Time-Dependent Phenomena in Protoplanetary Disks

Slides:

Advertisements

Similar presentations

The formation of stars and planets Day 3, Topic 3: Irradiated protoplanetary disks Lecture by: C.P. Dullemond.

Advertisements

Protostellar/planetary disk observations (and what they might imply) Lee Hartmann University of Michigan.

From protostellar cores to disk galaxies - Zurich - 09/2007 S.Walch, A.Burkert, T.Naab Munich University Observatory S.Walch, A.Burkert, T.Naab Munich.

Protoplanetary Disks: The Initial Conditions of Planet Formation Eric Mamajek University of Rochester, Dept. of Physics & Astronomy Astrobio 2010 – Santiago.

Planet Formation Topic: Disk thermal structure Lecture by: C.P. Dullemond.

FU Ori and Outburst Mechanisms Zhaohuan Zhu Hubble Fellow, Princeton University Collaborators: Lee Hartmann (Umich), Charles Gammie (UIUC), Nuria Calvet.

Disk corona in AGN: what do we expect? Bifang Liu Yunnan Observatory, CAS The disk corona evaporation model The model for X-ray binaries Similarities between.

Simulating the Extreme Environment Near Luminous Black Hole Sources Omer Blaes University of California, Santa Barbara.

Processes in Protoplanetary Disks Phil Armitage Colorado.

Processes in Protoplanetary Disks Phil Armitage Colorado.

Disc clearing conventional view: most stars are either rich in circumstellar diagnostics, e.g. Or devoid of same: intermediate states less common ==> RAPID.

Processes in Protoplanetary Disks Phil Armitage Colorado.

Planet Formation with Different Gas Depletion Timescales: Comparing with Observations Huigen Liu, Ji-lin Zhou, Su Wang Dept. of Astronomy.

Jeong-Eun Lee Kyung Hee University University of Texas at Austin.

Processes in Protoplanetary Disks Phil Armitage Colorado.

Multidimensional Models of Magnetically Regulated Star Formation Shantanu Basu University of Western Ontario Collaborators: Glenn E. Ciolek (RPI), Takahiro.

A Molecular Inventory of the L1489 IRS Protoplanetary Disk Michiel R. Hogerheijde Christian Brinch Leiden Observatory Jes K. Joergensen CfA.

Ge/Ay133 What effects do 1-10 M Earth cores & Jovian planets have on the surrounding disk? Or, … Migration & Gaps.

Structure and evolution of protoplanetary disks

The formation of stars and planets Day 3, Topic 2: Viscous accretion disks Continued... Lecture by: C.P. Dullemond.

Adwin Boogert Geoff Blake Michiel Hogerheijde Caltech/OVRO Univ. of Arizona Tracing Protostellar Evolution by Observations of Ices.

The Nature of Turbulence in Protoplanetary Disks Jeremy Goodman Princeton University “Astrophysics of Planetary Systems” Harvard.

Ge/Ay133 Disk Structure and Spectral Energy Distributions (SEDs)

Multi-Wavelength Time Variability of Active Galactic Nuclei Ritaban Chatterjee Advisor: Prof. Alan P. Marscher Collaborators: Svetlana Jorstad (B.U.),

Processes in Protoplanetary Disks

Giant Planet Accretion and Migration : Surviving the Type I Regime Edward Thommes Norm Murray CITA, University of Toronto Edward Thommes Norm Murray CITA,

Ge/Ay133 What effects do 1-10 M Earth cores have on the surrounding disk? Today = Gaps Wednesday = Migration (included here)

Monte Carlo Radiation Transfer in Protoplanetary Disks: Disk-Planet Interactions Kenneth Wood St Andrews.

An Accretion Disc Model for Quasar Optical Variability An Accretion Disc Model for Quasar Optical Variability Li Shuang-Liang Li Shuang-Liang Shanghai.

