The Physics of InAs Quantum Dot Lasers
Lasers incorporating self assembled quantum dot structures, in which the electrons' motion is confined in all three spatial directions, have already demonstrated significant performance advantages over the more conventional quantum well structures.
These include lower threshold current density, reduced temperature dependence, low alpha factor (in fact the alpha factor depends on the operating conditions - spread of carriers in the available states) and the extension of operating wavelength. The advantages of quantum dots lead to their use in applications as diverse as single photon emitters, essential for quantum key distribution, and high power lasers where the increased carrier localisation for example should lead to reduced catastrophic mirror damage. Even with this progress, fundamental behaviour, such as the mechanisms by which carriers distribute themselves among an ensemble of dots and the nature of many body interactions is still being debated and is critical for optimising device performance.
"Self assembled" or "self organised" quantum dots form when highly strained semiconductors grow epitaxially by the Stranski–Krastanow mode, in which 3-dimensional islands are formed after a few monolayers of 2-dimensional, layer-by-layer growth to minimise surface energy. The dimensions of the defect-free islands are of the order of the wavelength of the electron (the de Broglie wavelength), and provide three-dimensional quantum confinement of carriers. In(Ga)As self-organized quantum dots can lead to laser action in the wavelength range 920nm – 1.5µm.
Cyhoeddiadau
- Hutchings, M. et al. 2011. Temperature dependence of the gain peak in p-doped InAs quantum dot lasers. Applied Physics Letters 99 (15), pp.151118-151121. (10.1063/1.3652702)
- Sobiesierski, A. and Smowton, P. M. 2011. Quantum-dot lasers: physics and applications. In: Bhattacharya, P. , Fornari, R. and Kamimura, H. eds. Comprehensive Semiconductor Science and Technology: Volume 6: Devices and Applications. Burlington, VT: Elsevier. , pp.353-384. (10.1016/B978-0-44-453153-7.00034-1)
- O'Driscoll, I. et al. 2010. Many-body effects in InAs/GaAs quantum dot laser structures. Applied Physics Letters 97 (14) 141102. (10.1063/1.3496011)
- O'Driscoll, I. , Blood, P. and Smowton, P. M. 2010. Random population of quantum dots in InAs–GaAs laser structures. IEEE Journal of Quantum Electronics 46 (4), pp.525-532. (10.1109/JQE.2009.2039198)
- Smowton, P. M. and Blood, P. 2010. Quantum dot lasers: theory and experiment. In: Lee, E. et al., VLSI Micro- and Nanophotonics: Science, Technology, and Applications. Boca Raton, FL: CRC Press. , pp.9.1-9.35.
- O'Driscoll, I. , Smowton, P. M. and Blood, P. 2009. Low-temperature nonthermal population of InAs-GaAs quantum dots. IEEE Journal of Quantum Electronics 45 (4), pp.380-387. (10.1109/JQE.2009.2013869)
- Smowton, P. M. et al. 2008. Origin of temperature-dependent threshold current in p-doped and undoped in(Ga)As quantum dot lasers. IEEE Journal of Selected Topics in Quantum Electronics 14 (4), pp.1162-1170. (10.1109/JSTQE.2008.920040)
Tîm y prosiect
Project lead
Yr Athro Peter Smowton
Deputy Head of School and Director of Research
Tîm
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Honorary Distinguished Professor