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Geophysical & Astrophysical Convection PDF

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GEOPHYSICAL AND ASTROPHYSICAL CONVECTION THE FLUID MECHANICS OF ASTROPHYSICS AND GEOPHYSICS A series edited by ANDREW SOWARD, University of Exeter, UK and MICHAEL GHIL, University of California, Los Angeles, USA Founding Editor: PAUL ROBERTS, University of California, Los Angeles, USA Volume 1 SOLAR FLARE MAGNETOHYDRODYNAMICS Edited by E.R. Priest Volume 2 STELLAR AND PLANETARY MAGNETISM Edited by AM. Soward Volume 3 MAGNETIC FIELDS IN ASTROPHYSICS Ya.B. Zeldovich, AA Ruzmaikin and D.D. Sokoloff Volume 4 MANTLE CONVECTION: Plate Tectonics and Global Dynamics Edited by w.R. Peltier Volume 5 DIFFERENTIAL ROTATION AND STELLAR CONVECTION: Sun and Solar-Type Stars G. RUdiger Volume 6 TURBULENCE, CURRENT SHEETS AND SHOCKS IN COSMIC PLASMA S.l Vaintshtein, AM. Bykov and IN. Toptygin Volume 7 EARTH'S DEEP INTERIOR: The Doornbos Memorial Volume Edited by D.l. Crossley Volume 8 GEOPHYSICAL AND ASTROPHYSICAL CONVECTION Edited by P.A. Fox and R.M. Kerr This book is part of a series. The publisher will accept continuation orders which may be cancelled at any time and which provide for automatic billing and shipping of each title in the series upon publication. Please write for details. GEOPHYSICAL AND ASTROPHYSICAL CONVECTION Edited by PETER A. FOX National Center for Atmospheric Research Boulder, Colorado, USA and ROBERT M. KERR National Center for Atmospheric Research Boulder, Colorado, USA Contributions from a workshop sponsored by the Geophysical Turbulence Program at the National Center for Atmospheric Research, October 1995 GORDON AND BREACH SCIENCE PUBLISHERS Australia. Canada. France. Gennany • India. Japan Luxembourg. Malaysia. The Netherlands. Russia Singapore. Switzerland Copyright © 2000 OPA (Overseas Publishers Association) N.V. Published by license under The Gordon and Breach Science Publishers imprint. All rights reserved. No part of this book may be reproduced or utilized in any form or by any means, electronic or mechanical, including photocopying and recording, or by any information storage or retrieval system, without permission in writing from the publisher. Printed in Singapore. Amsteldijk 166 1st Floor 1079 LH Amsterdam The Netherlands British Library Cataloguing in Publication Data A catalogue record for this book is available from the British Library. ISBN: 90-5699-258-9 ISSN: 0260-4353 Contents List of Figures ix List of Tables xii Preface xiii Acknowledgements xiv 1. Atmospheric Convection with Analogies in Astrophysics and the Laboratory 15 Robert M. Kerr 1.1 Introduction 15 1.2 Reynolds number and modeling 17 1.3 Dry convective scaling 20 1.4 Precipitating convection 23 1.5 Hierarchy of scales 27 1.6 Improving LES 30 1.7 Conclusion 32 2. Solar and Stellar Convection: A Perspective for Geophysical Fluid Dynamicists 37 Peter A. Gilman 2.1 Introduction 38 2.2 Solar motions 39 2.3 Global features of convection zone 43 2.3.1 Structure with radius 43 2.3.2 Influence of rotation 45 2.3.3 Upper boundary layer 45 2.3.4 Lower boundary layer 46 2.3.5 Waves and instabilities in and near the convection zone 47 2.4 Simulating solar convection 48 2.5 Summary of methods and results for compressible convection 49 2.6 Convection as driver of differential rotation 51 2.7 Interaction of the convection zone with the solar surfaces and the shear layer at the base 52 2.8 Concluding remarks 54 3. Unsteady Non-Penetrative Thermal Convection From