Disk Structure and Evolution (the so-called model of disk viscosity) Ge/Ay 133.

Slides:

Advertisements

Similar presentations

The Accretion of Poloidal Flux by Accretion Disks Princeton 2005.

Advertisements

ECMWF Governing Equations 1 Slide 1 Governing Equations I by Clive Temperton (room 124) and Nils Wedi (room 128)

Models of Disk Structure, Spectra and Evaporation Kees Dullemond, David Hollenbach, Inga Kamp, Paola DAlessio Disk accretion and surface density profiles.

3D Vortices in Stratified, Rotating, Shearing Protoplanetary Disks April 8, I PAM Workshop I: Astrophysical Fluid Dynamics Philip Marcus – UC Berkeley.

Proto-Planetary Disk and Planetary Formation

Structure and Evolution of Protoplanetary Disks Carsten Dominik University of Amsterdam Radboud University Nijmegen.

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

Francesco Trotta YERAC, Manchester Using mm observations to constrain variations of dust properties in circumstellar disks Advised by: Leonardo.

Nuclear Astrophysics Lecture 5 Thurs. Nov. 21, 2011 Prof. Shawn Bishop, Office 2013, Ex

F.Nimmo EART164 Spring 11 EART164: PLANETARY ATMOSPHERES Francis Nimmo.

Topic: Turbulence Lecture by: C.P. Dullemond

1 The structure and evolution of stars Lecture 2: The equations of stellar structure Dr. Stephen Smartt Department of Physics and Astronomy

Lecture 15: Capillary motion

Processes in Protoplanetary Disks Phil Armitage Colorado.

Ch 24 pages Lecture 8 – Viscosity of Macromolecular Solutions.

Processes in Protoplanetary Disks Phil Armitage Colorado.

Introduction and Properties of Fluids

Boundary Layer Flow Describes the transport phenomena near the surface for the case of fluid flowing past a solid object.

II. Properties of Fluids. Contents 1. Definition of Fluids 2. Continuum Hypothesis 3. Density and Compressibility 4. Viscosity 5. Surface Tension 6. Vaporization.

Equations of Continuity

15. Physics of Sediment Transport William Wilcock (based in part on lectures by Jeff Parsons) OCEAN/ESS

Ge/Ay133 SED studies of disk “lifetimes” & Long wavelength studies of disks.

Properties of stars during hydrogen burning Hydrogen burning is first major hydrostatic burning phase of a star: Hydrostatic equilibrium: a fluid element.

0.1m 10 m 1 km Roughness Layer Surface Layer Planetary Boundary Layer Troposphere Stratosphere height The Atmospheric (or Planetary) Boundary Layer is.

Chapter 9 Solids and Fluids (c).

Engineering H191 - Drafting / CAD The Ohio State University Gateway Engineering Education Coalition Lab 4P. 1Autumn Quarter Transport Phenomena Lab 4.

Convection in Neutron Stars Department of Physics National Tsing Hua University G.T. Chen 2004/5/20 Convection in the surface layers of neutron stars Juan.

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

Stellar Structure Chapter 10. Stellar Structure We know external properties of a star L, M, R, T eff, (X,Y,Z) Apply basic physical principles From this,

Properties of stars during hydrogen burning Hydrogen burning is first major hydrostatic burning phase of a star: Hydrostatic equilibrium: a fluid element.

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

Chapter 1 – Fluid Properties

Processes in Protoplanetary Disks

Interesting News… Regulus Age: a few hundred million years Mass: 3.5 solar masses Rotation Period:

In the analysis of a tilting pad thrust bearing, the following dimensions were measured: h1 = 10 mm, h2 = 5mm, L = 10 cm, B = 24 cm The shaft rotates.

Wind Driven Circulation I: Planetary boundary Layer near the sea surface.

The Air-Sea Momentum Exchange R.W. Stewart; 1973 Dahai Jeong - AMP.

Solar System Physics I Dr Martin Hendry 5 lectures, beginning Autumn 2007 Department of Physics and Astronomy Astronomy 1X Session

Section 5: The Ideal Gas Law The atmospheres of planets (and the Sun too) can be modelled as an Ideal Gas – i.e. consisting of point-like particles (atoms.

