Modeling room-temperature lasing spectra of 1.3-μm self-assembled InAs∕GaAs quantum-dot lasers: Homogeneous broadening of optical gain under current injection

Sugawara, Mitsuru; Hatori, Nobuaki; Ebe, H.; Ishida, M.; Arakawa, Yasuhiko; Akiyama, T.; Otsubo, Kenji; Nakata, Yoshihiro

doi:10.1063/1.1849426

Cited by 136 publications

(91 citation statements)

References 15 publications

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“…The impact of these two mechanisms on the operation of QD lasers has been addressed mostly on the theoretical side, with emphasis on the transition of nonequilibrium to quasiequilibrium carrier distributions [7][8][9][10] as well as the transition from broadband multimode lasing emission to a narrow lasing line. 7,[11][12][13] This paper presents a detailed experimental investigation of carrier processes in QD lasers around and above the lasing threshold. Fitting these results with a numerical model allows a quantitative estimation of the crucial material parameters.…”

Section: Introductionmentioning

confidence: 99%

Role of thermal hopping and homogeneous broadening on the spectral characteristics of quantum dot lasers

Markus

Rossetti

Calligari

et al. 2005

Journal of Applied Physics

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The effect of thermal hopping and homogeneous broadening on the lasing spectra and carrier distribution in quantum dot lasers is investigated by measuring the spontaneous emission spectra through a top-contact window. Two intriguing features are observed, i.e., a strong redshift of the excited-state lasing peak as compared to the spontaneous emission spectrum and the absence of population clamping at threshold. These features are interpreted on the basis of a rate-equation model taking into account energy-broadening mechanisms and thermal coupling among quantum dots. The good agreement between model and experiment allows us to estimate the homogeneous broadening and capture time, two key parameters for the understanding and proper design of quantum dot lasers.

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Section: Introductionmentioning

confidence: 99%

Role of thermal hopping and homogeneous broadening on the spectral characteristics of quantum dot lasers

Markus

Rossetti

Calligari

et al. 2005

Journal of Applied Physics

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“…As it is seen in Figure 1,a the GS band is split into two peaks (~1.254 and ~1.262 nm). According to M. Sugawara et al 5 this splitting can be attributed to the homogenous broadening of the QD optical transition. They also suggested that the GS lasing quenching at high currents could be explained by increase of the homogenous broadening.…”

Section: Quenching Of Gs Spectral Componentmentioning

confidence: 99%

Front Matter: Volume 8562

Zhang¹,

Zhang²,

Li³

et al. 2012

SPIE Proceedings

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“…It remains constant above the excited-state lasing threshold in some structures; 8,19 in others, the ground-state power approaches its maximum and then rollover occurs. 1,4,7,12,16,17 3. Internal and external differential quantum efficiencies For j th1 j < j th2 , the internal quantum efficiency can be introduced for ground-state lasing only [see Eq.…”

Section: Pinning Of Output Power and Necessary Condition For Ground-smentioning

confidence: 99%

Output power of a quantum dot laser: Effects of excited states

Asryan

2015

Journal of Applied Physics

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A theory of operating characteristics of quantum dot (QD) lasers is discussed in the presence of excited states in QDs. We consider three possible situations for lasing: (i) ground-state lasing only; (ii) ground-state lasing at first and then the onset of also excited-state lasing with increasing injection current; (iii) excited-state lasing only. The following characteristics are studied: occupancies of the ground-state and excited-state in QDs, free carrier density in the optical confinement layer, threshold currents for ground-and excited-state lasing, densities of photons emitted via groundand excited-state stimulated transitions, output power, internal and external differential quantum efficiencies. Under the conditions of ground-state lasing only, the output power saturates with injection current. Under the conditions of both ground-and excited-state lasing, the output power of ground-state lasing remains pinned above the excited-state lasing threshold while the power of excited-state lasing increases. There is a kink in the light-current curve at the excited-state lasing threshold. The case of excited-state lasing only is qualitatively similar to that for single-state QDs-the role of ground-state transitions is simply reduced to increasing the threshold current.

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Modeling room-temperature lasing spectra of 1.3-μm self-assembled InAs∕GaAs quantum-dot lasers: Homogeneous broadening of optical gain under current injection

Cited by 136 publications

References 15 publications

Role of thermal hopping and homogeneous broadening on the spectral characteristics of quantum dot lasers

Role of thermal hopping and homogeneous broadening on the spectral characteristics of quantum dot lasers

Front Matter: Volume 8562

Output power of a quantum dot laser: Effects of excited states

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