Non-Uniform Surfaces 59 Richard D. Keane, Noboyuki Fujisawa and Ronald J. Adrian 3.1 Introduction 59 3.2 Experimental apparatus and procedure 62 3.3 Results 65 3.3.1 Heat transfer characteristics 65 3.3.2 Existence of horizontal mean flow 67 3.3.3 Patterns of convection 67 3.4 Summary and conclusions 74 4. Astrophysical Convection and Dynamos 85 Axel Brandenburg, Ake Nordlund and Robert F. Stein 4.1 Introduction 85 4.2 Deep solar convection 87 4.3 Low Prandtl number effects 88 4.4 The entropy gradient 90 4.5 The thermal time scale problem 94 4.6 The formation of magnetic structures 97 4.7 Magnetic dynamo action 99 4.8 Downward pumping 100 4.9 Outstanding problems 101 5. Dynamics of Cumulus Entrainment 107 Wojciech W. Grabowski 5.1 Introduction 107 v vi CONTENTS 5.2 Turbulent entrainment in cumulus clouds and in buoyancy-driven flows 111 5.3 Entrainment as a result of interfacial instabilities 113 5.4 Entraiument and buoyancy reversal 121 5.5 Conclusions 123 6. The 2/7 Law in Turbulent Thermal Convection 129 Stephane Zaleski 6.1 Introduction 129 6.2 Problem definition 130 6.3 Simple approaches to scaling 131 6.3.1 Similarity arguments based on dimensional analysis 131 6.3.2 Marginal stability and boundary layer similarity 132 6.4 Mechanistic approaches to scaling 133 6.4.1 Inviscid interior scaling 133 6.4.2 Plume theories with a single length scale 134 6.4.3 Plume theory with several length scales 135 6.4.4 2/7 scaling: Shraiman-Siggia theory 136 6.4.5 Range of validity 136 6.5 Comparison with experiments 138 6.6 Critique 139 6.7 Conclusion 140 7. Organization of Atmospheric Convection over the Tropical Oceans: The Role of Vertical Shear and Buoyancy 145 Margaret A. LeMone 7.1 Introduction 145 7.2 Convection in the fair weather mixed layer 146 7.2.1 Larger aspect-ratio mixed-layer banded structures 149 7.3 Precipitating convection 152 7.3.1 Buoyancy 152 7.3.2 Shear 154 7.4 Conclusions 161 8. Images of Hard Turbulence: Buoyant Plumes in a Crosswind 165 Andrew Belrrwnte and Albert Libchaber 8.1 Introduction 165 8.2 Hard Turbulence 167 8.3 Experimental techniques 169 8.3.1 The convection cell 169 8.3.2 Visualization 170 8.3.3 bnage processing 172 8.4 Shadowgraph images 172 8.5 Intensity correlation measurements 177 8.6 Discussion 179 9. Convection in Cloud-Topped Atmospheric Boundary Layers 185 Christopher S. Bretherton 9.1 Introduction 185 9.2 Global distribution and importance of boundary layer cloud 186 9.3 Convective dynamics of CTBLs 190 9.4 Further observations and conclusions 195 10. Solar Granulation: A Surface Phenomenon 199 Mark Peter Rast 10.1 Introduction 200 10.2 Granular dynamics 201 10.3 Heat transport 207 10.4 Flow stability 211 10.5 Conclusion 216 11. Turbulent Convection: What has Rotation Taught Us? 221 Joseph Weme 11.1 Introduction 221 11.2 Nonrotating Rayleigh-Benard convection 222 11.3 Turbulent convection theories 223 CONTENTS vii 11.3.1 Priestley's theory 223 11.3.2 Kadanoff, Zaleski & Zanetti's theory 223 11.3.3 Shraiman & Siggia's theory 224 11.3.4 Cautionary comment on scaling theories 224 11.3.5 She's theory 225 11.3.6 Yakhot's theory 225 11.4 Rotating Rayleigh-Benard convection 226 11.5 Numerical simulation of rotating convection 226 11.5.1 Intermittent flow fields 227 11.5.2 Cyclonic plumes 227 11.5.3 Ekman pumping 227 11.5.4 Linear thermal Ekman layer 230 11.5.5 Nonlinear Ekman spirals 232 11.5.6 Plume-plume interactions 234 11.5.7 Rotating hard turbulence 235 11.6 Conclusions 236 12. Helical Buoyant Convection 241 Douglas Lilly 12.1 Rotating thunderstorms