Buch, Englisch, 352 Seiten, Format (B × H): 175 mm x 249 mm, Gewicht: 726 g
Buch, Englisch, 352 Seiten, Format (B × H): 175 mm x 249 mm, Gewicht: 726 g
ISBN: 978-0-470-69957-7
Verlag: Wiley
An Introduction to Stellar Astrophysics aspires to provide the reader with an intermediate knowledge on stars whilst focusing mostly on the explanation of the functioning of stars by using basic physical concepts and observational results.
The book is divided into seven chapters, featuring both core and optional content:
- Basic concepts
- Stellar Formation
- Radiative Transfer in Stars
- Stellar Atmospheres
- Stellar Interiors
- Nucleosynthesis and Stellar Evolution and
- Chemically Peculiar Stars and Diffusion.
Student-friendly features include:
- Detailed examples to help the reader better grasp the most important concepts
- A list of exercises is given at the end of each chapter and answers to a selection of these are presented.
- Brief recalls of the most important physical concepts needed to properly understand stars.
- A summary for each chapter
- Optional and advanced sections are included which may be skipped without interfering with the flow of the core content.
This book is designed to cover the most important aspects of stellar astrophysics inside a one semester (or half-year) course and as such is relevant for advanced undergraduate students following a first course on stellar astrophysics, in physics or astronomy programs. It will also serve as a basic reference for a full-year course as well as for researchers working in related fields.
Autoren/Hrsg.
Fachgebiete
Weitere Infos & Material
Preface xi
Acknowledgments xiii
Chapter 1: Basic Concepts 1
1.1 Introduction 1
1.2 The Electromagnetic Spectrum 3
1.3 Blackbody Radiation 5
1.4 Luminosity, Effective Temperature, Flux and Magnitudes 8
1.5 Boltzmann and Saha Equations 13
1.6 Spectral Classification of Stars 21
1.7 The Hertzsprung–Russell Diagram 27
1.8 Summary 30
1.9 Exercises 31
Chapter 2: Stellar Formation 35
2.1 Introduction 35
2.2 Hydrostatic Equilibrium 36
2.3 The Virial Theorem 40
2.4 The Jeans Criterion 46
2.5 Free-Fall Times† 52
2.6 Pre-Main-Sequence Evolution† 54
2.7 Summary 57
2.8 Exercises 57
Chapter 3: Radiative Transfer in Stars 61
3.1 Introduction 61
3.2 Radiative Opacities 62
3.2.1 Matter–Radiation Interactions 62
3.2.2 Types of Radiative Opacities 64
3.3 Specific Intensity and Radiative Moments 69
3.4 Radiative Transfer Equation 77
3.5 Local Thermodynamic Equilibrium 81
3.6 Solution of the Radiative-Transfer Equation 82
3.7 Radiative Equilibrium 90
3.8 Radiative Transfer at Large Optical Depths 91
3.9 Rosseland and Other Mean Opacities 94
3.10 Schwarzschild–Milne Equations†† 97
3.11 Demonstration of the Radiative-Transfer Equation† 99
3.12 Radiative Acceleration of Matter and Radiative Pressure† 100
3.12.1 Radiative Acceleration of Matter 100
3.12.2 Radiative Pressure 103
3.13 Summary 104
3.14 Exercises 105
Chapter 4: Stellar Atmospheres 109
4.1 Introduction 109
4.2 The Grey Atmosphere 110
4.2.1 The Temperature Profile in a Grey Atmosphere 111
4.2.2 Radiative Flux in a Grey Atmosphere†† 117
4.3 Line Opacities and Broadening 119
4.3.1 Natural Broadening 120
4.3.2 Doppler Broadening 122
4.3.3 Pressure Broadening 130
4.3.4 Stimulated Emission and Masers 132
4.3.5 Einstein Coefficients†† 134
4.4 Equivalent Width and Formation of Atomic Lines 137
4.4.1 Equivalent Width 137
4.4.2 Formation of Weak Atomic Lines 139
4.4.3 Curve of Growth† 142
4.5 Atmospheric Modelling 143
4.5.1 Input Data and Approximations 143
4.5.2 Algorithm for Atmospheric Modelling†† 145
4.5.3 Example of a Stellar Atmosphere Model 148
4.5.4 Temperature-Correction Procedure†† 150
4.6 Summary 151
4.7 Exercises 152
Chapter 5: Stellar Interiors 155
5.1 Introduction 155
5.2 Equations of Stellar Structure 156
5.2.1 Hydrostatic Equilibrium Equation 156
5.2.2 Equation of Mass Conservation 156
5.2.3 Energy-Transport Equation 159
5.2.4 Equation of Energy Conservation 160
5.2.5 Other Ingredients Needed 161
5.3 Energy Transport in Stars 163
5.3.1 Monochromatic Radiative Flux in Stellar Interiors 164
5.3.2 Conduction 166
5.3.3 Convection 167
5.3.3.1 General Description of Convection 167
5.3.3.2 The Schwarzschild Criterion for Convection† 168
5.3.3.3 The Mixing-Length Theory†† 172
5.3.3.4 Convective Equilibrium† 176
5.4 Polytropic Models 176
5.5 Structure of the Sun 182
5.6 Equation of State 184
5.6.1 Introduction 184
5.6.2 The Ideal Gas 185
5.6.3 Degeneracy 189
5.6.4 Radiation Pressure 191
5.7 Variable Stars and Asteroseismology 191
5.7.1 Variable Stars 191
5.7.2 Asteroseismology† 197
5.7.3 Basic Physics Behind Period–Luminosity Relations† 200
5.8 Summary 202
5.9 Exercises 203
Chapter 6: Nucleosynthesis and Stellar Evolution 205
6.1 Introduction 205
6.2 Generalities Concerning Nuclear Fusion 206
6.3 Models of the Nucleus† 211<
