Galaxies delves into all of these surrounding subjects in six chapters written by dedicated, specialist astronomers and researchers in the field, from their numerical simulations to their evolutions.
Table of Contents
Introduction xi
Chapter 1. The Classification of Galaxies 1
Ronald BUTA
1.1. Introduction 1
1.2. Classes of galaxies 3
1.3. Elliptical galaxies 7
1.4. Spiral galaxies 12
1.5. S0 galaxies 22
1.6. Magellanic spiral and irregular galaxies 25
1.7. Dwarf elliptical, S0, and spheroidal galaxies 26
1.8. Edge-on galaxies 27
1.9. Morphology of interacting and merging galaxies 30
1.10. General properties along the CVRHS sequence 31
1.10.1. Morphological systematics 31
1.10.2. Astrophysical systematics 33
1.11. Other approaches to galaxy classification 34
1.12. Interpretations of morphology 35
1.13. Artificial galaxies and the future of galaxy classification 42
1.14. References 44
Chapter 2. Our Galaxy, the Milky Way 49
Paola Di MATTEO
2.1. Introduction 49
2.2. Baryonic discs and their spiral structure 52
2.2.1. Neutral, ionized and molecular gas 52
2.2.2. Thin and thick stellar discs 54
2.2.3. Spiral structure from gaseous and stellar tracers 59
2.3. The central kiloparsecs: the bar and the bulge 60
2.4. The stellar halo 63
2.5. On the dark matter content and shape, as inferred from rotation curves and stellar streams 67
2.6. Dissecting the global structure: stellar kinematics, abundances and ages 69
2.6.1. Setting the scene: the solar vicinity 70
2.6.2. Zooming out on a several kpc scale 76
2.6.3. Digging into the bulge 80
2.7. Reconstructing the Milky Way evolution 84
2.8. Perspectives 86
2.9. References 86
Chapter 3. Early-type Galaxies 93
Eric EMSELLEM
3.1. Introduction 93
3.2. General properties: components and morphology 95
3.2.1. Discs and bars 96
3.2.2. Gas and dust content 96
3.2.3. Dark matter and halo 97
3.2.4. Globular clusters 99
3.2.5. Light and mass profiles 99
3.2.6. Extreme cases: brightest cluster galaxies and ultra-diffuse galaxies 100
3.3. Zoom on the stellar component 101
3.3.1. Scaling relations: Faber-Jackson, fundamental plane and virial plane 102
3.3.2. Age and metallicity 104
3.3.3. Initial mass function 105
3.4. Dynamics of ETGs 108
3.4.1. Observations 109
3.4.2. Toward a kinematic classification of ETGs 110
3.4.3. Modeling 113
3.4.4. Supermassive black holes 119
3.5. Formation and evolution processes 119
3.5.1. Perspective at z = 0: the mass-radius plane 119
3.5.2. Growth, mergers and transformations 121
3.5.3. Ex situ versus in situ 123
3.5.4. Environment 124
3.6. Conclusion 126
3.7. References 127
Chapter 4. Spiral Galaxies 137
Françoise COMBES
4.1. Introduction 137
4.2. Blue and red galaxies: quenching star formation 142
4.2.1. Definition of bimodality 142
4.2.2. The parameters that determine the red sequence 146
4.2.3. Mechanisms for quenching star formation 148
4.3. Spiral galaxies: density waves or not? 152
4.3.1. The winding problem 152
4.3.2. The theory of density waves 155
4.3.3. Role of gas and star formation 159
4.4. Bars: drivers of evolution 160
4.4.1. Formation of bars 162
4.4.2. Orbits in a barred galaxy 164
4.4.3. Response of gas to a barred potential 166
4.4.4. Vertical resonances and peanuts 168
4.4.5. Dark matter and bars 171
4.5. Environment of spiral galaxies 173
4.5.1. Morphological segregation 173
4.5.2. The problem of bulgeless galaxies 174
4.6. Conclusion 176
4.7. References 177
Chapter 5. Galaxy Mergers and Interactions through Cosmic Time 181
Christopher J. CONSELICE
5.1. Introduction 182
5.2. The physics of merging 185
5.3. The merger history of galaxies 188
5.3.1. Defining mergers and merging 188
5.3.2. Merger rates in the nearby universe 190
5.3.3. Galaxy merger fraction evolution to z = 6 191
5.3.4. Galaxy merger rates 196
5.4. The added value of mergers 199
5.4.1. Galaxy and black hole assembly through interactions and mergers 199
5.4.2. Cosmological relevance 201
5.4.3. Future uses and methods 202
5.5. Summary 203
5.6. Acknowledgments 204
5.7. References 205
Chapter 6. Cosmic Evolution of Galaxies 209
David ELBAZ and Emeric Le FLOC’H
6.1. Introduction 209
6.2. Characteristics of galaxies used to define their cosmic evolution 211
6.2.1. Decoding multi-wavelength radiation 211
6.2.2. Populations of galaxies 216
6.3. Starbursts, secular evolution and universality of star formation 218
6.3.1. Definition of a starburst 218
6.3.2. The SFMS and the secular evolution of galaxies 220
6.3.3. Origin of starbursts 221
6.3.4. Secular evolution and the influence of the galactic environment 223
6.4. Detection of distant galaxies 225
6.4.1. Deep surveys of the Universe 227
6.4.2. Large samples of distant galaxies 229
6.4.3. K correction 232
6.5. Cosmic history of galaxies 234
6.5.1. History of star formation 234
6.5.2. Evolution of the stellar mass function and formation of the red galaxy sequence 237
6.5.3. Evolution of the metallicity and of the average size of galaxies 239
6.5.4. Evolution of the galaxy merger and starburst rates 241
6.6. Origin of the cosmic history of galaxies 244
6.6.1. The diffuse cosmic background as a signature of the cosmic history of galaxies 245
6.6.2. Unraveling the origin of the cosmic history of galaxies by studying their reservoirs of interstellar matter 249
6.7. Conclusion 251
6.8. References 252
List of Authors 257
Author Biographies 259
Index 261