Hydromagnetic waves in Earth's core and their influence on ...

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iAbstractIn this thesis east-west m
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iv2.5.3 Filter warm-up effects <str
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vi7.2.1 Governing
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viiiList of Figures1.1 The geomagne
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x5.5 Snapshots of ˜B r from DYN1 a
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xiiList of Tables6.1 Hydrom
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xiv̂φ Unit vector in</str
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xviĤ Time-averaged Ĥ˜H Time-ave
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xviiiu yu zVv nXx̂xxYŷyZẑzFlow
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xxAcknowledgementsI would like firs
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2 Chapter 1 — Introductionangle b
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4 Chapter 1 — Introductionseen by
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6 Chapter 1 — IntroductionThe ori
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8 Chapter 1 — IntroductionPoirier
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10 Chapter 1 — Introductionimport
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12 Chapter 1 — IntroductionRau et
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14 Chapter 1 — Introductionof geo
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16Chapter 2A space-time process<str
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18 Chapter 2 — Space-time analysi
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54Chapter 3Application of the space
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56 Chapter 3 — Historical field(a
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58 Chapter 3 — Historical field
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62 Chapter 3 — Historical field10
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68 Chapter 3 — Historical fieldTh
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70 Chapter 3 — Historical fieldso
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72 Chapter 3 — Historical fieldea
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78 Chapter 3 — Historical field40
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82 Chapter 4 — Archeomagnetic fie
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4.3.3 Hemispherical differences <st
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5.2.1 Radial magnetic field (B r )
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103 Chapter 5 — Dynamo model outp
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6.2 Survey of hydromagnetic wave li
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137 Chapter 6 — TheoryIn rapidly
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139 Chapter 6 — Theorywav
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141 Chapter 6 — TheoryProperties
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143 Chapter 6 — Theory6.5 Influen
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145 Chapter 6 — TheoryPlane wave
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147 Chapter 6 — Theory6.5.2 Full
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149 Chapter 6 — TheoryThe solutio
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151 Chapter 6 — Theory(i) Topogra
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153 Chapter 6 — Theoryfield where
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155 Chapter 6 — Theorythe length
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157 Chapter 6 — Theory(iii) Therm
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159 Chapter 6 — Theoryuniform bac
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161 Chapter 6 — Theorythermal Ros
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163 Chapter 6 — Theorybetween the
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165 Chapter 6 — Theoryfield becau
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167 Chapter 6 — Theorydue to the
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169 Chapter 6 — Theoryfocus<stron
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171 Chapter 7 — Lin</stro
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195 Chapter 8 — Wave flows8.2 1D
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197 Chapter 8 — Wave flowsthe fro
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199 Chapter 8 — Wave flowsso that
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201 Chapter 8 — Wave flows<strong
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203 Chapter 8 — Wave flowsbe cons
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205 Chapter 8 — Wave flows(a) U=1
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207 Chapter 8 — Wave flowsfor one
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209 Chapter 8 — Wave flowsIntegra
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211 Chapter 8 — Wave flowsField A
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213 Chapter 8 — Wave flows(a) m=8
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215 Chapter 8 — Wave flowsto aid
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217 Chapter 8 — Wave flowsthan th
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219 Chapter 8 — Wave flowssuite o
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221 Chapter 8 — Wave flows(a) Max
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223 Chapter 8 — Wave flows(a)B r
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229 Chapter 8 — Wave flowsFigure
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231 Chapter 8 — Wave flowsconcent
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Page 263 and 264: 241Chapter 9Conclusions and
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Page 267 and 268: 245 Chapter 9 — Conclusionsresolu
Page 269 and 270: 247 Chapter 9 — Conclusionsso lon
Page 271 and 272: 249Appendix AHistorical geomagnetic
Page 273 and 274: 251 Appendix A — gufm125000Freque
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Page 277 and 278: 255 Appendix A — gufm1(a) Annual
Page 279 and 280: 257 Appendix A — gufm1the secular
Page 281 and 282: 259Appendix BThe archeomagnetic fie
Page 283 and 284: 261 Appendix B — CALS7K.1Temporal
Page 285 and 286: B.5 Field modellin
Page 287 and 288: 265Appendix CA 3D, convection-drive
Page 289 and 290: 267 Appendix C — MAGICshell is re
Page 291 and 292: 269 Appendix C — MAGICmagnetic di
Page 293 and 294: 271 Appendix D — Governin
Page 295 and 296: 273 Appendix D — Governin
Page 297 and 298: 275 Appendix E — Symmetrywhile fo
Page 299 and 300: 277 Appendix E — SymmetryOn the o
Page 301 and 302: 279 Appendix F — AnimationsRefere
Page 303 and 304: 281 Appendix F — AnimationsRefere
Page 305: 283ReferencesAbramowitz, M. <strong
Page 309 and 310: 287 ReferencesDrazin</stron
Page 311 and 312: 289 ReferencesGubbin</stron
Page 313 and 314: 291 ReferencesJiang, W., Kuang, W.,
Page 315 and 316: 293 ReferencesMete Uz, B., Yoder, J
Page 317 and 318: 295 ReferencesSoward, A. M. Convect
Page 319: 297 ReferencesZhang, K. and
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