Turcotte・Schubert (2002) Geodynamics, Cambridge Univ. Press
進め方:担当者がレジュメを作る
参加者:地球内部ダイナミクス・地球深部物理学で合同
6. Fluid Mechanics | ||
| 2019.4.23 | In this chapter / 6.1 Introduction / 6.2 One-Dimensional Channel Flows (p265まで) | 田中 |
| 2019.5.7 | 6.2の続き | 皆川 |
| 2019.5.14 | 6.3 Asthenospheric Counterflow | 藤島 |
| 2019.6.11 | 6.4 Pipe Flow | 兵藤 |
| 2019.6.18 | 6.5 Artesian Aquifer Flows / 6.6 Flow Throgh Volcanic Pipes / 6.7 Conservation of Fluid in Two Dimensions | 谷口 |
| 2019.6.25 | 6.8 Elemental Force Balance in Two Dimensions | Gang |
| 2019.7.2 | 6.9 The Stream Function / 6.10 Postglacial Rebound (p278まで) | 入江 |
| 6.10の続き (p280まで) | 中島 | |
| 2019.7.9 | 6.10の続き / 6.11 Angle of Subduction (p282まで) | 長 |
| 2019.7.16 | 6.11の続き / 6.12 Diapirism (p285まで) | 白山 |
| 2019.10.3 | 6.12の続き (p287まで) | 田中 |
| 6.12の続き (p289まで) | 皆川 | |
| 2019.10.10 | 6.13 Folding (p291まで) | 藤島 |
| 2019.11.21 | 6.13の続き (p293まで) | 兵藤 |
| 2019.12.5 | 6.13の続き / 6.14 Stokes Flow (p296まで) | 谷口 |
| 2019.12.19 | 6.14 (p298まで) | Gang |
2. Stress and Strain in Solids | ||
| 2018.4.24 | In this chapter / 2.1 Introduction | 長 |
| 2.2 Body Forces and Surface Forces, Problem 2.1の前まで | 白山 | |
| 2018.5.1 | Problem 2.1-3 | 2.1-3:田中 |
| 2.2, Problem 2.4の前まで | 田中 | |
| 2018.5.29 | Problem 2.4-6 | 2.4:兵藤, 2.5:田代, 2.6:眞鍋 |
| 2.2, Problem 2.7の前まで | 田代 | |
| 2018.6.5 | Problem 2.8 | 2.8:羽路 |
| 2.2, Problem 2.9の前まで | 眞鍋 | |
| 2018.6.19 | Problem 2.10, 12 | 2.10:谷口, 2.12:中島 |
| 2.3 Stress in Two Dimensions, Problem 2.13の前まで | 浪平 | |
| 2018.6.26 | Problem 2.13 | 2.13:入江 |
| 2018.7.10 | 2.3, Problem 2.15の前まで | 羽路 |
| 2.4 Stress in Three Dimensions | 兵藤 | |
| 2.5 Pressures in the Deep Interiors of Planets | 兵藤 | |
| 2018.7.17 | Problem 2.11 | 2.11:Gang |
| 2.7 Basic Ideas about Strain, Problem 2.21の前まで | 登尾 | |
| 2.7, ~ p.111 | 白山 | |
| 2018.7.31 | 2.7, p.111 ~ p.112 | 入江 |
| 2.7, p.112 ~ p.113, Problem 2.23 | 中島 | |
| 2018.10.11 | Problem 2.15 | 2.15:兵藤 |
| 2.6 Stress Mesurement | 田代 | |
| 2018.10.18 | Problem 2.9, 14, 16, 17, 20-22 | 2.9:登尾, 14:田中, 16:田代, 17:眞鍋, 20:登尾, 21:谷口, 22:Gang |
| 2.7, p.114 ~ p.115 | 長 | |
| 2018.10.25 | Problem 2.18, 19, 24- | 2.18:浪平, 19:羽路, 24:入江 |
| 2018.11.8 | Problem 2.18, 19, 24- | 2.25:田中, 26:兵藤 |
| 2.7, p.115 ~ 2.8: Strain Mesurements, p.118 | 兵藤 | |
| 2018.11.22 | 2.8, p.118 ~ p.120 | 田中 |
| 2018.11.29 | 2.8, p.121 ~ p.125 | 眞鍋 |
| 2018.12.6 | 2.8, p.125 ~ p.127 | 浪平 |
| 2018.12.13 | 2.8, p.128 ~ Summary | 羽路 |
