Book contents
- Frontmatter
- Contents
- Foreword to the first edition
- Foreword to the second edition
- 1 Introduction
- 2 Linear waves and instabilities in infinite media
- 3 Convective and non-convective instabilities; group velocity in unstable media
- 4 A first look at surface waves and instabilities
- 5 Model equations for small amplitude waves and solitons; weakly nonlinear theory
- 6 Exact methods for fully nonlinear waves and solitons
- 7 Cartesian solitons in one and two space dimensions
- 8 Evolution and stability of initially one-dimensional waves and solitons
- 9 Cylindrical and spherical solitons in plasmas and other media
- 10 Soliton metamorphosis
- 11 Non-coherent phenomena
- Appendices
- References
- Author index
- Subject index
- Plate section
4 - A first look at surface waves and instabilities
Published online by Cambridge University Press: 05 June 2012
- Frontmatter
- Contents
- Foreword to the first edition
- Foreword to the second edition
- 1 Introduction
- 2 Linear waves and instabilities in infinite media
- 3 Convective and non-convective instabilities; group velocity in unstable media
- 4 A first look at surface waves and instabilities
- 5 Model equations for small amplitude waves and solitons; weakly nonlinear theory
- 6 Exact methods for fully nonlinear waves and solitons
- 7 Cartesian solitons in one and two space dimensions
- 8 Evolution and stability of initially one-dimensional waves and solitons
- 9 Cylindrical and spherical solitons in plasmas and other media
- 10 Soliton metamorphosis
- 11 Non-coherent phenomena
- Appendices
- References
- Author index
- Subject index
- Plate section
Summary
Introduction
One of the ironies of wave phenomena is that those waves which are most easily observed, such as waves on the surface of water, are more difficult to analyse theoretically than waves which propagate through a medium, such that their presence has to be inferred indirectly. Surface waves are more easily observed than bulk waves but mathematically it is more difficult to deal with them. The main reason for this is that for surface waves a boundary condition, such as continuity, must be satisfied at the surface of the wave which of course is not generally a simple plane. This was indicated briefly in the Introduction. Fortunately for linearized wave theory, the boundary condition has to be satisfied on the unperturbed surface which is usually planar. If the medium on either side of the boundary is homogeneous, the problem reduces to matching algebraic expressions at the interface. In this manner one obtains an algebraic dispersion relation for surface waves analogous to a bulk dispersion relation. However, in most practical situations the boundary is diffuse and this necessitates solving differential equations, with non-constant coefficients, for the behaviour perpendicular to the boundary. An algebraic dispersion relation is then replaced by an eigenvalue equation with a consequent increase in the difficulty of the problem.
The basic mathematical techniques are illustrated in Section 4.2 by considering the propagation of waves along the surface of a liquid.
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- Chapter
- Information
- Nonlinear Waves, Solitons and Chaos , pp. 59 - 81Publisher: Cambridge University PressPrint publication year: 2000