star and planet formation
DESCRIPTION
Star and Planet Formation. Sommer term 2007 Henrik Beuther & Sebastian Wolf. 16.4 Introduction (H.B. & S.W.) 23.4 Physical processes, heating and cooling, radiation transfer (H.B.) 30.4 Gravitational collapse & early protostellar evolution I (H.B.) - PowerPoint PPT PresentationTRANSCRIPT
Star and Planet Formation Sommer term 2007Henrik Beuther & Sebastian Wolf
16.4 Introduction (H.B. & S.W.)23.4 Physical processes, heating and cooling, radiation transfer (H.B.)30.4 Gravitational collapse & early protostellar evolution I (H.B.)07.5 Gravitational collapse & early protostellar evolution II (H.B.)14.5 Protostellar and pre-main sequence evolution (H.B.)21.5 Outflows and jets (H.B.)28.5 Pfingsten (no lecture)04.6 Clusters, the initial mass function (IMF), massive star formation (H.B.)11.6 Protoplanetary disks: Observations + models I (S.W.)18.6 Gas in disks, molecules, chemistry, keplerian motions (H.B.)25.6 Protoplanetary disks: Observations + models II (S.W.)02.7 Accretion, transport processes, local structure and stability (S.W.)09.7 Planet formation scenarios (S.W.)16.7 Extrasolar planets: Searching for other worlds (S.W.)23.7 Summary and open questions (H.B. & S.W.)
More Information and the current lecture files: http://www.mpia.de/homes/beuther/lecture_ss07.html and http://www.mpia.de/homes/swolf/vorlesung/sommer2007.html
Emails: [email protected], [email protected]
Summary last week
- The “first core” contracts until temperatures are able to dissociate H2 to H.- H-region spreads outward, T and P not high enough to maintain equilibrium, further collapse until H gets collisionally ionized. The dynamically stable protostar has formed.- Accretion luminosity. Definition of low-mass protostar can be “mass-gaining object where the luminosity is dominated by accretion”.- Structure of the protostellar envelope and effects of rotation.- Stellar structure equations: follow numerically the protostellar and then later the pre-main sequence evolution.- Convection and deuterium burning.- End of protostellar/beginning or pre-main sequence evolution --> birthline.- Pre-main sequence evolution in the Hertzsprung-Russel (HR) diagram.- Connection of HR diagram with protostellar and pre-main sequence class scheme.
Star Formation Paradigm
Discovery of outflows IHerbig 1950, 1951; Haro 1952, 1953
Initially thought to be embedded protostars but soon spectra were recognized as caused by shock waves --> jets and outflows
Discovery of outflows II
- In the mid to late 70th, first CO non-Gaussian line wing emission detected (Kwan & Scovile 1976).- Bipolar structures, extremely energetic, often associated with HH objects
Bachiller et al. 1990Snell et al. 1980
HH30, a disk-outflow system
QuickTime™ and aGIF decompressor
are needed to see this picture.
Outflow multiplicities in Orion
Stanke et al. 2002
The prototypical molecular outflow HH211
Jet entrainment in HH211
From Hirano et al. 2006, Palau et al. 2006, Chandler& Richer 2001, Gueth et al. 1999, Shang et al. 2006
- Warmer gas closer to source- Jet like SiO emission has always larger velocities than CO at the same projected distance from the driving protostar
IRAS 20126+4104
Lebron et al. 2006
Mass vs.velocity, energy vs. velocity
Lebron et al. 2006
- Mass-velocity relation exhibits broken power-law, steeper further out- Energy at high velocities of the same magnitude than at low velocities
Outflow/jet precession
Stanke 2003
Fendt & Zinnecker 1998
Jet rotation in DG Tau
Bacciotti et al. 2002
blue
red
Testi et al. 2002
Corotation of disk and jet
General outflow properties
- Jet velocities 100-500 km/s <==> Outflow velocities 10-50 km/s- Estimated dynamical ages between 103 and 105 years- Size between 0.1 and 1 pc- Force provided by stellar radiation too low (middle panel) --> non-radiative processes necessary!
Mass vs. L Force vs. L Outflow rate vs. L
Wu et al. 2004, 2005
Wu et al. 2004
Collimation degreesCollimation degrees (length/width) vary between 1 and 10HH211, Gueth et al. 1999
Collimation and pv-structure
Lee et al. 2001
HH212: consistent with jet-driving VLA0548: consistent with wind-driving
- pv-structure of jet- and wind-driven models very different- Often Hubble-law observed --> increasing velocity with increasing distance from the protostar
Outflow entrainment models IBasically 4 outflow entrainment models are discussed in the literature:
Turbulent jet entrainment model - Working surfaces at the jet boundary layer caused by Kelvin-Helmholtz instabilities form viscous mixing layer entraining molecular gas. --> The mixing layer grows with time and whole outflow gets turbulent. - Broken power-law of mass-velocity relation is reproduced, but velocity decreases with distance from source --> opposite to observations
Jet-bow shock model - As jet impact on ambient gas, bow shocks are formed at head of jet. High pressure gas is ejected sideways, creating a broader bow shock entraining the ambient gas. Episodic ejection produces chains of knots and shocks. - Numerical modeling reproduce many observables, e.g. Hubble-law.