| Problem 2.34 | 2.34:中島 | |
| 2018.12.20 | Problem 2.35 | 2.35:入江 |
Turcotte・Schubert (2002) Geodynamics, Cambridge Univ. Press
進め方:各自読んで、わからなかったところを議論
参加者:入江、中島
-----------------------------進行状況-----------------------------
1. Plate Tectonics | |
| 2018.1.25 | In this chapter / 1.1 Introduction |
| 2018.2.1 | 1.1の続き |
| 2018.2.8 | 1.2 The Lithosphere / 1.3 Accreting Plate Boundaries |
| 2018.2.15 | 1.3の続き |
| 2018.2.22 | 1.4 Subduction |
| 2018.3.1 | 1.4の続き |
| 2018.3.8 | 1.5 Transform Faults / 1.6 Hotspots and Mantle Plumes |
| 2018.3.15 | 1.7 Continents |
| 2018.3.22 | 1.8 Paleomagnetism and Motion of the Plates |
| 2018.3.29 | 1.8の続き |
| 2018.4.5 | 1.8の続き |
| 2018.4.12 | 1.9 Triple Junctions |
| 2018.4.19 | 1.10 The Wilson Cycle |
| 2018.4.26 | 1.11 Continental Collisions |
| 2018.5.3 | 1.12 Volcanism and Heat Flow |
| 2018.5.10 | 1.13 Seismicity and the State of Stress in the Lithosphere |
| 2018.5.21 | 1.14 The Driving Mechanism |
| 2018.5.31 | 1.15 Comparative Planetology |
| 2018.6.7 | 1.16 The Moon |
| 2018.6.14 | 1.16の続き |
| 2018.6.21 | 1.17 Merculy |
| 2018.6.28 | 1.18 Mars |
| 2018.7.5 | 1.18の続き |
| 2018.7.12 | 1.19 Phobos and Deimos / 1.20 Vesta |
| 2018.7.19 | 1.21 Venus |
| 2018.7.26 | 1.21の続き / 1.22 The Galilean Satellites |
| 2018.8.2 | 1.22の続き |
| 2018.8.9 | 1.23 Saturnian Satellites / Summary |
3. Elasticity and Flexure | |
| 2018.8.23 | In this chapter / 3.1 Introduction / 3.2 Linear Elasticity |
| 2018.8.30 | 3.3 Uniaxial Stress / 3.4 Uniaxial Strain |
| 2018.9.6 | 3.5 Plane Stress / 3.6 Plane Strain / 3.7 Pure Shear and Simple Shear / 3.8 Isotropic Stress |
| 2018.9.27 | 3.9 Two-Dimensional Bending or Flexure of Plates |
| 2018.10.4 | 3.10 Bending of Plates under Applied Moments and Vertical Loads |
| 2018.10.16 | 3.11 Buckling of a Plate under a Horizontal Load / 3.12 Deformation of Strata Overlying an Igneous Intrusion |
| 2018.10.23 | 3.13 Application to the Earth's Lithosphere / 3.14 Periodic Loading |
| 2018.10.30 | 3.15 Stability of the Earth's Lithosphere under an End Load |
| 2018.11.6 | 3.16 Bending of the Elastic Lithosphere under the Loads of Island Chains |
| 2018.11.13 | 3.17 Bending of the Elastic Lithosphere at an Ocean Trench |
| 2018.11.20 | 3.18 Flexure and the Structure of Sedimentary Basins / Summary |
4. Heat Transfer | |
| 2018.11.27 | In this chapter / 4.1 Introduction / 4.2 Fourier's Law of Heat Conduction |
