2019
DOI: 10.1109/jlt.2018.2884025
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Understanding the Bandwidth Limitations in Monolithic 1.3 μm InAs/GaAs Quantum Dot Lasers on Silicon

Abstract: In this paper, we present measurements and simulations of the small-signal modulation response of monolithic continuous-wave 1.3 m InAs/GaAs quantum dot (QD) narrow ridge-waveguide lasers on a silicon substrate. The 2.5 mm-long lasers investigated demonstrate 3dB modulation bandwidths of 1.6 GHz, D-factors of 0.3 GHz/mA 1/2 , modulation current efficiencies of 0.4 GHz/mA 1/2 , and K-factors of 2.4 ns and 3.7 ns. Since the devices under test are not designed for high-speed operation due to their long length an… Show more

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Cited by 15 publications
(6 citation statements)
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References 41 publications
(78 reference statements)
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“…However, due to the finite intraband relaxation time and gain saturation effect, even a moderate modulation bandwidth has been recognized as difficult to attain for QD lasers. [ 32 ] To date, the best reported modulation bandwidth of 1.3 µm QD DFB lasers grown on native substrates was limited to around 10 GHz, obtained with high‐reflective (HR)/antireflective (AR) coatings to the front and the rear facets, respectively. [ 33 ] Other reported modulation bandwidth of single wavelength QD laser integrated on a Si substrate is in the range of 4–7.5 GHz.…”
Section: Measurement and Analysismentioning
confidence: 99%
“…However, due to the finite intraband relaxation time and gain saturation effect, even a moderate modulation bandwidth has been recognized as difficult to attain for QD lasers. [ 32 ] To date, the best reported modulation bandwidth of 1.3 µm QD DFB lasers grown on native substrates was limited to around 10 GHz, obtained with high‐reflective (HR)/antireflective (AR) coatings to the front and the rear facets, respectively. [ 33 ] Other reported modulation bandwidth of single wavelength QD laser integrated on a Si substrate is in the range of 4–7.5 GHz.…”
Section: Measurement and Analysismentioning
confidence: 99%
“…The QD laser's energy structure is modelled as a coupled electronic system consisting of barrier layer, wetting layer and two discrete QD states, i.e. the ground state and excited state, respectively 12,13 . Although the barrier layer is often neglected due to their very small impact on the QD dynamics, we choose to include it for consistency with the QW simulations and due to the importance of dislocationinduced carrier loss in the continuum states.…”
Section: Theoretical Modelmentioning
confidence: 99%
“…where , , ℎ , and  are the maximum QD material gain, the electron and hole ground state occupation probability, and the gain compression factor 12 , and g0 and Ntr are the gain constant and the carrier number per laser section at transparency 21 , respectively.…”
Section: Theoretical Modelmentioning
confidence: 99%
“…Simulations and analysis suggest that there are two main reasons for the broadened pulse width: a limited gain from InAs QDs and a high gain compression factor. Therefore, it is believed that the optical applications of Si-based QD lasers could be significantly improved by increasing the number of active layers, introducing the p-doping in the active region as well as modifying the devices' geometry [50] .…”
Section: Fp Lasers On Off Cut Si Substratementioning
confidence: 99%