10. Appendix

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714 <strong>Appendix</strong> D D. J. Norris, A. Sacra, C. B. Murray, M. G. Bawendi: Measurement of the Size Dependent Hole Spectrum in CdSe Quantum Dots. Phys. Rev. Lett. 72, 2612–2615 (1994). A. I. Ekimov: Optical properties of oxide glasses doped by semiconductor nanocrystals. Radiation Effects and Defects in Solids, 134, 11–22 (1995). D. J. Norris, and M. G. Bawendi: Measurement and assignment of the sizedependent optical spectrum in CdSe quantum dots. Phys. Rev. B53, 16338– 16346 (1996). M. H. Huang, S. Mao, H. Feick, H. Q. Yan, Y. Y. Wu, H. Kind, E. Weber, R. Russo, P. D. Yang: Room-temperature ultraviolet nanowire nanolasers. Science, 292, 1897–1899 (2001). P. D. Yang: From nanowire lasers to quantum wire lasers. Proceedings of the SPIE – The International Society for Optical Engineering, 5349, 18–23 (2004). Phonon modes and Electron-Phonon Interaction in Quantum Wires and Quantum Dots M. C. Klein, F. Hache, D. Ricard, C. Flytzanis: Size dependence of electronphonon coupling in semiconductor nanospheres: The case of CdSe. Phys. Rev. B42, 11123–11132 (1990). S. Nomura, K. Takayoshi: Exciton–LO-phonon couplings in spherical semiconductor microcrystallites. Phys. Rev. B45, 1305–1316 (1992). T. Takagahara: Electron-phonon interactions and excitonic dephasing in semiconductor nanocrystals. Phys. Rev. Lett. 71, 3577–3580 (1993). P. A. Knipp, T. L. Reinecke: Effects of boundary conditions on confined optical phonons in semiconductor nanostructures. Phys. Rev. B48, 18037–18042 (1993). M. A. Stroscio, K. W. Kim, S. G. Yu, A. Ballato: Quantized acoustic phonon modes in quantum wires and quantum dots. J. Appl. Phys. 76, 4670–4675 (1994). E. Roca, C. Trallero-Giner, M. Cardona: Polar optical vibrational modes in quantum dots. Phys. Rev. B49, 13704–13711 (1994). Al. L. Efros, V. A. Kharchenko, M. Rosen: Breaking the Phonon bottleneck in nanometer Quantum Dots: Role of Auger-like Processes. Sol. State Commun. 93, 281–284 (1995). G. Tamulaitis, P. A. M. Rodrigues, P. Y. Yu: Screening of Longitudinal Optical Phonons by Carriers in Quantum Dots. Sol. State Commun. 95, 227–231 (1995). T. Itoh, M. Nishijima, A. I. Ekimov, C. Gourdon, Al. L. Efros, M. Rosen: Polaron and Exciton-Phonon Complexes in CuCl Nanocrystals. Phys. Rev. Lett. 74, 1645–1648 (1995). W. Cheng, S. F. Ren, P. Y. Yu: A Theoretical Investigation of the Surface Vibrational Modes in Germanium Nanocrystals. Phys. Rev. B68, 193309/1–4 (2003).