| 2018.12.4 | 4.3 Measuring the Earth's Surface Heat Flux |
| 2018.12.11 | 4.4 The Earth's Surface Heat Flow |
| 2018.12.18 | 4.5 Heat Generation by the Decay of Radioactive Elements |
| 2018.12.25 | 4.6 One-Dimensional Steady Heat Conduction with Volumetric Heat Production |
| 2019.1.8 | 4.7 A Conduction Temperature Profile for the Mantle |
| 2019.1.15 | 4.8 Continental Geotherms |
| 2019.1.22 | 4.9 Radial Heat Conduction in a Sphere or Spherical Shell |
| 2019.1.29 | 4.10 Temperatures in the Moon / 4.11 Steady Two- and Three-Dimensional Heat Conduction |
| 2019.2.12 | 4.12 Subsurface Temperature Due to Periodic Surface Temperature and Topography |
| 2019.2.19 | 4.13 One-Dimensional, Time-Dependent Heat Conduction |
| 2019.2.26 | 4.14 Periodic Heating of a Semi-Infinite Half-Space: Diurnal and Seasonal Changes in Subsurface Temperature |
| 2019.3.5 | 4.15 Instantaneous Heating or Cooling of a Semi-Infinite Half-Space |
| 2019.3.19 | 4.16 Cooling of the Oceanic Lithosphere |
| 2019.3.26 | 4.17 Plate Cooling Model of the Lithosphere |
| 2019.4.2 | 4.18 The Stefan Problem |
| 2019.4.11 | 4.19 Solidification of a Dike or Sill |
| 2019.4.18 | 4.20 The Heat Conduction Equation in a Moving Medium: Thermal Effects of Erosion and Sedimentation |
| 2019.4.25 | 4.21 One-Dimensional, Unsteady Heat Conduction in an Infinite Region |
| 2019.5.2 | 4.22 Thermal Stresses |
| 2019.5.9 | 4.22の続き / 4.23 Ocean Floor Topography |
| 2019.5.16 | 4.24 Changes in Sea Level |
| 2019.6.6 | 4.25 Thermal and Subsidence History of Sedimentary Basins |
| 2019.6.13 | 4.25の続き |
| 2019.6.20 | 4.26 Heating or Cooling a Semi-Infinite Half-Space by Constant Surface Heat Flux |
| 4.27 Frictional Heating on Faults: Island Arc Volcanism and Melting on the Surface of the Descending Slab | |
| 2019.6.27 | 4.28 Mantle Geotherms and Adiabats |
| 2019.7.4 | 4.28の続き |
| 2019.7.11 | 4.29 Thermal Structure of the Subducted Lithosphere |
| 2019.7.18 | 4.30 Culling Model for the Erosion and Deposition of Sediments / Summary |
7. Rock Rheology | |
| 2019.7.25 | 7.1 Introduction / 7.2 Elasticity |
| 2019.8.1 | 7.2の続き |
| 2019.8.8 | 7.2の続き |
| 2019.8.15 | 7.2の続き |
| 2019.8.22 | 7.3 Diffusion Creep |
| 2019.8.29 | 7.3の続き |
| 2019.9.5 | 7.3の続き |
| 2019.9.12 | 7.3の続き |
| 2019.9.19 | 7.4 Dislocation Creep |
| 2019.9.26 | 7.5 Shear Flows of Fluids with Temperature- and Stress-Dependent Rheologies |
| 2019.9.27 | p.359, 360 |
| 2019.9.28 | p.361 |
