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MHD Simulations of Radiation Pressure Dominated Accretion Disks

Title: MHD Simulations of Radiation Pressure Dominated Accretion Disks

Speaker: James M. Stone (Princeton)  

Time & Place: Thursday, 3:00pm, September 25th, Lecture Hall, 3rd floor   

Abstract: For black holes accreting at anything more than a small fraction of the Eddington limit, the inner regions of the flow will be dominated by radiation rather than gas pressure.  I will present results from a new study of the magnetohydrodynamics of accretion disks in this regime, using new numerical methods based on a formal solution of the radiation transfer equation using short characteristics, rather than the flux-limited diffusion approximation.  For gas pressure dominated disks, long-lived stable vertical structures in which turbulent heating is balanced by radiative cooling are observed.  However, when radiation pressure greatly exceeds gas pressure, we find the disk always undergoes a thermal runaway, either collapsing or expanding over several thermal times.  The physics of this runaway is quite different from the classical linear instability in radiation dominated alpha disks predicted by Shakura and Sunyaev. Saturation of the runaway will require global models of radiation pressure dominated accretion flows, and we discuss future work on this problem.  

Biog: James Stone is a Professor in the Department of Astrophysical Sciences at Princeton University, with a joint appointment in the Program in Applied and Computational Mathematics (PACM). Stone's research interests are in the use of numerical methods to study nonlinear and multidimensional fluid dynamics in astrophysical systems, such as accretion flows onto black holes. Currently he is Director of the Princeton Institute for Computational Science and Engineering (PICSciE), which supports and provides training for high-performance computing systems on the Princeton campus.

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