Chapter 9 715 S. F. Ren, W. Cheng, P. Y. Yu: Microscopic investigation of phonon modes in SiGe alloy nanocrystals. Phys. Rev. B69, 235327/1–8 (2004). Properties of Confined Excitons Y. Z. Hu, S. W. Koch, M. Lindberg, N. Peyghambarian: Theoretical and Experimental Results on Coulomb Effects in Semiconductor Quantum Dots. Phys. Stat. Sol. B 159, 249–257 (1990). M. G. Bawendi, W. L. Wilson, L. Rothberg, P. J. Carroll, T. M. Jedju, M. L. Steigerwald, L. E. Brus: Electronic structure and photoexcited-carrier dynamics in nanometer-size CdSe clusters. Phys. Rev. Lett. 65, 1623–1626 (1990). K. Shum, W. B. Wang, R. R. Alfano, K. M. Jones. Observation of the 1P excitonic states in Cd(S,Se)-glass quantum dots. Phys. Rev. Lett. 68, 3904–3907 (1992). J.-Y. Marzin, J.-M. Gérard, A. Izraël, and D. Barrier, G. Bastard: Photoluminescence of Single InAs Quantum Dots Obtained by Self-Organized Growth on GaAs. Phys. Rev. Lett. 73, 716–719 (1994). R. Rinaldi, R. Cingolani, M. Lepore, M. Ferrara, I. M. Catalano, F. Rossi, L. Rota, E. Molinari, P. Lugli, U. Marti, D. Martin, F. Morier-Gemoud, P. Ruterana, F. K. Reinhart: Exciton Binding Energy in GaAs V-Shaped Quantum Wires. Phys. Rev. Lett. 73, 2899–2902 (1994). C. R. M. de Oliveira, A. M. de Paula, F. O. Plentz Filho, J. A. Medeiros Neto, L. C. Barbosa, O. L. Alves, E. A. Menezes, J. M. M. Rios, H. L. Fragnito, C. H. Brito Cruz, C. L. Cesar: Probing of the quantum dot size distribution in CdTe-doped glasses by photoluminescence excitation spectroscopy. Appl. Phys. Lett. 66, 439–441 (1995). P. A. M. Rodrigues, G. Tamulaitis, P. Y. Yu, S. H. Risbud: Size selective Photoluminescence Excitation Spectroscopy in CdSe Nanocrystals. Sol. State Commun. 94, 583–587 (1995). M. Bayer, O. Stern, A. Kuther, A. Forchel: Spectroscopic study of dark excitons in InxGa1xAs self-assembled quantum dots by a magnetic-fieldinduced symmetry breaking. Phys. Rev. B61, 7273–7276 (2000). K. L. Teo, S. H. Kwok, P. Y. Yu, S. Guha: Quantum Confinement of the Quasi- Two-Dimensional E1 Excitons in Ge Nanocrystals Studied by Resonant Raman Scattering. Phys. Rev. B62, 1584–1587 (2000). Raman Scattering in Quantum Wires and Quantum Dots A. Tanaka, S. Onari, and T. Arai: Raman scattering from CdSe microcrystals embedded in a germanate glass matrix. Phys. Rev. B45, 6587–6592 (1992). J. J. Shiang, I. M. Craig, A. P. Alivisatos: Resonance Raman Depolarization in CdSe nanocrystals. Z. Phys. D26, 358–360 (1993). L. Saviot, B. Champagnon, E. Duval, A. I. Ekimov: Size-selective resonant Raman scattering in CdS doped glasses. Phys. Rev. B57, 341–346 (1998).
Page 1 and 2:
Appendix A: Pioneers of Semiconduct
Page 3 and 4:
Ultra-Pure Germanium 555 Ultra-Pure
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References Ultra-Pure Germanium 557
Page 7 and 8:
Two Pseudopotential Methods: Empiri
Page 9 and 10:
The Early Stages of Band-Structures
Page 11 and 12:
Cyclotron Resonance and Structure o
Page 13 and 14:
References Cyclotron Resonance and
Page 15 and 16:
Optical Properties of Amorphous Sem
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Optical Spectroscopy of Shallow Imp
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Page 21 and 22:
Page 23 and 24:
On the Prehistory of Angular Resolv
Page 25 and 26:
The Discovery and Very Basics of th
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The Birth of the Semiconductor Supe
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Number of papers 500 200 100 50 20
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Appendix B: Solutions to Some of th
Page 33 and 34:
Solution to Problem 2.6 585 transfo
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⎧ ⎫ 2apple ⎪⎨ cos (y z)
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Partial solution to Problem 2.8 589
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Page 41 and 42:
Page 43 and 44:
Solution to Problem 2.16 Solution t
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Solution to Problem 2.20 597 to the
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Therefore the result of I ′ on
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Solution to Problem 3.2(c) Solution
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Solution to Problem 3.5 603 Similar
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Solution to Problem 3.7 (b and c) 6
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u3. The above equation can be reduc
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Solution to Problem 3.8 (a, c and d
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Solution to Problem 3.11(a,b and c)
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Solution to Problem 3.16 613 (1) Al
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Solution to Problem 3.17 Solution t
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Solution to Problem 3.17 617 forces
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Solution to Problem 4.1 619 the abo
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C dz ′ z ′ i° Solution to Pro
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R -R A y E’-E y E’-E R x Soluti
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Solution to Problem 5.3(a) 625 tion
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Solution to Problem 5.5 627 To obta
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Ùm ∞ NLOq 0 2 apple dq 0 ∞
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plus Jz ·Fz Solution to Problem 5
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Solution to Problem 6.7 633 axes. F
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which can be found in standard text
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Solution to Problem 6.11 637 The co
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Solution to Problem 6.19(a) 639 if
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Solution to Problem 6.19(a) 641 k.
