Rate equation description of quantum noise in nanolasers with few emitters

Mørk, Jesper; Lippi, G. L.

doi:10.1063/1.5022958

Cited by 59 publications

(100 citation statements)

References 39 publications

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“…In this work we will show that another stochastic approach, often used in the fields of chemistry and biochemistry [19][20][21][22], can be used to describe the laser dynamics, and can decrease the computation times by several orders of magnitude compared to previous approaches [16][17][18]. Additionally, certain numerical assumptions made in [18] can be avoided with the new method, leading to a robust and versatile stochastic approach with numerous applications. Here we use it to consider the intra-cavity photon probability density functions as a lasing system transitions from thermal to coherent emission, and we will investigate the prospects of introducing effectively altered rates of emission in the rate equations as a way to qualitatively describe the effects of collective inter-emitter correlations.…”

Section: Introductionmentioning

confidence: 93%

“…One major area of interest in regards to nanolasers is the photon noise and photon statistics: With a relatively small number of intra-cavity photons and a large fraction of the spontaneously emitted photons ending up in the cavity mode(s), the associated quantum noise becomes increasingly important [11][12][13][14][15]. Recently, stochastic methods have been used to simulate nanoscale lasers with large values of the spontaneous emission β-factor [16][17][18], and it was found that the noise and statistics of nanolasers can be captured surprisingly well by including only shot noise; that is, the noise associated with the discreteness of the photons and emitters in the cavity.…”

Section: Introductionmentioning

confidence: 99%

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Efficient stochastic simulation of rate equations and photon statistics of nanolasers

André¹,

Mørk²,

Wubs³

2020

Opt. Express

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Section: Introductionmentioning

confidence: 93%

Section: Introductionmentioning

confidence: 99%

Efficient stochastic simulation of rate equations and photon statistics of nanolasers

André¹,

Mørk²,

Wubs³

2020

Opt. Express

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“…The idea was to tightly confine light in the form of localized plasmons into deep subwavelength dimensions overlapping with a gain material to achieve stimulated emission and plasmon oscillations amplification or lasing. Enhanced coherent plasmon oscillations, in this case, would be a source of giant near fields (hotspots) and coherent light at the nanometer scale [149], even beyond the diffraction limit. In contrast to all-dielectric semiconductor microlasers, the quanta of the resonator in the spaser is a plasmon, instead of a photon, but it can also generate 22 coherent light emission, which has been realized in a series of subsequent experiments [61], [78], [238], [239].…”

Section: Loss Compensation and Amplificationmentioning

confidence: 99%

“…The remaining part of the total Purcell factor tot m () FF  corresponds to the change of energy decay rate to all other modes. Thus, in order to make the laser threshold smaller, one has to increase  by enhancement of the mode Purcell factor m F as much as possible, simultaneously reducing tot m () FF  .Rate equations.Taking into account all the processes of pumping, energy transfer, radiation and dissipation, the dynamics of the coupled gain-resonator system can be described (weak-coupling regime) by so-called rate equations[149]-[151]:…”

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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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“…The model used in this paper is based on semi-classical stochastic rate equations [43] taking into account the electron scattering mechanisms into the QDs as derived in our previous works [37,44,45]. The description of micro-and nanolasers with semi-classical equations was recently shown to be valid down to a surprisingly low number of emitters on the order of 10 [46]. Our chosen theoretical framework should therefore be suited to accurately describe the dynamical properties of the micropillar lasers considered here.…”

Section: Modelmentioning

confidence: 99%

Mutual coupling and synchronization of optically coupled quantum-dot micropillar lasers at ultra-low light levels

et al. 2019

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Synchronization of coupled oscillators at the transition between classical physics and quantum physics has become an emerging research topic at the crossroads of nonlinear dynamics and nanophotonics. We study this unexplored field by using quantum dot microlasers as optical oscillators. Operating in the regime of cavity quantum electrodynamics (cQED) with an intracavity photon number on the order of 10 and output powers in the 100 nW range, these devices have high β -factors associated with enhanced spontaneous emission noise. We identify synchronization of mutually coupled microlasers via frequency locking associated with a sub-gigahertz locking range. A theoretical analysis of the coupling behavior reveals striking differences from optical synchronization in the classical domain with negligible spontaneous emission noise. Beyond that, additional self-feedback leads to zero-lag synchronization of coupled microlasers at ultra-low light levels. Our work has high potential to pave the way for future experiments in the quantum regime of synchronization.

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Rate equation description of quantum noise in nanolasers with few emitters

Cited by 59 publications

References 39 publications

Efficient stochastic simulation of rate equations and photon statistics of nanolasers

Efficient stochastic simulation of rate equations and photon statistics of nanolasers

Active Nanophotonics

Mutual coupling and synchronization of optically coupled quantum-dot micropillar lasers at ultra-low light levels

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