𝔖 Scriptorium
✦   LIBER   ✦
πŸ“

Mesoscale-Convective Processes in the Atmosphere

✍ Scribed by Robert J. Trapp

Year
2013
Tongue
English
Leaves
379
Category
Library
⬇  Acquire This Volume

No coin nor oath required. For personal study only.

✦ Table of Contents

Cover......Page 1
MESOSCALE-CONVECTIVE PROCESSES IN THE ATMOSPHERE......Page 4
Β©......Page 5
Contents......Page 6
Preface......Page 8
1.1 Introduction......Page 10
1.2 Historical Perspectives......Page 12
1.3 Atmospheric-Scale Classification Schemes......Page 15
1.4 Mesoscale-Convective Processes......Page 16
2.1.1 Equations......Page 20
2.1.2 Scale Analysis......Page 22
2.1.3 Approximations to the Mass Continuity Equation......Page 25
2.1.4 Inclusion of Moisture......Page 27
2.1.5 Equations for Water Substance......Page 30
2.2 Atmospheric Waves and Oscillations......Page 31
2.2.1 Acoustic Waves......Page 33
2.2.2 Rossby Waves......Page 35
2.2.3 Gravity Waves......Page 36
2.3.1 Gravitational Instability......Page 39
2.3.2 Rayleigh-BΓ©nard Instability......Page 40
2.3.2 Kelvin-Helmholtz Instability......Page 43
2.4 Density Currents......Page 47
Supplementary Information......Page 50
3.1 Introduction......Page 52
3.2.1 Surface......Page 54
3.2.2 Upper-Air Observations......Page 57
3.3 Report-Based Observations of Hazardous Convective Weather......Page 60
3.4.1.1 Overview of Basic Operations......Page 62
3.4.1.2 Retrievals from Multiple Doppler Radars......Page 65
3.4.1.3 Mobile Radar Systems......Page 69
3.4.1.4 Polarimetric Weather Radar......Page 70
3.4.1.5 Wind Profilers......Page 73
3.4.2.1 Overview of Basic Operations......Page 74
3.4.2.2 Radiative Transfer Theory and Satellite Retrievals......Page 76
3.4.2.3 Satellite Applications......Page 80
3.5 Observation Networks......Page 81
3.6.1 Function Fitting......Page 87
3.6.2 Empirical Analysis: Successive Corrections Method......Page 89
Supplementary Information......Page 94
4.1 Introduction......Page 97
4.2.1 Continuous Equations......Page 98
4.2.2 Numerical Approximations......Page 102
4.3.1 Subgrid Scale Turbulence......Page 105
4.3.2 The Land Surface and Atmospheric Boundary Layer......Page 109
4.3.3 Cloud and Precipitation Microphysics......Page 112
4.3.4 Atmospheric Radiation......Page 118
4.3.5 Convective Clouds......Page 119
4.4.1 Initial and Boundary Conditions......Page 121
4.4.2 Data Assimilation......Page 122
4.4.3 Other Design Issues......Page 125
Supplementary Information......Page 127
5.1 Parcel Theory......Page 154
5.2 Synoptic-Scale Conditioning of the Convective Environment......Page 159
5.3 Mechanisms of Local or Near-Field Mesoscale Lift......Page 164
5.3.1 Orographic Lifting......Page 165
5.3.2 Horizontal Convective Rolls......Page 166
5.3.3 Internal Gravity Wave-HCR Interaction......Page 169
5.4.1 Frontogenesis......Page 171
5.4.2 The Dryline......Page 175
5.4.3 The Sea-Breeze Front......Page 180
5.5 Lifting Mechanisms from Nonlocal Sources......Page 182
5.5.1 Convective-Storm Gust Fronts......Page 183
5.5.2 Gravity Waves......Page 187
5.5.3 Atmospheric Bores......Page 190
Supplementary Information......Page 192
6.1 Overview of the Convective Storm Spectrum......Page 195
6.2.1 Updrafts......Page 196
6.2.2 Downdrafts......Page 208
6.3 Convective Outflow......Page 215
6.4 Unicellular Convective Storms......Page 221
6.5 Multicellular Convective Storms......Page 223
Supplementary Information......Page 225
7.1 Characteristics of Supercell Thunderstorms: An Overview......Page 228
7.2 Midlevel Mesocyclogenesis in an Early-Stage Supercell......Page 232
7.3 Supercell Dynamics......Page 236
7.3.2 Case of Curved Hodographs......Page 238
7.3.3 The Linear-Dynamic Pressure Forcing......Page 241
7.3.4 Development of Net Updraft Rotation......Page 245
7.3.5 Storm-Relative Environmental Helicity......Page 246
7.4 Interaction of Wind Field and Precipitation......Page 250
7.5 Low-Level Mesocyclogenesis......Page 252
7.6 Tornadogenesis......Page 256
7.7 Supercell Environment Quantification......Page 261
7.8 Analogues in Tropical Convection: Vortical Hot Towers......Page 262
Supplementary Information......Page 264
8.1 Overview of MCS Characteristics and Morphology......Page 266
8.2.1 The Rotunno-Klemp-Weisman Theory......Page 272
8.2.2 The Rear Inflow......Page 277
8.2.3 The Presence of a Nocturnal Stable Atmospheric Boundary Layer......Page 280
8.2.4 Movement......Page 282
B 8.3.1 Straight-Line Surface Winds from the RIJ......Page 284
8.3.2 Mesovortices (and Related Vortical Topics)......Page 287
8.3.3 Tornadoes......Page 293
8.3.4 Heavy Rainfall and Flash Flooding......Page 294
8.4 Mesoscale Convective Complex......Page 296
8.5 Environments......Page 298
Supplementary Information......Page 300
9.1 Introduction......Page 303
9.2 Boundaries......Page 304
9.3 Mesoscale-Convective Vortices......Page 306
9.4 Interaction between Deep Moist Convection and Synoptic-Scale Dynamics......Page 310
9.5.1 Soil Moisture-Rainfall Feedback......Page 314
9.5.2 Heterogeneities in the Land Surface......Page 318
9.6 Convective Processes and the Global Climate......Page 321
Supplementary Information......Page 325
10.1 Introduction......Page 328
10.2 On Predictability and Its Theoretical Limits......Page 329
10.3 Probabilistic Forecasts and Ensemble Prediction Systems......Page 336
10.4 Forecast Evaluation......Page 338
10.5 Forecast Strategies with Mesoscale Numerical Models......Page 345
10.6 Long-Range Prediction......Page 348
Supplementary Information......Page 353
References......Page 356
Index......Page 376

