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

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Presentation transcript:

Warm Absorbers: Are They Disk Outflows? Daniel Proga UNLV

Collaborators T. Kallman (GSFC/NASA) T. Kallman (GSFC/NASA) J. Stone (Princeton University) J. Stone (Princeton University) N. Arav (CASA/University of Colorado) N. Arav (CASA/University of Colorado) G. Richards (STScI) G. Richards (STScI)

OUTLINE Introduction Introduction Multidimensional Time-Dependent Simulations Multidimensional Time-Dependent Simulations Conclusions Conclusions Future Work Future Work

AGN are powered by gas accretion onto a supermassive black hole.

Arav et a. (1999) -- HST and ground-based obs. of PG

NGC 3785: Warm Absorbers NGC 3785: Warm Absorbers Chandra spectrum (Kaspi et al. 2002). The H-like and He-like lines of the identified ions are marked in red and blue, respectively. Lines from other ions (lower ionization metals and Fe XVII Fe XXIV) are marked in green. Chandra spectrum (Kaspi et al. 2002). The H-like and He-like lines of the identified ions are marked in red and blue, respectively. Lines from other ions (lower ionization metals and Fe XVII Fe XXIV) are marked in green.

Mass outflows are very common in AGN Mass outflows are very common in AGN Outflows are important because they can change Outflows are important because they can change - the rate of accretion onto a black hole; - the rate of accretion onto a black hole; - the AGN radiation; - the AGN radiation; - environment of the AGN, its host galaxy, and IGM - environment of the AGN, its host galaxy, and IGM … Outflows: another aspect of activity

There are many questions: Where do the outflows come from? Where do the outflows come from? How do the outflows avoid full ionization? How do the outflows avoid full ionization? What is the geometry and structure of the outflows (e.g., wind or moving clouds)? What is the geometry and structure of the outflows (e.g., wind or moving clouds)? What force accelerates the outflows? What force accelerates the outflows? What is the mass loss rate, momentum, and energy of the outflows? What is the mass loss rate, momentum, and energy of the outflows?…

An accretion disk is the most plausible origin of AGN outflows.

What can drive an outflow? Thermal expansion (the Sun, X-ray binaries) Thermal expansion (the Sun, X-ray binaries) Magnetic fields (stars, accretion disks) Magnetic fields (stars, accretion disks) Radiation pressure (OB stars, accretion disks) Radiation pressure (OB stars, accretion disks)

Numerical HD simulations. Proga, Stone & Kallman (2000)

Calculations Geometry: Geometry: axial symmetry – 2D spatial domain but 3D axial symmetry – 2D spatial domain but 3D velocity (i.e., so-called 2.5D) velocity (i.e., so-called 2.5D) Assumptions: Assumptions: disk - flat, Keplerian and optically thick; disk - flat, Keplerian and optically thick; radiation field (?) radiation field (?) (the Shakura Sunyaev model); (the Shakura Sunyaev model); central engine - sphere; central engine - sphere; radiation field (?) radiation field (?) (the black body radiation, (the black body radiation, comptonization) comptonization)

gas - an ideal gas with adiabatic EOS gas - an ideal gas with adiabatic EOS Forces: Forces: gravity, rotation, gas and radiation gravity, rotation, gas and radiation pressure effects pressure effects The structure and evolution of a wind: The structure and evolution of a wind: the ZEUS code is used to solve the ZEUS code is used to solve the equations of HD that describe the equations of HD that describe the conservation of mass, the conservation of mass, momentum, and momentum, and energy. energy. We allow for radiative heating and cooling. We allow for radiative heating and cooling.

The equations of hydrodynamics

the Eddington factor the radiation force due to electron scattering the Eddington luminosity

The accretion disk

the radiation force due to lines the total radiation force

Radiation force Radiation force The Sobolev approximation (a generalized version) and the force multiplier due to Castor, Abbott, & Klein (1975)

An angle-adaptive quadrature to evaluate the flux integral

What do we need to specify? - the mass of the central object; - the mass of the central object; - the mass accretion rate; - the mass accretion rate; - the luminosity of the central object; - the luminosity of the central object; and the SED of the central object and the SED of the central object radiation radiation

CASE ONE: no X-rays

Proga, Stone & Drew (1998)

HD simulations and their line profiles

Applications: Cataclysmic Variables Cataclysmic Variables (Proga, Drew, Stone 1998, 1999 … (Proga, Drew, Stone 1998, 1999 … Proga 2003 added magnetic fields, Proga 2003 added magnetic fields, Proga et al computed synthetic line profiles) Proga et al computed synthetic line profiles) Young Stellar Objects Young Stellar Objects (Drew et al and Oudmaijer et al. 1999) (Drew et al and Oudmaijer et al. 1999)

Proga (1999) and Drew & Proga (2000)

CASE TWO: X-rays & UV

Proga & Kallman (2004) also Proga, Stone, & Kallman (2000) UV and no X-rays UV and X-rays

The wind solution is sensitive to the BH mass and accretion rate.

What is the origin of the outflows? What is the origin of the outflows? What force accelerates the outflows? What force accelerates the outflows? How do the outflows avoid full ionization? How do the outflows avoid full ionization? What is the geometry and structure of the outflows (e.g., wind or moving clouds)? What is the geometry and structure of the outflows (e.g., wind or moving clouds)? What is the mass loss rate, momentum, and energy of the outflows? What is the mass loss rate, momentum, and energy of the outflows?… Summary ASSUMED

Conclusions LD winds can withstand external X-rays. LD winds can withstand external X-rays. LD disk winds can be powerful but only for high BH masses and accretion rates. LD disk winds can be powerful but only for high BH masses and accretion rates. They change the radiation of the source They change the radiation of the source (i.e., the spectrum and total flux depend on orientation). (i.e., the spectrum and total flux depend on orientation). LD disk wind models can explain observed UV line absorption (and likely capable of reproducing observed absorption lines). LD disk wind models can explain observed UV line absorption (and likely capable of reproducing observed absorption lines). The models predict a warm absorbing outflow but its velocity appears too high to account for warm absorbers observed in AGN. The models predict a warm absorbing outflow but its velocity appears too high to account for warm absorbers observed in AGN.

Quenching Disk Corona Disk Disk and inflow/outflow Disk and corona Disk and ???? THIS TALK