Accretion processes in star formation /
Hartmann, Lee, 1950-
Accretion processes in star formation / Lee Hartmann. - Second edition. - Cambridge : Cambridge University Press, 2009. - 1 online resource (xiv, 332 pages) : digital, PDF file(s). - Cambridge astrophysics ; 47 . - Cambridge astrophysics series ; 47. .
Title from publisher's bibliographic system (viewed on 05 Oct 2015).
Molecular clouds The IMF, clusters, and binaries Young stars Protostars Long-wavelength emission: dusty envelopes and disks Imaging of disks Disk accretion Disks and planet formation A picture of star and planet formation Beginnings: molecular clouds Large-scale properties of molecular clouds Turbulence and cloud lifetimes Molecular cloud formation and dispersal Flows, magnetic fields, and cloud formation Gravity and fragmentation Sheets and filaments Turbulence and cloud structure Initial conditions for protostellar collapse Molecular cloud cores Virial theorem and cloud stability Centrally concentrated clouds Core lifetimes and equilibrium Stability of magnetized clouds Ambipolar diffusion of magnetic flux The magnetic flux "problem(s)" Protostellar cloud collapse Free-fall collapse of a uniform cloud Similarity solution for collapse Generalized models of protostellar collapse Rotating collapse Time evolution of rotating collapse Disk formation Massive protostars Protostellar collapse: observations vs. theory Protostellar luminosities and accretion SEDs of spherical infalling envelopes SEDs for rotating collapse models A case study: L1551 IRS 5 The Class 0 sources Flat spectrum sources Spatial distribution of emission Detection of infall from line profiles Massive protostars Binaries, clusters, and the IMF Observations of binary and multiple systems Theories of multiple stellar system formation Evolution of multiple systems during accretion Young clusters Cluster formation The Initial Mass Function Theories of the IMF Disk accretion Energy minimization and angular momentum conservation The thin accretion disk The steady optically thick disk The [alpha] disk Sources of viscosity: the magnetorotational instability The ionization problem Gravitational instability and angular momentum transport Disk boundary layers Disk irradiation The disks of pre-main-sequence stars Disk imaging Disk SEDs Long-wavelength emission and disk masses Disk/magnetosphere accretion Accretion rates What drives accretion? The WTTS The Herbig Ae/Be stars The transitional disks The FU Orionis objects Basic observational properties The accretion disk model Disk kinematics Disk properties Time variability and circumstellar envelopes Outburst mechanisms The boundary layer problem Outburst statistics and evolutionary significance Disk winds, jets, and magnetospheric accretion Outflows and jets P Cygni profiles FU Ori disk winds T Tauri winds Mass loss rates Magnetocentrifugal acceleration and collimation Magnetohydrodynamic flows MHD disk winds Applications of MHD disk wind theory Models of magnetospheric accretion Disk accretion and early stellar evolution Pre-main-sequence stellar evolutionary tracks Protostellar properties The "birthline" Birthlines: comparison with observations Age estimates Star formation histories Disk evolution and planet formation Clearing of optically thick disks Viscous disk evolution Binaries Disk evaporation Dust evolution Core accretion and planet formation Gaseous gravitational instability and planet formation Migration Disk gaps and holes Debris disks Speculations Basic hydrodynamic and MHD equations Jeans masses and fragmentation Basic radiative transfer 1.1 2 -- 1.2 4 -- 1.3 5 -- 1.4 9 -- 1.5 10 -- 1.6 12 -- 1.7 14 -- 1.8 16 -- 1.9 18 -- 2 21 -- 2.1 21 -- 2.2 23 -- 2.3 26 -- 2.4 30 -- 2.5 32 -- 2.6 34 -- 2.7 40 -- 3 43 -- 3.1 43 -- 3.2 46 -- 3.3 49 -- 3.4 53 -- 3.5 54 -- 3.6 55 -- 3.7 57 -- 4 60 -- 4.1 60 -- 4.2 61 -- 4.3 65 -- 4.4 68 -- 4.5 73 -- 4.6 74 -- 4.7 76 -- 5 