Geodynamicsセミナー(その1, 輪読)


 2019年4月〜

 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



日程と担当(2019年度)

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 
   6.13の続き (p293まで)  兵藤 
   6.13の続き / 6.14 Stokes Flow (p296まで)  谷口 
   6.14 (p298まで)  Gang 



日程と担当(2018年度)

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 




Geodynamicsセミナー(その2, 学生セミナー)


 2018年1月〜

 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

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