and tornadoes 241 12.2 Analysis and illustrations 244 12.3 Further discussion 250 13. Modeling Mantle Convection: A Significant Challenge in Geophysical Fluid Dynamics 257 David A. Yuen, S. Balachandar and U. Hansen 13.1 Introduction 258 13.2 Model and numerical techniques 259 13.2.1 Anelastic liquid model 260 13.2.2 Internal solid-state phase transitions 261 13.2.3 Thermal-chemical convection 262 13.2.4 Mantle rheology 263 13.2.5 Numerical methodologies 264 13.3 Past achievements and computational challenges 264 13.3.1 Sample past results 265 13.3.2 Computational requirements 268 13.4 Results 269 13.4.1 Viscous heating in mantle convection 269 13.4.2 High Rayleigh number thermal-chemical convection 271 13.5 Perspectives and future directions 273 14. Turbulent Transport in Rotating Compressible Convection 295 Nicholas H. Brummell 14.1 Introduction 295 14.2 Local modelling of rotating compressible convection 297 14.2.1 Turbulent transport of convective energy 299 14.2.2 Turbulent transport of (angular) momentum 302 14.3 Conclusions 306 15. Potential Vorticity, Resonance and Dissipation in Rotating Convective Turbulence 309 Peter Bartello 15.1 Background 310 15.2 Normal mode equations, conservation and resonance 312 15.2.1 The <GGG> interactions 314 15.2.2 The <AAA> interactions 314 15.2.3 The <GAA> interactions 314 15.2.4 The <GGA> interactions 314 15.3 Numerical Results 315 15.3.1 Metais et al. (1994) revisited 315 15.3.2 Simulations with large vertical dissipation 316 15.4 Conclusions 320 16. Numerical Simulations of Convection in Protostellar Accretion Disks 323 William Cabot 16.1 Introduction 323 16.1.1 What are protostellar accretion disks? 323 viii CONTENTS 16.1.2 Why is convection (potentially) important? 324 16.2 Properties of protostellar disks 326 16.2.1 General disk properties 326 16.2.2 Under what conditions do disks become convective? 326 16.2.3 Simplifying assumptions 327 16.3 Numerical hydrodynamic simulations 327 16.3.1 Further simplifying assumptions 327 16.3.2 Governing equations 329 16.3.3 Boundary conditions 330 16.3.4 Parameters 331 16.4 Simulation results 332 16.4.1 Incompressible simulations 332 16.4.2 Compressible simulations 332 16.5 Discussion 336 16.5.1 Why does disk convection generate inward transport of angular momentum? 339 16.5.2 What are the consequences? 340 16.5.3 What more needs to be done? 341 16.5.4 Conclusions 342 17. A New Model for Turbulence: Convection Rotation and 2D 345 V.M. Canuto, M.S. Dubovikov, A. Dienstfrey and D.J. Wielaard 17.1 Turbulent convection 345 17.1.1 New stochastic equations 345 17.1.2 Numerical results 347 17.1.3 Conclusions 347 17.2 Rotating turbulence 347 17 .2.1 Basic results 347 17.2.2 2D-3D states in rotating turbulence 352 17.2.3 Decaying turbulence 353 17.2.4 Conclusions 354 17.3 2D Turbulence 354 17.3.1 Basic features 354 17.3.2 Basic equations. Time evolution of the energy spectrum 354 17.3.3 Numerical results 355 17.3.4 Conclusions 357 18. Transport Using Transilient Matrices 363 Roland B. Stull and Jerzy Bartnicki 18.1 Introduction 363 18.2 A transilient turbulence parameterization 365 18.2.1 Mixing potential, Y, first estimate 366 18.2.2 Influences of nonlocal static stability 366 18.2.3 Convective overturning and subgrid turbulence 367 18.2.4 Unequal grid spacing 368 18.2.5 Transilient matrices 368 18.2.6 Use of transilient matrices 369 18.2.7 Turbulent flux and mixed-layer depth 369 18.3 Split time step and the destabilization problem 369 18.4 Calibration 371 18.5 lllustrative model 372 18.6 Simulation