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NSF Project: Semiconductor Technology for Nanoscale Lasers and Quantum Light Sources D.G. Deppe CREOL, College of Optics and Photonics, UCF Prof. Tomo.

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Presentation on theme: "NSF Project: Semiconductor Technology for Nanoscale Lasers and Quantum Light Sources D.G. Deppe CREOL, College of Optics and Photonics, UCF Prof. Tomo."— Presentation transcript:

1 NSF Project: Semiconductor Technology for Nanoscale Lasers and Quantum Light Sources D.G. Deppe CREOL, College of Optics and Photonics, UCF Prof. Tomo Yoshie Duke University Collaborating groups: Prof. C.K. Shih, UT Austin Prof. G. Solomo, Arkansas ---- Quantum dot formation is strain driven and wants to form larger size to increase surface area and provide greater strain relief

2 Motivations Work in the regime of where nanoscience can impact future technology through the quantum/classical interface: ---- High quality semiconductors ---- Quantum devices with room temperature capability ---- Photonic/electronic integration capability at the quantum level

3 Single QD Self-Aligned to a Microcavity
1.16 1.20 1.24 1.28 S P 5.5 K Energy (eV) x 1/3 400P0 X x 5 P0 6P0 11P0 43P0 XX 5 μm

4 Quantum Light Generation Using Resonance Flourescence - The Quantum Optical Modulator -with Shih and Salamo

5

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