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Although nonlinear waves occur in nearly all branches of physics and engi neering, there is an amazing degree of agreement about the fundamental con cepts and the basic paradigms. The underlying unity of the theory for linearized waves is already well-established, with the importance of such universal concepts as group velocity and wave superposition. For nonlinear waves the last few decades have seen the emergence of analogous unifying comcepts. The pervasiveness of the soliton concept is amply demonstrated by the ubiquity of such models as the Korteweg-de Vries equation and the nonlinear Schrodinger equation. Similarly, there is a universality in the study of wave-wave interactions, whether determin istic or statistical, and in the recent developments in the theory of wave-mean flow interactions. The aim of this text is to present the basic paradigms of weakly nonlinear waves in fluids. This book is the outcome of a CISM Summer School held at Udine from September 20-24, 2004. . Like the lectures given there the text covers asymptotic methods for the derivation of canonical evolution equations, such as the Kortew- de Vries and nonlinear Schrodinger equations, descriptions of the basic solution sets of these evolution equations, and the most relevant and compelling applica tions. These themes are interlocked, and this will be demonstrated throughout the text . The topics address any fluid flow application, but there is a bias towards geophysical fluid dynamics, reflecting for the most part the areas where many applications have been found.
Engineering. --- Engineering Fluid Dynamics. --- Math. Applications in Geosciences. --- Applications of Mathematics. --- Mathematical Methods in Physics. --- Fluids. --- Continuum Mechanics and Mechanics of Materials. --- Mathematics. --- Mathematical physics. --- Materials. --- Hydraulic engineering. --- Ingénierie --- Mathématiques --- Physique mathématique --- Fluides --- Matériaux --- Technologie hydraulique --- Fluid dynamics. --- Nonlinear wave equations. --- Nonlinear waves. --- Wave-motion, Theory of. --- Nonlinear waves --- Fluid dynamics --- Wave-motion, Theory of --- Nonlinear wave equations --- Engineering & Applied Sciences --- Civil & Environmental Engineering --- Applied Mathematics --- Civil Engineering --- Undulatory theory --- Earth sciences. --- Applied mathematics. --- Engineering mathematics. --- Physics. --- Continuum mechanics. --- Fluid mechanics. --- Earth Sciences, general. --- Fluid- and Aerodynamics. --- Mechanics --- Wave equation --- Dynamics --- Fluid mechanics --- Nonlinear theories --- Waves --- Geography. --- Mechanics. --- Mechanics, Applied. --- Solid Mechanics. --- Engineering, Hydraulic --- Engineering --- Hydraulics --- Shore protection --- Applied mechanics --- Engineering, Mechanical --- Engineering mathematics --- Classical mechanics --- Newtonian mechanics --- Physics --- Quantum theory --- Physical mathematics --- Math --- Science --- Cosmography --- Earth sciences --- World history --- Mathematics --- Hydrostatics --- Permeability --- Natural philosophy --- Philosophy, Natural --- Physical sciences --- Engineering analysis --- Mathematical analysis --- Geosciences --- Environmental sciences --- Hydromechanics --- Continuum mechanics
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The dynamics of flows in density-stratified fluids has been and remains now an important topic for scientific enquiry. Such flows arise in many contexts, ranging from industrial settings to the oceanic and atmospheric environments. It is the latter topic which is the focus of this book. Both the ocean and atmosphere are characterised by the basic vertical density stratification, and this feature can affect the dynamics on all scales ranging from the micro-scale to the planetary scale. The aim of this book is to provide a “state-of-the-art” account of stratified flows as they are relevant to the ocean and atmosphere with a primary focus on meso-scale phenomena; that is, on phenomena whose time and space scales are such that the density stratification is a dominant effect, so that frictional and diffusive effects on the one hand and the effects of the earth’s rotation on the other hand can be regarded as of less importance. This in turn leads to an emphasis on internal waves.
Stratified flow. --- Geophysics. --- Physical geography. --- Environmental protection. --- Oceanography. --- Environmental Physics. --- Classical and Continuum Physics. --- Atmospheric Protection/Air Quality Control/Air Pollution. --- Environmental sciences. --- Continuum physics. --- Air pollution. --- Oceanography, Physical --- Oceanology --- Physical oceanography --- Thalassography --- Earth sciences --- Marine sciences --- Ocean --- Air --- Air contaminants --- Air pollutants --- Air pollution --- Air pollution control --- Air toxics --- Airborne pollutants --- Atmosphere --- Contaminants, Air --- Control of air pollution --- Pollutants, Air --- Toxics, Air --- Pollution --- Air quality --- Atmospheric deposition --- Classical field theory --- Continuum physics --- Physics --- Continuum mechanics --- Environmental science --- Science --- Control --- Field theory (Physics) --- Pollution.
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