61 research outputs found
On the origin of the featureless soft X-ray excess emission from the Seyfert 1 galaxy ESO~198--G24
We present medium and high resolution X-ray spectral study of a Seyfert 1
galaxy ESO~198--G24 using a long (122 ks) XMM-Newton observation performed in
February 2006. The source has a prominent featureless soft X-ray excess below
2\kev. This makes the source well suited to investigate the origin of the
soft excess. Two physical models -- blurred reflection, and optically thick
thermal Comptonization in a warm plasma, describe the soft-excess equally well
resulting in similar fits in the 0.3-10\kev band. These models also yield
similar fits to the broad-band UV (Optical Monitor) and X-ray data. XMM-Newton
observations performed in 2000, 2001 and 2006 on this source show flux
variability. From 2001 to 2006, the UV flux increased by while the
2-10\kev X-ray flux as well as the soft-excess flux decreased by ~ 20. This
observation can be described in the blurred reflection scenario by a truncated
accretion disk whose inner-most radius had come closer to the blackhole. We
find that the best-fit inner radius of the accretion disk decreases from
R_{in}=4.93_{-1.10}^{+1.12}R_G to R_{in}<2.5R_G from 2001 to 2006. This leads
to an increase in the UV flux and compressing the corona, leading to reduction
of the powerlaw flux and therefore the soft-excess. The blurred reflection
model seems to better describe the soft-excess for this source.Comment: Accepted for publication in the MNRA
Towards a robust estimate of the merger rate evolution using near-IR photometry
We use a combination of deep, high angular resolution imaging data from the
CDFS (HST/ACS GOODS survey) and ground based near-IR images to derive the
evolution of the galaxy major merger rate in the redshift range . We select galaxies on the sole basis of their J-band rest-frame,
absolute magnitude, which is a good tracer of the stellar mass. We find steep
evolution with redshift, with the merger rate for
optically selected pairs, and for pairs selected
in the near-IR. Our result is unlikely to be affected by luminosity evolution
which is relatively modest when using rest-frame J band selection. The
apparently more rapid evolution that we find in the visible is likely caused by
biases relating to incompleteness and spatial resolution affecting the ground
based near IR photometry, underestimating pair counts at higher redshifts in
the near-IR. The major merger rate was 5.6 times higher at
than at the current epoch. Overall 41%(0.5\gyr/) of all
galaxies with have undergone a major merger in the last \sim8
\gyr, where is the merger timescale. Interestingly, we find no effect
on the derived major merger rate due to the presence of the large scale
structure at in the CDFS.Comment: Accepted for Publication in ApJ. 9 Figure
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