| 2019.9.29 | p.362 |
| 2019.9.30 | p.363 |
| 2019.10.1 | p.364 / 7.6 Mantle Rheology |
| 2019.10.2 | p.365 |
| 2019.10.3 | p.366 |
| 2019.10.4 | p.367 |
| 2019.10.5 | p.368 |
| 2019.10.6 | p.369 / 7.7 Rheological Effects on Mantle Convection |
| 2019.10.7 | p.370 |
| 2019.10.8 | p.371 / 7.8 Mantle Convection and the Cooling of the Earth |
| 2019.10.9 | p.372 |
| 2019.10.10 | p.373 / 7.9 Crustal Rheology |
| 2019.10.11 | p.374 |
| 2019.10.12 | p.375 |
| 2019.10.13 | p.376 / 7.10 Viscoelasticity |
| 2019.10.14 | p.377 |
| 2019.10.15 | p.378 |
| 2019.10.16 | p.379 / 7.11 Elastic-Perfectly Plastic Behavior |
| 2019.10.17 | p.380 |
| 2019.10.18 | p.381 |
| 2019.10.19 | p.382 |
| 2019.10.20 | p.383 |
| 2019.10.21 | p.384 |
6. Fluid Mechanics [夏休み毎日1ページセミナー] | |
| 2019.8.9 | 6.12 Diapirism p.285 |
| 2019.8.10 | p.286 |
| 2019.8.11 | p.287 |
| 2019.8.12 | p.288 |
| 2019.8.13 | p.289 / 6.13 Folding |
| 2019.8.14 | p.290 |
| 2019.8.15 | p.291 |
| 2019.8.16 | p.292 |
| 2019.8.17 | p.293 |
| 2019.8.18 | p.294 |
| 2019.8.19 | p.295 / 6.14 Stokes Flow |
| 2019.8.20 | p.296 |
| 2019.8.21 | p.297 |
| 2019.8.22 | p.298 |
| 2019.8.23 | p.299 |
| 2019.8.24 | p.300 / 6.15 Plume Heads and Tails |
| 2019.8.25 | p.301 |
| 2019.8.26 | p.302 |
| 2019.8.27 | p.303 / 6.16 Pipe Flow with Heat Addition |
| 2019.8.28 | p.304 |
| 2019.8.29 | p.305 / 6.17 Aquifer Model for Hot Springs |
| 2019.8.30 | p.306 |
| 2019.8.31 | p.307 / 6.18 Thermal Convection |
| 2019.9.1 | p.308 |
| 2019.9.2 | p.309 / 6.19 Linear Stability Analysis for the onset of Thermal Convection in a Layer of Fluid Heated from Below |
| 2019.9.3 | p.310 |
| 2019.9.4 | p.311 |
| 2019.9.5 | p.312 |
| 2019.9.6 | p.313 / 6.20 A Transient Boundary-Layer Theory for Finite-Amplitude Thermal Convection |
| 2019.9.7 | p.314 |
| 2019.9.8 | p.315 |
| 2019.9.9 | p.316 / 6.21 A Steady-State Boundary-Layer Theory for Finite-Amplitude Thermal Convection |
| 2019.9.10 | p.317 |
| 2019.9.11 | p.318 |
| 2019.9.12 | p.319 |
| 2019.9.13 | p.320 |
| 2019.9.14 | p.321 |
| 2019.9.15 | p.322 |
| 2019.9.16 | p.323 / 6.22 The Forces that Drive Plate Tectonics |
| 2019.9.17 | p.324 |
| 2019.9.18 | p.325 |
| 2019.9.19 | p.326 / 6.23 Heating by Viscous Dissipation |
| 2019.9.20 | p.327 |
| 2019.9.21 | p.328 / 6.24 Mantle Recycling and Mixing |
| 2019.9.22 | p.329 |
| 2019.9.23 | p.330 |
| 2019.9.24 | p.331 |
| 2019.9.25 | p.332 |
| 2019.9.26 | p.333 / Summary |