Monte Carlo Radiation Transfer in Circumstellar Disks Jon E. Bjorkman Ritter Observatory.

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Presentation transcript:

Monte Carlo Radiation Transfer in Circumstellar Disks Jon E. Bjorkman Ritter Observatory

Systems with Disks Infall + Rotation –Young Stellar Objects (T Tauri, Herbig Ae/Be) –Mass Transfer Binaries –Active Galactic Nuclei (Black Hole Accretion Disks) Outflow + Rotation (?) –AGBs (bipolar planetary nebulae) –LBVs (e.g., Eta Carinae) –Oe/Be, B[e] Rapidly rotating (V rot = 350 km s -1 ) Hot stars (T = 20000K) Ideal laboratory for studying disks

3-D Radiation Transfer Transfer Equation –Ray-tracing (requires  -iteration) –Monte Carlo (exact integration using random paths) May avoid  -iteration automatically an adaptive mesh method –Paths sampled according to their importance

Monte Carlo Radiation Transfer Transfer equation traces flow of energy Divide luminosity into equal energy packets (“photons”) –Number of physical photons –Packet may be partially polarized

Monte Carlo Radiation Transfer Pick random starting location, frequency, and direction –Split between star and envelope StarEnvelope

most CPU time Monte Carlo Radiation Transfer Doppler Shift photon packet as necessary –packet energy is frame-dependent Transport packet to random interaction location

Monte Carlo Radiation Transfer Randomly scatter or absorb photon packet If photon hits star, reemit it locally When photon escapes, place in observation bin (direction, frequency, and location) REPEAT times

Sampling and Measurements MC simulation produces random events –Photon escapes –Cell wall crossings –Photon motion –Photon interactions Events are sampled –Samples => measurements (e.g., Flux) –Histogram => distribution function (e.g., I )

SEDs and Images Sampling Photon Escapes

SEDs and Images Source Function Sampling –Photon interactions (scatterings/absorptions) –Photon motion (path length sampling)

Monte Carlo Maxims Monte Carlo is EASY –to do wrong (G.W Collins III) –code must be tested quantitatively –being clever is dangerous –try to avoid discretization The Improbable event WILL happen –code must be bullet proof –and error tolerant

Monte Carlo Assessment Advantages –Inherently 3-D –Microphysics easily added (little increase in CPU time) –Modifications do not require large recoding effort –Embarrassingly parallelizable Disadvantages –High S/N requires large N  –Achilles heel = no photon escape paths; i.e., large optical depth

Improving Run Time Photon paths are random –Can reorder calculation to improve efficiency Adaptive Monte Carlo –Modify execution as program runs High Optical Depth –Use analytic solutions in “interior” + MC “atmosphere” Diffusion approximation (static media) Sobolev approximation (for lines in expanding media) –Match boundary conditions

MC Radiative Equilibrium Sum energy absorbed by each cell Radiative equilibrium gives temperature When photon is absorbed, reemit at new frequency, depending on T –Energy conserved automatically Problem: Don’t know T a priori Solution: Change T each time a photon is absorbed and correct previous frequency distribution avoids iteration

Temperature Correction Bjorkman & Wood 2001 Frequency Distribution:

Disk Temperature Bjorkman 1998

Effect of Disk on Temperature Inner edge of disk –heats up to optically thin radiative equilibrium temperature At large radii –outer disk is shielded by inner disk –temperatures lowered at disk mid-plane

T Tauri Envelope Absorption

Disk Temperature Snow Line Water Ice Methane Ice

CTTS Model SED

AGN Models Kuraszkiewicz, et al. 2003

Spectral Lines Lines very optically thick –Cannot track millions of scatterings Use Sobolev Approximation (moving gas) –Sobolev length –Sobolev optical depth –Assume S, , etc. constant (within l)

Split Mean Intensity Solve analytically for J local Effective Rate Equations Spectral Lines

Resonance Line Approximation Two-level atom => pure scattering Find resonance location If photon interacts –Reemit according to escape probability –Doppler shift photon; adjust weight

NLTE Ionization Fractions Abbott, Bjorkman, & MacFarlane 2001

Wind Line Profiles Bjorkman 1998 pole-on edge-on

NLTE Monte Carlo RT Gas opacity depends on: –temperature –degree of ionization –level populations During Monte Carlo simulation: –sample radiative rates Radiative Equilibrium –Whenever photon is absorbed, re-emit it After Monte Carlo simulation: –solve rate equations –update level populations and gas temperature –update disk density (integrate HSEQ) determined by radiation field

Be Star Disk Temperature Carciofi & Bjorkman 2004

Disk Density Carciofi & Bjorkman 2004

NLTE Level Populations Carciofi & Bjorkman 2004

Be Star H  Profile Carciofi and Bjorkman 2003

SED and Polarization Carciofi & Bjorkman 2004

IR Excess Carciofi & Bjorkman 2004

Future Work Spitzer Observations –Detecting high and low mass (and debris) disks –Disk mass vs. cluster age will determine disk clearing time scales –SED evolution will help constrain models of disk dissipation –Galactic plane survey will detect all high mass star forming regions –Begin modeling the geometry of high mass star formation Long Term Goals –Combine dust and gas opacities –include line blanketing –Couple radiation transfer with hydrodynamics

Acknowledgments Rotating winds and bipolar nebulae –NASA NAGW-3248 Ionization and temperature structure –NSF AST –NSF AST Geometry and evolution of low mass star formation –NASA NAG Collaborators: A. Carciofi, K.Wood, B.Whitney, K. Bjorkman, J.Cassinelli, A.Frank, M.Wolff UT Students: B. Abbott, I. Mihaylov, J. Thomas REU Students: A. Moorhead, A. Gault

FluxPolarization Bjorkman & Carciofi 2003 Inner Disk: NLTE Hydrogen Flared Keplerian h 0 = 0.07,  = 1.5 R * < r < R dust Outer Disk: Dust Flared Keplerian h 0 = 0.017,  = 1.25 R dust < r < R * High Mass YSO

Protostar Evolutionary Sequence i =80i =30 Mid IR Image Density SED Whitney, Wood, Bjorkman, & Cohen 2003

Protostar Evolutionary Sequence Mid IR Image DensitySED i =80i =30 Whitney, Wood, Bjorkman, & Cohen 2003

Disk Evolution: SED Wood, Lada, Bjorkman, Whitney & Wolff 2001

Disk Evolution: Color Excess Wood, Lada, Bjorkman, Whitney & Wolff 2001

Determining the Disk Mass Wood, Lada, Bjorkman, Whitney & Wolff 2001

Gaps in Protoplanetary Disks Smith et al. 1999

Disk Clearing (Inside Out) Wood, Lada, Bjorkman, Whitney & Wolff 2001

GM AUR Scattered Light Image H J Schneider et al Model Residuals i = 55 i = 50 Observations

GM AUR SED Inner Disk Hole = 4 AU Schneider et al. 2003Rice et al. 2003

Planet Gap-Clearing Model Rice et al. 2003

Protoplanetary Disks Surface Density i = 5 i = 75 i = 30