems. We conclude by proposing directions for future research that will have the greatest impact on realizing Smart City initiatives.

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Subwavelength semiconductor lasers for dense chip-scale integration

Cited by 26 publications

References 112 publications

Realization of Perovskite‐Nanowire‐Based Plasmonic Lasers Capable of Mode Modulation

Realization of Perovskite‐Nanowire‐Based Plasmonic Lasers Capable of Mode Modulation

Minimal spaser threshold within electrodynamic framework: Shape, size and modes

Photonics for Smart Cities

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