xion: reflected spectrum of photo-ionized accretion disk/ring
This model describes the reflected
spectra of a photo-ionized accretion disk or a ring if one so chooses. The
approach is similar to the one used for tables with stellar spectra. Namely, a
large number of models are computed for a range of values of the spectral
index, the incident X-ray flux, disk gravity, the thermal disk flux and iron
abundance. Each model's output is an un-smeared reflected spectrum for 5
different inclination angles ranging from nearly pole-on to nearly face on,
stored in a look-up table. The default geometry is that of a lamppost, with
free parameters of the model being the height of the X-ray source above the
disk, hX, the dimensionless accretion rate through the disk, 
, the luminosity of the X-ray
source, LX, the inner and outer disk radii, and the spectral
index. This defines the gravity parameter, the ratio of X-ray to thermal
fluxes, etc., for each radius, which allows the use of a look-up table to
approximate the reflected spectrum. This procedure is repeated for about 30
different radii. The total disk spectrum is then obtained by integrating over
the disk surface, including relativistic smearing of the spectrum for a
non-rotating black hole (e.g., Fabian 1989).
In addition, the geometry of a central sphere (with power-law optically thin emissivity inside it) plus an outer cold disk, and the geometry of magnetic flares are available (par13 = 2 and 3, respectively). One can also turn off relativistic smearing to see what the local disk spectrum looks like (par12 = 2 in this case; otherwise leave it at 4). In addition, par11 = 1 produces reflected plus direct spectrum/direct; par11 =2 produces (incident + reflected)/incident [note that normalization of incident and direct are different because of solid angles covered by the disk; 2 should be used for magnetic flare model]; and par11 =3 produces reflected/incident. Abundance is controlled by par9 and varies between 1 and 4 at the present. A much more complete description of the model will be presented in Nayakshin et al. 2001 (currently available at http://adsabs.harvard.edu/cgi-bin/nph-bib_query?bibcode=2001ApJ...546..406N&db_key=AST&data_type=HTML&format=&high=4230b2429423803)
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par1 |
height of the source above the disk (in Schwarzschild radii) |
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par2 |
ratio of the X-ray source luminosity to that of the disk |
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par3 |
accretion rate (in Eddington units) |
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par4 |
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par5 |
inner radius of the disk (in Schwarzschild radii) |
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par6 |
outer radius of the disk (in Schwarzschild radii) |
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par7 |
photon index of the source |
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par8 |
redshift z |
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par9 |
Fe abundance relative to Solar (which is defined as |
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par10 |
Exponential high energy cut-off energy for the source |
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par11 |
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par12 |
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par13 |
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Note that setting par13 to 2 gives a central hot sphere
with luminosity law |
the inclination angle (1 =
face-on)
by number relative to H)
lamppost
central hot sphere
with outer cold disk
magnetic flares
above a cold disk
. The
inner radius of the sphere is 3 Schwarzschild radii and the outer radius is
equal to par1. Only the case with par5 
par1 has been tested so
far.