Nanolaser arrays: toward application-driven dense integration

Deka, Suruj S.; Jiang, Shisong; Pan, Si; Fainman, Yeshaiahu

doi:10.1515/nanoph-2020-0372

Cited by 21 publications

(14 citation statements)

References 98 publications

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“…Changing the properties of active elements is possible due to external manipulations on demand and is not limited to the specifics of the metastructure production process [20,21]. Dynamic control over the light propagation by tuning active elements of metamaterials has many practical applications, such as loss compensation [22][23][24], lasing [25][26][27], nonlinear optical operations [28][29][30], thermal radiation control [31], interferometry [32], holography [33,34], etc. Among many configurations of all-dielectric metamaterials, we are interested here in two-dimensional flat structures (metasurfaces) that support the so-called trapped modes [35][36][37][38] (recently, such modes are also referred to the phenomenon of bound states in the continuum (BIC) [39][40][41]).…”

Section: Introductionmentioning

confidence: 99%

Trapped mode excitation in all-dielectric metamaterials with loss and gain

Hlushchenko,

Novitsky,

Tuz

2022

Preprint

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Non-Hermitian photonics based on combining loss and gain media within a single optical system provides a number of approaches to control and generate the flow of light. In this paper, we show that by introducing non-Hermitian perturbation into the system with loss and gain constituents, the high-quality resonances known as trapped modes can be excited without the need to change the symmetry of the unit cell geometry. To demonstrate this idea, we consider a widely used all-dielectric planar metamaterial whose unit cell consists of a pair of rectangular nanoantennas made of ordinal (lossy) and doped (gainy) silicon. Since the quality factor of the trapped-mode resonance can be controlled by changing both geometrical symmetry and non-Hermiticity, varying loss and gain allows us to compensate for the influence of asymmetry and restore an almost perfectly localized trapped mode. The results obtained suggest new ways to achieve high-quality resonances in non-Hermitian metasurfaces promising for many practical applications in nanophotonics.

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Section: Introductionmentioning

confidence: 99%

Trapped mode excitation in all-dielectric metamaterials with loss and gain

Hlushchenko,

Novitsky,

Tuz

2022

Preprint

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“…Coupled nanophotonic semiconductor lasers are a prototypical model for on-chip laser networks 1 , 2 , which have attracted considerable attention as an optical solution for neuromorphic realizations in the recent years 3 – 5 . Due to their small footprint, high speed and low power consumption, they are promising light sources for a wide range of nanophotonic applications such as photonic integrated circuits, on-chip optical computing, and optical communication 4 , 6 – 9 .…”

Section: Introductionmentioning

confidence: 99%

Stabilizing nanolasers via polarization lifetime tuning

Roos

Meinecke

Lüdge

2021

Sci Rep

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We investigate the emission dynamics of mutually coupled nanolasers and predict ways to optimize their stability, i.e., maximize their locking range. We find that tuning the cavity lifetime to the same order of magnitude as the dephasing time of the microscopic polarization yields optimal operation conditions, which allow for wider tuning ranges than usually observed in conventional semiconductor lasers. The lasers are modeled by Maxwell–Bloch type class-C equations. For our analysis, we analytically determine the steady state solutions, analyze the symmetries of the system and numerically characterize the emission dynamics via the underlying bifurcation structure. The polarization lifetime is found to be a crucial parameter, which impacts the observed dynamics in the parameter space spanned by frequency detuning, coupling strength and coupling phase.

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“…The thorough understanding and smart design of pulsed laser sources at the nanoscale is a fundamental step toward the development of many practical applications [ 1–4 ] : secure communications (chaos cryptography, random number generation), optical computers (optical interconnects, reservoir computing), and biochemical sensing, among others. With the advent of new and improved technologies of micro and nanofabrication, new types of miniaturized lasers have started to be implemented and investigated [ 1–3,5 ] that allow not only dense integration into photonic circuitry but enable the control of both light–matter coupling strengths and light transport properties, opening up new opportunities to study novel fundamental laser phenomena. [ 6,7 ]…”

Section: Introductionmentioning

confidence: 99%

“…The thorough understanding and smart design of pulsed laser sources at the nanoscale is a fundamental step toward the development of many practical applications [1][2][3][4] : secure communications (chaos cryptography, random number generation), optical computers (optical interconnects, reservoir computing), and biochemical sensing, among others. With the advent of new and improved technologies of micro and nanofabrication, new types of miniaturized lasers have started to be implemented and investigated [1][2][3]5] that allow not only dense integration into photonic circuitry but enable the control of both light-matter coupling strengths and light transport properties, opening up new opportunities to study novel fundamental laser phenomena. [6,7] Several experimental and theoretical proposals for both photonic [8][9][10][11][12][13][14][15][16][17][18][19][20][21] and plasmonic [22][23][24][25][26] nanolasers have demonstrated the feasibility to automatically start a pulsed lasing state under continuous wave (CW) excitation, paving the way for the integration of ultra-fast lasers at the nanoscale.…”

Section: Introductionmentioning

confidence: 99%

Ultrashort Pulse Generation in Nanolasers by Means of Lorenz–Haken Instabilities

Cerdán

2021

Annalen der Physik

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Nearly half a century ago, the German physicist Hermann Haken proved that the laser dynamics could be described, under certain conditions, by the Lorenz equations, the paradigm of deterministic chaos. Unfortunately, its experimental realization has remained elusive for conventional laser materials and cavities mostly due to the extreme pumping conditions and the low cavity quality factors (“bad‐cavity condition”) required to achieve Lorenz–Haken (L‐H) self‐pulsing dynamics upon continuous wave excitation. In this paper, it is theoretically proved that dielectric and plasmonic nanolasers, that can naturally fulfill the bad‐cavity condition, may overcome the limitations of macroscopic cavities and make the observation of L‐H instabilities in visible‐IR solid‐state materials become a reality. Remarkably, the adequate choice of active material and cavity design enables the generation of trains of ultrashort pulses in the sub‐ps regime and with MHz–GHz repetition rates without the need of resorting to neither mode‐locking nor Q‐switching techniques. Thus, the results reported in this manuscript unveil a new paradigm in the generation of ultrashort pulses at the nanoscale.

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Nanolaser arrays: toward application-driven dense integration

Cited by 21 publications

References 98 publications

Trapped mode excitation in all-dielectric metamaterials with loss and gain

Trapped mode excitation in all-dielectric metamaterials with loss and gain

Stabilizing nanolasers via polarization lifetime tuning

Ultrashort Pulse Generation in Nanolasers by Means of Lorenz–Haken Instabilities

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