82 -- 5.1 84 -- 5.2 86 -- 5.3 91 -- 5.4 94 -- 5.5 98 -- 5.6 100 -- 5.7 103 -- 5.8 104 -- 5.9 108 -- 6 112 -- 6.1 113 -- 6.2 115 -- 6.3 116 -- 6.4 118 -- 6.5 121 -- 6.6 123 -- 6.7 125 -- 7 129 -- 7.1 130 -- 7.2 132 -- 7.3 139 -- 7.4 142 -- 7.5 143 -- 7.6 146 -- 7.7 148 -- 7.8 152 -- 7.9 155 -- 8 158 -- 8.1 161 -- 8.2 163 -- 8.3 168 -- 8.4 173 -- 8.5 177 -- 8.6 180 -- 8.7 183 -- 8.8 184 -- 8.9 185 -- 9 188 -- 9.1 189 -- 9.2 192 -- 9.3 196 -- 9.4 200 -- 9.5 203 -- 9.6 205 -- 9.7 210 -- 9.8 211 -- 10 213 -- 10.1 213 -- 10.2 216 -- 10.3 219 -- 10.4 222 -- 10.5 223 -- 10.6 228 -- 10.7 229 -- 10.8 233 -- 10.9 237 -- 10.10 240 -- 11 247 -- 11.1 247 -- 11.2 252 -- 11.3 253 -- 11.4 259 -- 11.5 261 -- 11.6 264 -- 12 268 -- 12.1 269 -- 12.2 272 -- 12.3 275 -- 12.4 276 -- 12.5 279 -- 12.6 284 -- 12.7 285 -- 12.8 286 -- 12.9 287 -- 12.10 288 -- 12.11 290 -- Appendix 1 292 -- Appendix 2 294 -- Appendix 3 298.
Our understanding of the formation of stars and planetary systems has changed greatly since the first edition of this book was published. This new edition has been thoroughly updated, and now includes material on molecular clouds, binaries, star clusters and the stellar initial mass function (IMF), disk evolution and planet formation. This book provides a comprehensive picture of the formation of stars and planetary systems, from their beginnings in cold clouds of molecular gas to their emergence as new suns with planet-forming disks. At each stage gravity induces an inward accretion of mass, and this is a central theme for the book. The author brings together current observations, rigorous treatments of the relevant astrophysics, and 150 illustrations, to clarify the sequence of events in star and planet formation. It is a comprehensive account of the underlying physical processes of accretion for graduate students and researchers.
9780511552090 (ebook)
Stars--Formation.
Accretion (Astrophysics)
Disks (Astrophysics)
Gravitational collapse.
QB806 / .H39 2009
523.8/8
Accretion processes in star formation / Lee Hartmann. - Second edition. - Cambridge : Cambridge University Press, 2009. - 1 online resource (xiv, 332 pages) : digital, PDF file(s). - Cambridge astrophysics ; 47 . - Cambridge astrophysics series ; 47. .
Title from publisher's bibliographic system (viewed on 05 Oct 2015).
Molecular clouds The IMF, clusters, and binaries Young stars Protostars Long-wavelength emission: dusty envelopes and disks Imaging of disks Disk accretion Disks and planet formation A picture of star and planet formation Beginnings: molecular clouds Large-scale properties of molecular clouds Turbulence and cloud lifetimes Molecular cloud formation and dispersal Flows, magnetic fields, and cloud formation Gravity and fragmentation Sheets and filaments Turbulence and cloud structure Initial conditions for protostellar collapse Molecular cloud cores Virial theorem and cloud stability Centrally concentrated clouds Core lifetimes and equilibrium Stability of magnetized clouds Ambipolar diffusion of magnetic flux The magnetic flux "problem(s)" Protostellar cloud collapse Free-fall collapse of a uniform cloud Similarity solution for collapse Generalized models of protostellar collapse Rotating collapse Time evolution of rotating collapse Disk formation Massive protostars Protostellar collapse: observations vs. theory Protostellar luminosities and accretion SEDs of spherical infalling envelopes SEDs for rotating collapse models A case study: L1551 IRS 5 The Class 0 sources Flat spectrum sources Spatial distribution of emission Detection of infall from line profiles Massive protostars Binaries, clusters, and the IMF Observations of binary and multiple systems Theories of multiple stellar system formation Evolution of multiple systems during accretion Young clusters Cluster formation The Initial Mass Function Theories of the IMF Disk accretion Energy minimization and angular momentum