πŸ“œ SIMILAR VOLUMES

Mesoscale-Convective Processes in the At
πŸ“ Mesoscale-Convective Processes in the Atmosphere
✍ Robert J. Trapp πŸ“‚ Library πŸ“… 2013 πŸ› Cambridge University Press 🌐 English

This new textbook seeks to promote a deep yet accessible understanding of mesoscale-convective processes in the atmosphere. Mesoscale-convective processes are commonly manifested in the form of thunderstorms, which are fast evolving, inherently hazardous, and can assume a broad range of sizes and se

Atmospheric and Oceanic: Mesoscale Proce
πŸ“ Atmospheric and Oceanic: Mesoscale Processes
✍ T. N. Krishnamurti, L. Stefanova, L. Watson, S. Pattnaik (auth.), Maithili Shara πŸ“‚ Library πŸ“… 2007 πŸ› BirkhΓ€user Basel 🌐 English

<p><P>Understanding, modeling and prediction of mesoscale processes in the atmosphere, ocean and environmental systems, have gained importance in the last decade or so. This is because of the availability of more sophisticated observational systems, provided by technological innovations and more rea

Atmospheric and Oceanic Mesoscale Proces
πŸ“ Atmospheric and Oceanic Mesoscale Processes
✍ Maithili Sharan, Sethu Raman πŸ“‚ Library πŸ“… 2007 πŸ› BirkhΓ€user Basel 🌐 English

Understanding, modeling and prediction of mesoscale processes in the atmosphere, ocean and environmental systems, have gained importance in the last decade or so. This is because of the availability of more sophisticated observational systems, provided by technological innovations and more realistic

Atmospheric and Oceanic Mesoscale Proces
πŸ“ Atmospheric and Oceanic Mesoscale Processes (Pageoph Topical Volumes)
✍ Maithili Sharan, Sethu Raman πŸ“‚ Library πŸ“… 2007 🌐 English

This volume contains many original findings on mesoscale processes in atmospheric and oceanic systems through mathematical modeling, numerical simulations and field experiments. These scientific papers examine and provide the latest developments on a range of topics that include tropical cyclones/hu

Diffusion and Transport of Pollutants in
πŸ“ Diffusion and Transport of Pollutants in Atmospheric Mesoscale Flow Fields
✍ Prof B. W. Atkinson (auth.), Albert Gyr, Franz-S. Rys (eds.) πŸ“‚ Library πŸ“… 1995 πŸ› Springer Netherlands 🌐 English

<p>In regions as densely populated as Western Europe, prediction of the ecological implications of pollutant transport are important in order to minimise damage in the case of accidents, and to evaluate the possible influence of existing or planned sources. In most cases, such predictions depend on