Book contents
- Frontmatter
- Contents
- Chapter 1 Introduction
- Chapter 2 Space Environment
- Chapter 3 Transport Equations
- Chapter 4 Collisions
- Chapter 5 Simplified Transport Equations
- Chapter 6 Wave Phenomena
- Chapter 7 Magnetohydrodynamic Formulation
- Chapter 8 Chemical Processes
- Chapter 9 Ionization and Energy Exchange Processes
- Chapter 10 Neutral Atmospheres
- Chapter 11 The Terrestrial Ionosphere at Middle and Low Latitudes
- Chapter 12 The Terrestrial Ionosphere at High Latitudes
- Chapter 13 Planetary Ionospheres
- Chapter 14 Ionospheric Measurement Techniques
- Appendices
- A Physical Constants and Conversions
- B Vector Relations and Operations
- C Integrals and Transformations
- D Functions and Series Expansions
- E Systems of Units
- F Maxwell Transfer Equations
- G Collision Models
- H Maxwell Velocity Distribution
- I Semilinear Expressions for Transport Coefficients
- J Solar Fluxes and Relevant Cross Sections
- K Atmospheric Models
- L Scalars, Vectors, Dyadics and Tensors
- Index
L - Scalars, Vectors, Dyadics and Tensors
Published online by Cambridge University Press: 06 January 2010
- Frontmatter
- Contents
- Chapter 1 Introduction
- Chapter 2 Space Environment
- Chapter 3 Transport Equations
- Chapter 4 Collisions
- Chapter 5 Simplified Transport Equations
- Chapter 6 Wave Phenomena
- Chapter 7 Magnetohydrodynamic Formulation
- Chapter 8 Chemical Processes
- Chapter 9 Ionization and Energy Exchange Processes
- Chapter 10 Neutral Atmospheres
- Chapter 11 The Terrestrial Ionosphere at Middle and Low Latitudes
- Chapter 12 The Terrestrial Ionosphere at High Latitudes
- Chapter 13 Planetary Ionospheres
- Chapter 14 Ionospheric Measurement Techniques
- Appendices
- A Physical Constants and Conversions
- B Vector Relations and Operations
- C Integrals and Transformations
- D Functions and Series Expansions
- E Systems of Units
- F Maxwell Transfer Equations
- G Collision Models
- H Maxwell Velocity Distribution
- I Semilinear Expressions for Transport Coefficients
- J Solar Fluxes and Relevant Cross Sections
- K Atmospheric Models
- L Scalars, Vectors, Dyadics and Tensors
- Index
Summary
Plasma physics is a subject where advanced mathematical techniques are frequently required to gain an understanding of the physical phenomena under consideration. This is particularly true in studies involving kinetic theory and plasma transport effects, where scalars, vectors, and multi-order tensors are needed (Chapters 3 and 4). Therefore, it is useful to briefly review some of the required mathematics.
A scalar is a single number that is useful for describing, say, the temperature of a gas. However, in order to describe the velocity of the gas, both a magnitude and direction are required (e.g., a vector). A vector is defined relative to some orthogonal coordinate system and three numbers, corresponding to the components of the vector, are required to define the vector. In a Cartesian coordinate system, the vector a is given
where e1, e2, and e3 are unit vectors along the x, y, and z axes, respectively. In index notation, the vector a is simply represented by aα where α varies from 1 to 3.
- Type
- Chapter
- Information
- IonospheresPhysics, Plasma Physics, and Chemistry, pp. 539 - 544Publisher: Cambridge University PressPrint publication year: 2000