Multiwavelength Continuum Survey of Protostellar Disks in Ophiuchus Left: Submillimeter Array (SMA) aperture synthesis images of 870 μm (350 GHz) continuum.

Processes in Protoplanetary Disks Phil Armitage Colorado.

The Origin of Gaps and Holes in Transition Disks Uma Gorti (SETI Institute) Collaborators: D. Hollenbach (SETI), G. D’Angelo (SETI/NASA Ames), C.P. Dullemond.

Modeling Disks of sgB[e] Stars Jon E. Bjorkman Ritter Observatory.

1 Indiana 3D Hydro Group The Effects of Envelope Irradiation on Gravitational Instabilities in Embedded Protoplanetary Disks Kai Cai Astronomy Department.

Massive Star Formation: The Role of Disks Cassandra Fallscheer In collaboration with: Henrik Beuther, Eric Keto, Jürgen Sauter, TK Sridharan, Sebastian.

Collapsar Accretion and the Gamma-Ray Burst X-Ray Light Curve Chris Lindner Milos Milosavljevic, Sean M. Couch, Pawan Kumar.

Variability of radio-quiet AGN across the spectrum: facts and ideas B. Czerny Copernicus Astronomical Center, Warsaw, Poland.

1 S. Davis, April 2004 A Beta-Viscosity Model for the Evolving Solar Nebula Sanford S Davis Workshop on Modeling the Structure, Chemistry, and Appearance.

References Bell, R. & Lin, D. N. C., 1994, ApJ, 427, 987 Bertin, G., Coppi, B., Rousseau, F., 2005, APS, 47 th Annual Meeting of the Division of Plasma.

1 X-ray enhancement and longterm evolution of Swift J arXiv: Authors: O. Benli, S. Caliskan, U. Ertan et al. Reporter: Fu, Lei.

Long term evolution of circumstellar discs: DM Tau and GM Aur Ricardo Hueso (*) & Tristan Guillot Laboratoire Cassini, Observatoire de la Côte d’Azur,

Line emission by the first star formation Hiromi Mizusawa(Niigata University) Collaborators Ryoichi Nishi (Niigata University) Kazuyuki Omukai (NAOJ) Formation.

Kenneth Wood St Andrews

Warm Absorbers: Are They Disk Outflows? Daniel Proga UNLV.

Primordial Disks: From Protostar to Protoplanet Jon E. Bjorkman Ritter Observatory.

The University of Western Ontario Shantanu Basu and Eduard Vorobyov Cores to Disks to Protostars: The Effect of the Core Envelope on Accretion and Disk.

Planetesimal dynamics in self-gravitating discs Giuseppe Lodato IoA - Cambridge.

Protoplanetary disk evolution and clearing Paola D’Alessio (CRYA) J. Muzerolle (Steward) C. Briceno (CIDA) A. Sicilia-Aguilar (MPI) L. Adame (UNAM) IRS.

Huge accretion disks Accretion disk + Black Hole in the core of elliptical galaxy NGC 4261 (Hubble Space Telescope) A disk of cold gas and dust fuels.

Processes in Protoplanetary Disks Phil Armitage Colorado.

Photoevaporation of Disks around Young Stars D. Hollenbach NASA Ames Research Center From Stars to Planets University of Florida April, 2007 Collaborators:

Massive planets in FU Orionis objects Giuseppe Lodato Institute of Astronomy, Cambridge In collaboration with Cathie Clarke (IoA)

Planet Formation in a disk with a Dead Zone Soko Matsumura (Northwestern University) Ralph Pudritz (McMaster University) Edward Thommes (Northwestern University)

Planet and Gaps in the disk

Orbital Evolution of Dust Grains and Rocks During FU Orionis Outbursts

ALMA User Perspective: Galactic Studies

Chemical Evolution During Star Formation

Mariko KATO (Keio Univ., Japan) collaboration with

Ravit Helled Institute for Computational Science

and the Stellar Upper Mass Limit

Some considerations on disk models

Planetesimal formation in self-gravitating accretion discs

Eduard Vorobyov and Shantanu Basu

Dust Evolution & Planet Traps: Effects on Planet Populations

Changes in the YSO FU Ori Disk

Ge/Ay133 What effects do 1-10 MEarth cores

Wladimir Lyra California State University, Northridge

Can Giant Planet Form by Direct Gravitational Instability?

