
This graduate-level meteorology text and reference provides a scientifically rigorous description of the many types of convective circulations in the Earth's atmosphere. These range from small-scale, convectively driven turbulences in the boundary layer to precipitating systems covering many thousands of square kilometers. The text introduces the principal techniques used in understanding and predicting convective motion: theory, field experiment, and numerical modelling. Part I explores dry convection, including turbulent plumes and thermals from isolated buoyancy sources, Raleigh-Benard convection, and turbulent convection in the planetary boundary layer. Emphasis is placed on applying theoretical understanding and lessons from experiments. Part II offers a complete treatment of the thermodynamics of moist and cloudy air, including fundamental laws, conserved quantities, graphical techniques, and stability. Part III explores the characteristics of individual convective clouds, thunderstorms, squall lines, mesoscale convective systems, and slantwise convection. Part IV studies the ensemble effects of convective clouds, including stratocumulus at trade cumulus boundary layers and the representation of convective clouds in numerical models. Each chapter is followed by a set of exercises.
This text investigates the physical mechanisms and mathematical frameworks governing convective circulations within the Earth's atmosphere. Kerry A. Emanuel, a distinguished professor of atmospheric science, synthesizes decades of research to provide a rigorous analysis of convective motion. The book utilizes a combination of fluid dynamics theory, empirical data from field experiments, and computational numerical modeling to explain atmospheric phenomena ranging from small-scale turbulence to large-scale storm systems.
What You Will Find
Experts recognize this work as a foundational graduate-level text for students and researchers in meteorology. Readers frequently note the high level of mathematical and physical density required to fully grasp the presented concepts.
Page Count:
592
Publication Date:
1994-02-17
Publisher:
Oxford University Press
ISBN-10:
0195066308
ISBN-13:
9780195066302
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