Raga et al. 1993
Gueth et al. 1999
Jet simulations I
QuickTime™ and aYUV420 codec decompressor
are needed to see this picture.
QuickTime™ and aYUV420 codec decompressor
are needed to see this picture.
Rosen & Smith 2004
3-dimensional hydrodynamic simulations, including H, C and O chemistryand cooling of the gas, this is a pulsed jet.
Jet simulations II: small precession
QuickTime™ and aYUV420 codec decompressor
are needed to see this picture.
QuickTime™ and aYUV420 codec decompressor
are needed to see this picture.
Rosen &Smith 2004
Jet simulations III, large precession
QuickTime™ and aYUV420 codec decompressor
are needed to see this picture.
QuickTime™ and aYUV420 codec decompressor
are needed to see this picture.
Rosen &Smith 2004
Outflow entrainment models II
Wide-angle wind model - A wide-angle wind blows into ambient gas forming a thin swept-up shell. Different degrees of collimation can be explained by different density structures of the ambient gas. - Attractive models for older and low collimated outflows.
Circulation model - Molecular gas is not entrained by underlying jet or wind, but it is rather infalling gas that was deflected from the central protostar in a region of high MHD pressure. - This model was proposed to explain also massive outflows because it was originally considered difficult to entrain that large amounts of gas. Maybe not necessary today anymore …
Fiege & Henriksen 1996
Shu et al. 1991
Outflow entrainment models III
Arce et al. 2002
Jet launching
- Large consensus that outflows are likely driven by magneto- centrifugal winds from open magnetic field lines anchored on rotating circumstellar accretion disks.
- Two main competing theories: disk winds <==> X-winds
- Are they launched from a very small area of the disk close to the truncation radius (X-wind), or over larger areas of the disk (disk wind)?
Jet-launching: Disk winds ICollapse: 6.81 x 104 yr 5 months later
1AU~1.5x1013cm
- Infalling core pinches magnetic field.- If poloidal magnetic field component has angle larger 30˚ from vertical, centrifugal forces can launch matter- loaded wind along field lines from disk surface.- Wind transports away from 60 to 100% of disk angular momentum.
Banerjee & Pudritz 2006
Recent review: Pudritz et al. 2006
Jet-launching: Disk winds II
Banerjee & Pudritz 2006
1AU~1.5x1013cm
Toroidal magnetic field
t=1.3x105 yr t=9.66x105 yr
- On larger scales, a strong toroidal magnetic field builds up during collapse.
- At large radii (outside Alfven radius rA, the radius where kin. energy equals magn. energy) B/Bp much larger than 1 --> collimation via Lorentz-force FL~jzB
X-winds
Shu et al. 2000
- The wind is launched magneto-centrifugally from the inner co-rotation radius of the accretion disk (~0.03AU)
Jet-launching points and angular momenta
Woitas et al. 2005
r0,in correspondsapproximately tocorotation radius~ 0.03 AU
- From toroidal and poloidal velocities, one infers footpoints r0, where gas comes from --> outer r0 for the blue and red wing are about 0.4 and 1.6 AU (lower limits) --> consistent with disk winds- About 2/3 of the disk angular momentum may be carried away by jet.
Spectro-Astrometry
Impact on surrounding cloud
- Entrain large amounts of cloud mass with high energies.
- Potentially partly responsible to maintain turbulence in cloud.
- Can finally disrupt the cores to stop any further accretion.
- Can erode the clouds and alter their velocity structure.
- May trigger collapse in neighboring cores.
- Via shock interactions heat the cloud.
- Alter the chemical properties.
Outflow chemistry
Bachiller et al. 2001
Summary- Outflows and jets are ubiquitous and necessary phenomena in star formation.
- Transport angular momentum away from protostar.
- The are likely formed by magneto-centrifugal disk-winds.
- Collimation is caused by Lorentz forces.
- Gas entrainment can be due to various processes: turbulent entrainment, bow-shocks, wide-angle winds, circulation …
- They inject significant amounts of energy in the ISM, may be important to maintain turbulence.
- Disrupt at some stage their maternal clouds.
- Often point back to the forming star
Star and Planet Formation Sommer term 2007Henrik Beuther & Sebastian Wolf
16.4 Introduction (H.B. & S.W.)23.4 Physical processes, heating and cooling, radiation transfer (H.B.)30.4 Gravitational collapse & early protostellar evolution I (H.B.)07.5 Gravitational collapse & early protostellar evolution II (H.B.)14.5 Protostellar and pre-main sequence evolution (H.B.)21.5 Outflows and jets (H.B.)28.5 Pfingsten (no lecture)04.6 Clusters, the initial mass function (IMF), massive star formation (H.B.)11.6 Protoplanetary disks: Observations + models I (S.W.)18.6 Gas in disks, molecules, chemistry, keplerian motions (H.B.)25.6 Protoplanetary disks: Observations + models II (S.W.)02.7 Accretion, transport processes, local structure and stability (S.W.)09.7 Planet formation scenarios (S.W.)16.7 Extrasolar planets: Searching for other worlds (S.W.)23.7 Summary and open questions (H.B. & S.W.)
More Information and the current lecture files: http://www.mpia.de/homes/beuther/lecture_ss07.html and http://www.mpia.de/homes/swolf/vorlesung/sommer2007.html
Emails: [email protected], [email protected]