Mayer et al Viability of Giant Planet Formation by Direct Gravitational Instability Roman Rafikov (CITA)

Two puzzles of FU Ori objects

Presentation transcript:

Time-Dependent Phenomena in Protoplanetary Disks Zhaohuan Zhu Advisor: Lee Hartmann Collaborators: Charles Gammie(UIUC), Nuria Calvet (Umich), Catherine Espaillat(CFA), Richard Durisen, Kai Cai, Jesus Hernandez

Introduction “Luminosity Problem” (Kenyon et al. 1990) Solution: Ṁ~Mʘ /105 yrs~10-5 Mʘ yr-1 L~ ~20 Lʘ for 0.3 Mʘ, 2 Rʘ Observed L peaks at <0.5 Lʘ Solution: Infall to disk, with episodic disk accretion (Evans et al 2008) Ṁinfall~10-5 Mʘ yr-1 Ṁinfall~10-5 Mʘ yr-1 quiescent outburst Ṁ~10-8 Mʘ yr-1 Ṁ~10-4 Mʘ yr-1

FU Ori : example of episodic accretion Accretion disk model predicts SED, variation of spectral type and rotation with wavelength. (Zhu et al 2007, 2008) 2000 K 6000 K 0.5-1 AU α~0.02-0.2 Accrete 10-2 Mʘ in 100 year Massive inner disk

Outburst mechanism: general picture GI (Armitage et al. 2001, Zhu, Hartmann, Gammie 2009 a,b)

Outburst mechanism: 2 D simulations ZEUS axisymmetric hydro-simulation of viscous fluid accretion With the artificial viscosity of MRI and GI and the radiative cooling Movie1 (Zhu et al. 2009b) 4 stages

Outburst mechanism: 2 D simulations Compared with Observation Maximum mass accretion rate Outburst duration time High Ṁ disk size Short time scale variations

Disk long term evolution: layered picture Longterm 1-D 2-Zone model with infall to disk Faster rotating core MRI MRI GI Dead Zone (1) (2) (3) (2) (1) Fiducial model Slower rotating core (3) Ease Luminosity problem Initial core rotation important (Zhu et al. submitted)

Disk long term evolution: Predictions Compare with current observation and Predict with future obeservations W =10-14 W=2 X10-14 ad=0.001 viscous W =10-14 W=3 X10-15 Massive dead zone within 10 AU

Conclusion: Ongoing work Azimuthal 2D to treat Pure TI model does not work for FU Ori outbursts GI+MRI model does work It can explain the Luminosity problem The disk may have a massive ‘dead zone’ which can be observed by future EVLA, ALMA observations Ongoing work Azimuthal 2D to treat self-gravity consistently How do planets open a hole or gap in accreting disks, which can be compared with (Pre)Transitional disks.

(Evans et al. 2008)

FU Orionis objects: disk differential rotation optical 2µm 5 µm Zhu et al. 2009 b Support the disk accretion model The high Ṁ disk could extend to 0.5 AU (Close to Keplarian rotation velocity at 0.5 AU)

FU Orionis objects: flared outer disk or envelope? BBW 76 & V1515 Cyg V1515 Cyg BBW 76 (Zhu et al. 2008 ) The variety of dusty structures (flared disks for FU Ori and BBW 76; an envelope for V1515 Cyg) suggests that FU Orionis phase can be present at either early or late stages of protostellar evolution.

(Pre-)Transitional disk Constant nu Constant alpha

TI and S curve Tc Σ unstable Stable Cooling>heating heating>cooling Tc unstable Stable Σ

Opacity With , if the disk is convectively unstable.