Book contents
- Frontmatter
- Contents
- Preface
- Notes on the text
- Acknowledgements
- Abbreviations
- Standard parameters and symbols
- Units and their symbols
- SI prefixes
- Approximate values of commonly used measures
- 1 Turbulence, heat and waves
- 2 Measurement of ocean turbulence
- 3 Turbulence in oceanic boundary layers
- 4 Turbulence in the ocean pycnocline
- 5 Turbulent dispersion
- 6 The energetics of ocean mixing
- References
- Index
- Answers
1 - Turbulence, heat and waves
Published online by Cambridge University Press: 05 June 2012
- Frontmatter
- Contents
- Preface
- Notes on the text
- Acknowledgements
- Abbreviations
- Standard parameters and symbols
- Units and their symbols
- SI prefixes
- Approximate values of commonly used measures
- 1 Turbulence, heat and waves
- 2 Measurement of ocean turbulence
- 3 Turbulence in oceanic boundary layers
- 4 Turbulence in the ocean pycnocline
- 5 Turbulent dispersion
- 6 The energetics of ocean mixing
- References
- Index
- Answers
Summary
Introduction
Turbulence is the dominant physical process in the transfer of momentum and heat, and in dispersing solutes and small organic or inorganic particles, in the lakes, reservoirs, seas, oceans and fluid mantles of this and other planets. Oceanic turbulence has properties that are shared by turbulence in other naturally occurring fluids and in flows generated in civil, hydraulic and chemical engineering installations and in buildings. The study of turbulence consequently has applications well beyond the particular examples in the ocean that are selected for description below.
Figure 1.1 shows the sea surface in a wind of about 26 m s− 1. It is covered by waves, many of them breaking and injecting their momentum and bubbles of air from the overlying atmosphere into the underlying seawater. Immediately below the surface, and even at great depths, the water is generally in the state of irregular and variable motion that is referred to as ‘turbulence’, although there is no simple and unambiguous definition of the term. Turbulence has, however, characteristics that, as will be explained, can be quantified and which make it of vital importance. Many of the figures in this book illustrate the nature of turbulent motion, the processes that drive turbulence, or the measurements that can be made to determine its effects.
• Turbulence is generally accepted to be an energetic, rotational and eddying state of motion that results in the dispersion of material and the transfer of momentum, heat and solutes at rates far higher than those of molecular processes alone.
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- Chapter
- Information
- An Introduction to Ocean Turbulence , pp. 1 - 36Publisher: Cambridge University PressPrint publication year: 2007