Itinerant Spin Dynamics in Structures of ... - Jacobs University

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120 Bibliography [Fro01] [GF97] [GGB + 07] [GI02] [GI04] [GKD04] [Gol05] [Gru00] [HLN80] [HNA + 99] [HPB + 97] V. A. Froltsov. Diffusion of inhomogeneous spin distribution in a magnetic field parallel to interfaces of a III-V semiconductor quantum well. Phys. Rev. B, 64(4):045311, Jun 2001. Claudio Grimaldi and Peter Fulde. Theory of screening of the phononmodulated spin-orbit interaction in metals . Phys. Rev. B, 55(23):15523– 15530, Jun 1997. S. Giglberger, L. E. Golub, V. V. Bel’kov, S. N. Danilov, D. Schuh, C. Gerl, F. Rohlfing, J. Stahl, W. Wegscheider, D. Weiss, W. Prettl, and S. D. Ganichev. Rashba and dresselhaus spin splittings in semiconductor quantum wells measured by spin photocurrents. Phys. Rev. B, 75(3):035327, Jan 2007. M. M. Glazov and E. L. Ivchenko. Precession spin relaxation mechanism caused by frequent electron-electron collisions. Jetp Lett., 75:403, 2002. M. M. Glazov and E. L. Ivchenko. Effect of electron-electron interaction on spin relaxation of charge carriers in semiconductors. J. Exp. and Theoret. Phys., 99:1279, 2004. Alexander O. Govorov, Alexander V. Kalameitsev, and John P. Dulka. Spindependent transport of electrons in the presence of a smooth lateral potential and spin-orbit interaction. Phys. Rev. B, 70(24):245310, Dec 2004. L. E. Golub. Weak Antilocalization in High-Mobility Two-Dimensional Systems. Phys. Rev. B, 71(23):235310, 2005. Dirk Grundler. Large Rashba Splitting in InAs Quantum Wells due to Electron Wave Function Penetration into the Barrier Layers. Phys. Rev. Lett., 84(26):6074–6077, Jun 2000. ShinobuHikami, Anatoly I. Larkin, and Yosuke Nagaoka. Spin-Orbit Interaction and Magnetoresistance in the Two Dimensional Random System. Prog. Theor. Phys., 63(2):707–710, 1980. Can-Ming Hu, Junsaku Nitta, Tatsushi Akazaki, Hideaki Takayanagi, Jiro Osaka, P. Pfeffer, and W. Zawadzki. Zero-field spin splitting in an inverted In 0.53 Ga 0.47 As/In 0.52 Al 0.48 As heterostructure: Band nonparabolicity influence and the subband dependence. Phys. Rev. B, 60(11):7736–7739, Sep 1999. T Hassenkam, S Pedersen, K Baklanov, A Kristensen, C B Sorensen, P E Lindelof, F G Pikus, and G E Pikus. Spin splitting and weak localization in (110) GaAs/AlxGa1-xAs quantum wells. Phys. Rev. B, 55(15):9298–9301, 1997.
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Itinerant Spin Dynamics in Structur
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Itinerant Spin Dynamics in Structur
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Contents v 3.2.2 Weak Localization
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Citations to Previously Published W
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Dedicated to Linda, my parents and
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Chapter 1 Introduction Structure of
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Chapter 1: Introduction 3 the coupl
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Chapter 1: Introduction 5 Throughou
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Chapter 2: Spin Dynamics: Overview
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Chapter 3 WL/WAL Crossover and Spin
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Chapter 3: WL/WAL Crossover and Spi
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Chapter 4 Direction Dependence of S
Page 79 and 80: Chapter 4: Direction Dependence of
Page 93 and 94: Chapter 5 Spin Hall Effect 5.1 Intr
Page 95 and 96: Chapter 5: Spin Hall Effect 85 curr
Page 97 and 98: Chapter 5: Spin Hall Effect 87 with
Page 99 and 100: Chapter 5: Spin Hall Effect 89 1.0
Page 101 and 102: Chapter 5: Spin Hall Effect 91 as s
Page 103 and 104: Chapter 5: Spin Hall Effect 93 V⩵
Page 105 and 106: Chapter 5: Spin Hall Effect 95 0.4
Page 107 and 108: Chapter 5: Spin Hall Effect 97 oper
Page 109 and 110: Chapter 5: Spin Hall Effect 99 the
Page 111 and 112: Chapter 5: Spin Hall Effect 101 str
Page 113 and 114: Chapter 5: Spin Hall Effect 103 Com
Page 115 and 116: Chapter 5: Spin Hall Effect 105 Fin
Page 117 and 118: Chapter 6: Critical Discussion and
Page 119 and 120: Chapter 6: Critical Discussion and
Page 121 and 122: List of Figures 111 3.3 Exemplifica
Page 123 and 124: List of Figures 113 4.2 The spin de
Page 125 and 126: List of Tables 3.1 Singlet and trip
Page 127 and 128: Bibliography 117 [BB04] [BBF + 88]
Page 129: Bibliography 119 [DP71b] [DP71c] [D
Page 133 and 134: Bibliography 123 [MACR06] T. Mickli
Page 135 and 136: Bibliography 125 [PMT88] [PP95] [PT
Page 137 and 138: Bibliography 127 [Tor56] H. C. Torr
Page 139 and 140: Appendix A SOC Strength in the Expe
Page 141 and 142: Appendix A: SOC Strength in the Exp
Page 143 and 144: Appendix B: Linear Response 133 in
Page 145 and 146: Appendix B: Linear Response 135 Pro
Page 147 and 148: Appendix C Cooperon and Spin Relaxa
Page 149 and 150: Appendix C: Cooperon and Spin Relax
Page 157 and 158: Appendix D: Hamiltonian in [110] gr
Page 159 and 160: Appendix E: Summation over the Ferm
Page 161: Appendix F: KPM 151 integer running
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