Fluid Properties: Liquid or Gas

Basic dynamics  The equations of motion and continuity Scaling Hydrostatic relation Boussinesq approximation  Geostrophic balance in ocean’s interior.

Hydraulics for Hydrographers Basic Hydrodynamics

Xin Xi. 1946: Obukhov Length, as a universal length scale for exchange processes in surface layer. 1954: Monin-Obukhov Similarity Theory, as a starting.

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

Momentum Equations in a Fluid (PD) Pressure difference (Co) Coriolis Force (Fr) Friction Total Force acting on a body = mass times its acceleration (W)

Modeling of Materials Processes using Dimensional Analysis and Asymptotic Considerations Patricio Mendez, Tom Eagar Welding and Joining Group Massachusetts.

Mass Transfer Coefficient

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.

Jan cm 0.25 m/s y V Plate Fixed surface 1.FIGURE Q1 shows a plate with an area of 9 cm 2 that moves at a constant velocity of 0.25 m/s. A Newtonian.

A Submillimeter View of Protoplanetary Disks Sean Andrews University of Hawaii Institute for Astronomy Jonathan Williams & Rita Mann, UH IfA David Wilner,

Lecture Outline Chapter 9 College Physics, 7 th Edition Wilson / Buffa / Lou © 2010 Pearson Education, Inc.

PHYS377: A six week marathon through the firmament by Orsola De Marco Office: E7A 316 Phone: Week 1.5, April 26-29,

15. Physics of Sediment Transport William Wilcock (based in part on lectures by Jeff Parsons) OCEAN/ESS 410.

FREE CONVECTION 7.1 Introduction Solar collectors Pipes Ducts Electronic packages Walls and windows 7.2 Features and Parameters of Free Convection (1)

Conservation of Salt: Conservation of Heat: Equation of State: Conservation of Mass or Continuity: Equations that allow a quantitative look at the OCEAN.

INTRODUCTION TO CONVECTION

Physics 778 – Star formation: Protostellar disks Ralph Pudritz.

Basic dynamics ●The equations of motion and continuity Scaling Hydrostatic relation Boussinesq approximation ●Geostrophic balance in ocean’s interior.

Basic dynamics The equation of motion Scale Analysis

Sarthit Toolthaisong FREE CONVECTION. Sarthit Toolthaisong 7.2 Features and Parameters of Free Convection 1) Driving Force In general, two conditions.

Scales of Motion, Reynolds averaging September 22.

Friction Losses Flow through Conduits Incompressible Flow.

Processes in Protoplanetary Disks Phil Armitage Colorado.

Viscosità Equazioni di Navier Stokes. Viscous stresses are surface forces per unit area. (Similar to pressure) (Viscous stresses)

Convective Core Overshoot Lars Bildsten (Lecturer) & Jared Brooks (TA) Convective overshoot is a phenomenon of convection carrying material beyond an unstable.

Chapter 4 Fluid Mechanics Frank White

OCEAN/ESS Physics of Sediment Transport William Wilcock (based in part on lectures by Jeff Parsons)

Disk Structure and Evolution (the so-called a model of disk viscosity)

Presentation transcript:

Disk Structure and Evolution (the so-called model of disk viscosity) Ge/Ay 133

Recapitulation of passive disk structure equations. I. and mass surface density,, where the in the equation above right is taken to mean the density at the disk midplane. Equation for hydrostatic equilibrium using only stellar gravity. For an ideal gas where c is the sound speed (c 2 = RT). Solving yields the scale height, H,

Recapitulation of passive disk structure equations. II. In the previous analysis we did not consider that there is a radial pressure gradient, which exerts an acceleration since pressure = force/unit area. Thus, a(pressure)= dPA/m=dPA/ Adr. Balancing gravity, centripetal acceleration, and pressure gives: A dr F=PA Thus, the gas in passive disks moves at slightly sub-Keplerian speeds.