results for idealized scenarios 373 18.6.1 Neutral boundary layer 374 18.6.2 Unstable (free-convective) mixed layer 376 18.6.3 Mechanically mixed layer 377 18.6.4 Both buoyant and mechanically mixed layer 378 18.6.5 Stable boundary layer 378 18.6.6 Diurnal cycles of boundary layer forcings (including pollution dispersion) 380 18.6.7 Discussion 382 18.7 Conclusions 384 Index 389 List of Figures 1.1 Velocities from a Ra = 2 x 107, Prandtl number = 0.7, aspect ratio 6 direct simulation of Rayleigh-Benard convection 16 1.2 Huid motion in Rayleigh-Benard convection in the hard turbulence regime 22 1.3 Deep convection results for CAPE in the boundary layer 25 1.4 Huid motions near a squall line (SL) that maintain precipitation 26 2.1 High resolution photograph of solar granulation 40 2.2 Full disk dopplergram from MDI instrument on SOHO 41 2.3 Differential rotation linear velocity and mean meridional flow 42 2.4 Structure of the solar convection zone 44 2.5 Schematic of angular momentum balance within the solar convection zone 53 3.1 Test-section schematic 62 3.2 Temperature history for the resistance wire thermometer 63 3.3 Nusselt number vs. flux Rayleigh number 66 3.4 How visualization of non-penetrative thermal convection 68 3.5 How visualization of non-penetrative thermal convection 69 3.6 Planform flow visualization of convection 70 3.7 Planform flow visualizations of convection 71 3.8 Sections of thermal plumes 73 3.9 Temperature distributions 77 3.10 Temperature distributions 78 3.11 Temperature distributions through a thermal plume 79 3.12 Temperature distributions through a thermal plume 80 3.13 Temperature distributions through a thermal plume 81 3.14 Temperature distributions through a thermal plume 82 3.15 Temperature distributions through a thermal plume 83 3.16 Temperature distributions through a thermal plume 84 4.1 Contours of horizontal slices of the density fluctuation and the vertical velocity 89 4.2 Profiles of entropy and convective flux 91 4.3 Profiles of entropy and convective flux 92 4.4 Evolution of two downdrafts shown in the entropy 93 4.5 Horizontal slices of the temperature through a downdraft 93 4.6 Histograms of cosines of angles between eigenvectors 96 4.7 Cosines of angles between different vector fields 97 4.8 Power spectra of the kinetic and magnetic energy, temperature fluctuation, and kinetic and magnetic helicities 98 4.9 Snapshots of a strong magnetic flux tube 99 4.10 Evolution of magnetic and kinetic energy and magnetic Taylor microscale 100 4.11 Three-dimensional image of the magnetic energy density 101 4.12 Three-dimensional image of the enstrophy density 102 4.13 Three-dimensional visualisation of vorticity 103 5.1 Example of the lower-tropospheric sounding and analysis of convection 108 5.2 Results of the mixing analysis 110 5.3 Fields of the cloud water and the perturbation streamfunction 114 5.4 Three-dimensional perspective of the cloud water field 116 5.5 Profiles of the velocity tangential to the interface 117 5.6 Average buoyancy and shear production of perturbation kinetic energy 118 7.1 Structure of the fair weather tropical atmospheric boundary layer over the ocean 147 7.2 Radar-reflectivity patterns in the fair-weather boundary layer 148 7.3 Fair-weather banded structures over the tropical ocean 150 7.4 Schematic showing how mixed-layer convention induces gravity waves 151 7.5 Thermodynamic profiles for tropical convention 153 7.6 Updraft magnitudes over the tropical oceans 155 ix

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