conservation The thin accretion disk The steady optically thick disk The [alpha] disk Sources of viscosity: the magnetorotational instability The ionization problem Gravitational instability and angular momentum transport Disk boundary layers Disk irradiation The disks of pre-main-sequence stars Disk imaging Disk SEDs Long-wavelength emission and disk masses Disk/magnetosphere accretion Accretion rates What drives accretion? The WTTS The Herbig Ae/Be stars The transitional disks The FU Orionis objects Basic observational properties The accretion disk model Disk kinematics Disk properties Time variability and circumstellar envelopes Outburst mechanisms The boundary layer problem Outburst statistics and evolutionary significance Disk winds, jets, and magnetospheric accretion Outflows and jets P Cygni profiles FU Ori disk winds T Tauri winds Mass loss rates Magnetocentrifugal acceleration and collimation Magnetohydrodynamic flows MHD disk winds Applications of MHD disk wind theory Models of magnetospheric accretion Disk accretion and early stellar evolution Pre-main-sequence stellar evolutionary tracks Protostellar properties The "birthline" Birthlines: comparison with observations Age estimates Star formation histories Disk evolution and planet formation Clearing of optically thick disks Viscous disk evolution Binaries Disk evaporation Dust evolution Core accretion and planet formation Gaseous gravitational instability and planet formation Migration Disk gaps and holes Debris disks Speculations Basic hydrodynamic and MHD equations Jeans masses and fragmentation Basic radiative transfer 1.1 2 -- 1.2 4 -- 1.3 5 -- 1.4 9 -- 1.5 10 -- 1.6 12 -- 1.7 14 -- 1.8 16 -- 1.9 18 -- 2 21 -- 2.1 21 -- 2.2 23 -- 2.3 26 -- 2.4 30 -- 2.5 32 -- 2.6 34 -- 2.7 40 -- 3 43 -- 3.1 43 -- 3.2 46 -- 3.3 49 -- 3.4 53 -- 3.5 54 -- 3.6 55 -- 3.7 57 -- 4 60 -- 4.1 60 -- 4.2 61 -- 4.3 65 -- 4.4 68 -- 4.5 73 -- 4.6 74 -- 4.7 76 -- 5 82 -- 5.1 84 -- 5.2 86 -- 5.3 91 -- 5.4 94 -- 5.5 98 -- 5.6 100 -- 5.7 103 -- 5.8 104 -- 5.9 108 -- 6 112 -- 6.1 113 -- 6.2 115 -- 6.3 116 -- 6.4 118 -- 6.5 121 -- 6.6 123 -- 6.7 125 -- 7 129 -- 7.1 130 -- 7.2 132 -- 7.3 139 -- 7.4 142 -- 7.5 143 -- 7.6 146 -- 7.7 148 -- 7.8 152 -- 7.9 155 -- 8 158 -- 8.1 161 -- 8.2 163 -- 8.3 168 -- 8.4 173 -- 8.5 177 -- 8.6 180 -- 8.7 183 -- 8.8 184 -- 8.9 185 -- 9 188 -- 9.1 189 -- 9.2 192 -- 9.3 196 -- 9.4 200 -- 9.5 203 -- 9.6 205 -- 9.7 210 -- 9.8 211 -- 10 213 -- 10.1 213 -- 10.2 216 -- 10.3 219 -- 10.4 222 -- 10.5 223 -- 10.6 228 -- 10.7 229 -- 10.8 233 -- 10.9 237 -- 10.10 240 -- 11 247 -- 11.1 247 -- 11.2 252 -- 11.3 253 -- 11.4 259 -- 11.5 261 -- 11.6 264 -- 12 268 -- 12.1 269 -- 12.2 272 -- 12.3 275 -- 12.4 276 -- 12.5 279 -- 12.6 284 -- 12.7 285 -- 12.8 286 -- 12.9 287 -- 12.10 288 -- 12.11 290 -- Appendix 1 292 -- Appendix 2 294 -- Appendix 3 298.
Our understanding of the formation of stars and planetary systems has changed greatly since the first edition of this book was published. This new edition has been thoroughly updated, and now includes material on molecular clouds, binaries, star clusters and the stellar initial mass function (IMF), disk evolution and planet formation. This book provides a comprehensive picture of the formation of stars and planetary systems, from their beginnings in cold clouds of molecular gas to their emergence as new suns with planet-forming disks. At each stage gravity induces an inward accretion of mass, and this is a central theme for the book. The author brings together current observations, rigorous treatments of the relevant astrophysics, and 150 illustrations, to clarify the sequence of events in star and planet formation. It is a comprehensive account of the underlying physical processes of accretion for graduate students and researchers.
9780511552090 (ebook)
Stars--Formation.
Accretion (Astrophysics)
Disks (Astrophysics)
Gravitational collapse.
QB806 / .H39 2009
523.8/8