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Utilizing electromagnetically induced transparency in InAs quantum dots for all-optical transistor design

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Utilizing electromagnetically induced transparency in InAs quantum dots for all-optical transistor design

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Optical properties of In(Ga)As/GaAs quantum dot-based devices emitting at 1.3[mu]m

Site- and energy-controlled pyramidal quantum dot heterostructures

Tuning InAs/GaAs quantum dot properties under Stranski-Krastanov growth mode for 1.3 mu m applications

Photorécepteurs 1,3-1,55 µm obtenus par intégration monolithique de photodiodes p-i-n et de transistors HEMT

Characterization of Lattice-Matched Single In1-Xgaxasyp1-Y Quantum-Wells Grown by Conventional Liquid-Phase Epitaxy

Optical properties of In(Ga)As/GaAs quantum dot-based devices emitting at 1.3[mu]m

Tuning InAs/GaAs quantum dot properties under Stranski-Krastanov growth mode for 1.3 mu m applications

Photorécepteurs 1,3-1,55 µm obtenus par intégration monolithique de photodiodes p-i-n et de transistors HEMT

Site- and energy-controlled pyramidal quantum dot heterostructures

Characterization of Lattice-Matched Single In1-Xgaxasyp1-Y Quantum-Wells Grown by Conventional Liquid-Phase Epitaxy