Molecular beam epitaxial growth of III-V semiconductor ... - KOBRA

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REFERENCES [8] J. M. Gerard, O. Cabrol, and B. Sermage: InAs quantum boxes: Highly ecient radiative traps for light emitting devices on Si, Applied Physics Letters 68, P. 3123-3125 (1996) [9] T. Wang, H. Liu, A. Lee, F. Pozzi, and A. Seeds: 1.3 µm InAs/GaAs quantumdot lasers monolithically grown on Si substrates, Optics express 19, P. 11381- 11386 (2011) [10] H. Park, M. Sysak, H. Chen, A. Fang, D. Liang, L. Liao, B. R. Koch, J. Bovington, and Y. Tang: Device and Integration Technology for Silicon Photonic Transmitters, IEEE Journal of Selected Topics in Quantum Electronics 17, P. 671-688 (2011) [11] P. Yeh, A. E. T. Chiou, J. Hong: Optical interconnection using photorefractive dynamic holograms, Applied Optics 27, P. 2093-2096 (1989) [12] Z. Zhao, Z. Hao, K. Yadavalli, K. L. Wang, and A. P. Jacob: Optical properties of InAs quantum dots grown on patterned Si with a thin GaAs buer layer, Applied Physics Letters 92, 083111 (2008) [13] S. Anwar, M. Yasin, A. Raja, S. Qazi, and M. Ilyas (editors): Nanotechnology for Telecommunications, CRC Press Taylor & Francis Group, (2010) [14] M. E. Gronert: Monlithic Heteroepitaxial Integration of III-V semiconductor Lasers, Dissertation, Massachusetts Institue of Technology (MIT), (2002) [15] B. Sapoval, C. Hermann, Ellipses Paris (editor): Physics of Semiconductor, Spriner-Verlag, (1988) [16] T. Mano, H. Fujioka , K. Ono , Y. Watanabe , M. Oshima: InAs nanocrystal growth on Si (100), Applied Surface Science 130-132, P. 760-764 (1998) [17] Z. M. Zhao , O. Hulko, H. J. Kim, J. Liu, T. Sugahari, B. Shi, Y. H. Xie: Growth and characterization of InAs quantum dots on Si (001) substrates, Journal of crystal growth 271, P. 450-455 (2004) 130
REFERENCES [18] J. M. Martínez-Duart, R. J. Martín-Palma, F. Agulló-Rueda: Nanotechnology for Microelectronics and Optoelectronics, Elsevier Inc., (2006) [19] B. J.Thompson, J. W. Haus, V. B. Shoenoy , and A. Lakhthakia (editor): NANOMETER STRUCTURES: Theory, Modeling, and Simulation, SPIE - The International Society for Optical Engineering, (2004) [20] C. J. Gilfert: High-Speed Semiconductor Lasers based on Low-Dimensional Active Materials for Optical Telecommunication, Dissertation, University of Kassel, (2012) [21] D. Bimberg, M. Grundmann, and N. N. Ledentsov (editor): Quantum Dot Hetrostructures, John Wiley & Sons West Sussex UK, (1999) [22] T. Steiner: Semiconductor Nanostructures for Optoelectronic Applications, Artech House, Inc. London, (2004) [23] M. Fox: Optical Properties of Solids, Oxford University Press, (2001) [24] P. Yu, M. Cardona: Fundamentals of Semiconductors: Physics and Materials Properties, Springer, (2005) [25] J. Sole, L. Bausa, and D. Jaque: An Introduction to the Optical Spectroscopy of Inorganic Solids, Wiley, (2005) [26] G. T. Einevoll: Connement of excitons in quantum dots, Physical Review B 45, P. 3410-3417 (1992) [27] L. E. Brus: Electron-electron and electron-hole interactions in small semiconductor crystallites: The size dependence of the lowest excited electronic state, Journal of Chemical Physics 80, 4403 (1984) [28] K. Yosuke and M. Hiroshi: Incomplete connement of electrons and holes in microcrystals, Physical Review B 41, P. 10261-10263 (1990) 131
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Molecular Beam Epitaxial Growth of
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Gutachter (Supervisors): 1. Prof. D
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patterns indicating a 2D smooth sur
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(MEE = migration enhance epitaxy) u
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CONTENTS 3.4.4 Planar Defects Assoc
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CONTENTS xii
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Introduction thesis a detailed stud
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Introduction 1.1.2 Thesis Approach
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Introduction 1.2 Thesis Outline The
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Theoretical Background of Semicondu
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Heteroepitaxial Growth of III-V Sem
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Experimental Growth and Characteriz
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MBE Growth of Self-Assembled InAs a
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Page 146 and 147: REFERENCES [29] http://www.wmi.badw
Page 148 and 149: REFERENCES [49] M. R. Brenner: GaP/
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Page 152 and 153: REFERENCES [84] A. Garcia, C. M. Ma
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Page 156 and 157: REFERENCES [116] H. Usui, H. Yasuda
Page 158 and 159: REFERENCES [133] Grassman, T. J. Br
Page 160 and 161: Conferences Contributions: Tariq Al
Page 162 and 163: Nomenclature
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Molecular beam epitaxial growth of III-V semiconductor ... - KOBRA

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