Detailansicht

InhaltsangabePart 1: Principle Ideas chap1: Basic equations chap2: Basic balances and stability chap3: Approximations of equations chap4: Waves chap5: Instability chap6: Forced motions chap7: Eddy transport chap8: Thermodynamics of moist air chap9: Basic equations of moist air chap10: Radiation process chap11: Turbulence Part 2: Atmospheric Structures chap12: Global budget chap13: Latitudinal energy balance chap14: Vertical structure chap15: Moist convection chap16: Lowlatitude circulations chap17: Circulations on the sphere chap18: Midlatitude circulations chap19: Global mixing Part 3: General Circulation Modeling chap20: Basic equations of the general circulation models chap21: Spectral method on the sphere chap22: Vertical discretization chap23: Time integration chap24: Global nonhydrostatic models chap25: Standard experiments of atmospheric general circulation models Appendix1: Transformation of coordinates Appendix2: Physical constants Appendix3: Meridional structure

General circulation models (GCMs), which define the fundamental dynamics of atmospheric circulation, are nowadays used in various fields of atmospheric science such as weather forecasting, climate predictions and environmental estimations. The Second Edition of this renowned work has been updated to include recent progress of high resolution global modeling. It also contains for the first time aspects of high-resolution global nonhydrostatis models that the author has been studying since the publication of the first edition. Some highlighted results from the Non-hydrostatic ICosahedral Atmospheric Model (NICAM) are also included. The author outlines the theoretical concepts, simple models and numerical methods for modeling the general circulation of the atmosphere. Concentrating on the physical mechanisms responsible for the development of large-scale circulation of the atmosphere, the book offers comprehensive coverage of an important and rapidly developing technique used in the atmospheric science. Dynamic interpretations of the atmospheric structure and their aspects in the general circulation model are described step by step. This book describes the methods used to construct general circulation models of the atmosphere, and how such models perform in applications relating to the real climate or environmental systems. The book is divided into three parts: Part 1 summarizes the physical processes involved, including basic equations, waves and instabilities; Part 2 covers atmospheric structures, including various types of one- and two-dimensional structures and circulations; and Part 3 describes the basic notions for construction of general circulation models of the atmosphere and their applications. Three appendices incorporate the basic data and mathematical formulae required to enable readers to construct GCMs for themselves.