Far-IR to deep-UV adaptive supercontinuum generation using semiconductor nano-antennas via carrier injection rate modulation

Aşırım, Özüm Emre

doi:10.1007/s13204-021-02147-1

Cited by 10 publications

(15 citation statements)

References 39 publications

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“…Hence, our investigation involves the concurrent solution of the wave equation, Lorentz dispersion equation, and the associated rate equation that model the carrier dynamics. These equations are expressed as follows [18][19][20][21] Wave equation:…”

Section: Methodsmentioning

confidence: 99%

Plasmonic tuning of nano-antennas for super-gain light amplification

Aşırım,

Kuzuoğlu

2024

J. Phys. Photonics

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Nanoscale conductive materials are often used for inducing localized free electron oscillations known as plasmons. This is due to their high electronic excitability under optical irradiation owing to their super-small volume. Recently, plasmons have been of interest for enhancing the gain-bandwidth product of optical amplifiers. There are currently two well-established mechanisms for light amplification. The first one is via stimulated emission of radiation (lasers) using a given energy source and often an optical feedback mechanism. The second one is based on the nonlinear coupling of a low-intensity input wave and a high-intensity pump wave for energy exchange (parametric amplifiers). Both techniques have shortcomings. Lasers have a small operation bandwidth and offer a limited gain, but require moderate energy pumping to operate. Whereas optical parametric amplifiers (OPAs) offer a high operation bandwidth along with a much higher optical gain, with the drawback of requiring intense pumping to be functional. The aim of this paper is to introduce a technique that combines the advantages and eliminates the drawbacks of both techniques in the nanoscale to allow for a better amplification performance in integrated optical devices. This is achieved by inducing a plasmonic chirp in conductive nanomaterials a.k.a nano-antennas, which enables the confinement of an enormous electric energy density that can be coupled to an input beam for amplification. Using the Finite Difference Time Domain (FDTD) numerical-method with the material parameters of well-known semiconductors, intramaterial condensation of electric energy density is observed in semiconductor nano-antennas for certain plasmonic chirp-frequencies which enables broadband high-gain optical amplification based on free-electron oscillations that is promising for small-scale optical devices requiring a high gain-bandwidth product. The results are in good agreement with semiempirical data.

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Section: Methodsmentioning

confidence: 99%

Plasmonic tuning of nano-antennas for super-gain light amplification

Aşırım,

Kuzuoğlu

2024

J. Phys. Photonics

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“…The long optical fiber introduces different time delays for each spectral component due to the variation in its refractive index with respect to frequency. This naturally makes the group velocity of the laser beam a function of frequency and introduces chromatic dispersion [28][29][30][31][32][33]. Depending on the dispersion characteristics of the fiber, the chromatic dispersion usually distorts the signal pattern of the FDML laser.…”

Section: Methodsmentioning

confidence: 99%

Influence of the linewidth enhancement factor on the signal pattern of Fourier domain mode-locked lasers

2022

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Fourier domain mode-locked (FDML) lasers are frequency-swept lasers that operate in the near-infrared region and allow for the attainment of a large sweep-bandwidth, high sweep-rate, and a narrow instantaneous linewidth, all of which are usually quite desirable characteristics for a frequency-swept laser. They are used in various sensing and imaging applications but are most commonly noted for their practical use in optical coherence tomography (OCT). An FDML laser consists of three fundamental components, which are the semiconductor optical amplifier (SOA), optical fiber, and the wavelength-swept optical bandpass filter. Due to the complicated nonlinear dynamics of FDML lasers that stems from the coaction of these three components, often the output signal of an FDML laser is corrupted by frequent power-dips of varying depth and duration. The frequent recurrence of these dips in the FDML laser signal pattern lowers the quality of imaging and detection. This study examines the role of the linewidth enhancement factor (LWEF) of an SOA in reducing both the strength and the number of power-dips throughout the FDML laser operation. The results are obtained using numerical computations that are in agreement with experimental data. The study aims to show that using SOAs with low LWEFs, the number of power-dips can be reduced for a better detection and imaging quality.

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“…To minimize the LWEF, its main culprit, which is the fluctuations of the refractive index, must be minimized [37][38][39][40][41]. Therefore, in this study, all parameters that influence the refractive index are investigated to provide a systematic approach in decreasing the LWEF of MQW SOAs.…”

Section: Introductionmentioning

confidence: 99%

Minimizing the linewidth enhancement factor in multiple-quantum-well semiconductor optical amplifiers

Aşırım¹,

Jirauschek²

2022

J. Phys. B: At. Mol. Opt. Phys.

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Semiconductor optical amplifiers (SOAs) often exhibit pronounced phase noise owing to their inherently high linewidth enhancement factor (LWEF). The signal to noise ratio of a semiconductor optical amplifier is often decreased due to refractive index fluctuations in the gain medium causing distorted phase relationship between the generated photons, which is quantified by the LWEF. A simple and precise theoretical model that offers a prescription for minimizing the LWEF in SOAs is unavailable in the literature. In this study, we have developed an inclusive yet simple algorithmic model that aims to both represent the variation and to provide a strategy for minimizing the LWEF in multiple-quantum-well (MQW) based SOAs. The results of the presented model were verified via a reasonable agreement with experimental results. This study provides a theoretical description of how to adjust the linewidth enhancement factor through tuning of the most critical MQW SOA parameters in the design stage.

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Far-IR to deep-UV adaptive supercontinuum generation using semiconductor nano-antennas via carrier injection rate modulation

Cited by 10 publications

References 39 publications

Plasmonic tuning of nano-antennas for super-gain light amplification

Plasmonic tuning of nano-antennas for super-gain light amplification

Influence of the linewidth enhancement factor on the signal pattern of Fourier domain mode-locked lasers

Minimizing the linewidth enhancement factor in multiple-quantum-well semiconductor optical amplifiers

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