CO Can only see Keplerian v M. Simon et al. 2001, PdBI The CO line shape is sensitive to R disk, M star,, Inc.; but the pressure support is highly sub- Keplerian & similar to v doppler in the outer disk. Dent et al. 2005, JCMT v LSR (km/s) T MB (K)

What do other obs. tell us? Radial structure of the MMSN: Mass surface density varies as r -3/2 in this model, what do aperture synthesis observations of circumstellar disks have to say?

Mm-interferometry observations of disks. I. Overview If you ASSUME the temperature and mass surface density vary as power laws of radius, and that the mass opacity coefficient varies as a power of the frequency, analytical fits to resolved mm-wave aperture synthesis data can directly constrain the exponents. Andrews & Williams 2007, ApJ 659, 705

Mass surface density seems flatter than that from the MMSN, while the temperature distribution (at the midplane) is intermediate between that expected for flat and flared disks. Dust growth and settling? The mass surface density is highly uncertain, both due to materials properties and the unconstrained gas:dust ratio. Andrews & Williams 2007, ApJ 659, 705 Mm-interferometry observations of disks. II. Statistical Results

What is viscosity? x y For Newtonian fluids, the shear stress,, is u/ y) and where is the dynamic viscosity, is the kinematic viscosity and is the density Units? m 2 /s or cm 2 /s (CGS= 1 Stokes), that is, a velocity × a length scale. In turbulent fluids, the transport of heat and energy is NOT driven by molecular viscosity, but by eddies. For example, for water: H 2 O (1) ~ Pa-s (dynamic viscosity) Ocean ~ 10 7 Pa-s (from transport) Similarly, in circumstellar disks the molecular gas viscosity is many orders of magnitude too small to account for the observed transport, some other means of generating viscosity must be found. Velocity, u Imagine applying a linear stress field to a fluid (by placing it between a rotating and fixed plate, for example):

Viscous Disks x y In circumstellar disks the molecular gas viscosity is many orders of magnitude too small to account for the observed transport, some other means of generating viscosity must be found. What, roughly, is required in a turbulent model? Time scale ~ 10 5 – 10 6 years at a few tens of AU n ~ cm 2 /s Plausibly, n~v convection L ~ 10 4 cm/s L or L(eddy) ~ cm etc. Source of this viscosity? Opacity from dust? Can work in special circumstances if k is temperature dependent. Most popular culprit is magnetic fields via the Balbus- Hawley instability (more later when we look into planet migration). For this to work the disk must be partially ionized. Velocity, u If viscosity is characterized as velocity × a length scale then the time scale for a fluid to respond should be

The so-called alpha disk model: Assume that the sound speed characterizes the velocity associated with the viscosity and the gas scale height the length scale, multiplied by a dimensionless parameter. Values of a near are needed to fit the observables (more in just a bit). What does this imply about the radial structure of such disks, and do these properties correlate with the fits derived from mm-interferometry?

Radial evolution of a constant disk: Solving the eq. for yields a characteristic time t s, where R 1 is the location at which 40% of the mass lies inside R 1. Gas within R t moves inward. Does R make sense? Note that the fractional ionization by cosmic rays goes like n -1/2, where n=gas density, and so goes up with R! This should help drive the Balbus- Hawley instability. Hartmann et al. 1998, ApJ 495, 385 Time evolution of the mass surface density subjected to a point mass M. The alpha model requires that the viscosity be a power law function of radius (for constant ).

Evolution of MMSN (gas) under viscous dissipation:

Do disks correspond to observations? I. The SED and mass surface density profiles for INDIVIDUAL disks can certainly be well fit with the a disk model. However, when statistical samples of disks are studied, the scatter is large! Andrews & Williams 2007, ApJ 659, 705 Isella et al. (2009)

Do disks correspond to observations? II. The expected trends are likely present, but clearly the actual situation is far more complex than a constant model predicts. Nevertheless, since we have no analytical physics-based models of disk transport, it is difficult to determine what sort of (R,z, t) is appropriate. Andrews & Williams 2007, ApJ 659, 705 What about the dust evolution? Well start looking into this next time…