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Solution to Problem 6.19(a) 643 The
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Solution to Problem 6.21 645 by a s
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Solution to Problem 6.21 647 °25
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Equating the two expressions for Nn
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Solution to Problem 7.5 651 erties
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A Short Cut to the Calculation of t
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The diagram for the process labeled
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Solution to Problem 7.12 657 or sca
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Solution to Problem 8.1 Solution to
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Solution to Problem 8.9 661 of 19.5
Page 111 and 112: Solution to Problem 8.10 663 corres
Page 113 and 114: Solution to Problem 9.2 Solution to
Page 115 and 116: Solution to Problem 9.4 667 Table 9
Page 117 and 118: Solution to Problem 9.14 669 Again
Page 119: Solution to Problem 9.14 671 Note t
Page 122 and 123: 674 Appendix C A4.1.2 Historical Ba
Page 124 and 125: 676 Appendix C from the slopes of t
Page 126 and 127: 678 Appendix C Fig. A4.3 The electr
Page 128 and 129: 680 Appendix C Fig. A4.5 (a)-(d)The
Page 130 and 131: 682 Appendix C tion of alloying (se
Page 132 and 133: 684 Appendix C 17 -3 Hall Concentra
Page 135 and 136: Appendix D: Recent Developments and
Page 137 and 138: Chapter 1 689 ing up the glass to a
Page 139 and 140: Chapter 2 691 Popov, V. N., Lambin,
Page 141 and 142: Chapter 2 693 and zinc-blende group
Page 143 and 144: Chapter 3 695 Inelastic x-ray Scatt
Page 145 and 146: Chapter 4 697 results from a better
Page 147 and 148: Chapter 5 699 K. Alberi, K. M. Yu,
Page 149 and 150: Chapter 5 701 P. Ramvall, N. Carlss
Page 151 and 152: Chapter 6 Ab initio calculations of
Page 153 and 154: Chapter 6 705 Strain-induced birefr
Page 155 and 156: Chapter 7 707 S. Baroni, S. de Giro
Page 157 and 158: Chapter 7 709 W. Windl, K. Karch, P
Page 159 and 160: Chapter 8 711 Strain Shift Coeffici
Page 161: Chapter 9 713 Z. J. Zhao, F. Liu, L
Page 165: Chapter 9 717 V. P. Gusynin, S. G.
Page 168 and 169: 720 References tions II. Misfitting
Page 170 and 171: 722 References 2.30 R. M. Wentzcovi
Page 172 and 173: 724 References 3.23 R. M. Martin: E
Page 174 and 175: 726 References Nye J. F.: Physical
Page 176 and 177: 728 References Schubert E. F.: Dopi
Page 178 and 179: 730 References Ferry D. K.: Semicon
Page 180 and 181: 732 References 6.28 S. Logothetidis
Page 182 and 183: 734 References 6.73 H. D. Fuchs, C.
Page 184 and 185: 736 References 6.116 D. E. Aspnes:
Page 186 and 187: 738 References Chapter 7 7.1 W. Hei
Page 188 and 189: 740 References 7.43 G. Finkelstein,
Page 190 and 191: 742 References 7.82 J. R. Sandercoc
Page 192 and 193: 744 References 7.122 D. C. Reynolds
Page 194 and 195: 746 References 8.27 A. Goldmann, J.
Page 196 and 197: 748 References Electronic and Surfa
Page 198 and 199: 750 References 9.31 A. Pinczuk, G.
Page 200 and 201: 752 References 9.68 J. P. Palmier:
Page 203 and 204: Subject Index A ·-Sn (gray tin) 95
Page 205 and 206: C c(2 × 8)(111) surface of Ge - di
Page 207 and 208: Dielectric function 117, 246, 253,
Page 209 and 210: Emission rate vs frequency in Ge 34
Page 211 and 212: Galena (PbS) 1 Gamma-ray detectors
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Insulators 1 Integral quantum Hall
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- - vs T 222 - temperature dependen
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- frequency 253, 306, 335 - - of va
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Resonant Raman profile 403 Resonant
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- - LA phonons 512 - - LO phonons 5
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- structure 142 - symmetry operatio
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