158 research outputs found
Models of Accretion Disks
An accretion flow onto a supermassive black hole is the primary process
powering quasars. However, a geometry of this flow is not well constrained.
Both global MHD simulations and observations suggest that there are several
emission components present in the nucleus: an accretion disk, hot plasma
(corona or sphere) with electrons scattering the optical and UV photons, and an
outflow (wind/jet). The relative location and size of these emission
components, as well as their "interplay" affect the emerging quasar spectrum. I
review briefly standard accretion disk models and the recent progress, point
out discrepancies between the predicted and observed spectra and discuss some
issues in fitting these models to the broad-band spectral energy distribution
of quasars. I present examples of models fitted simultaneously to the
optical-UV-X-ray data and possible constraints on the parameters.Comment: Invited review presented at the conference on "The Multicolored
Landscape of Compact Objects and Their Explosive Origins" held on June 11-24,
2006 in Cefalu, Ital
An extraordinary view of the universe : the use of X-ray vision in space science
X-ray emission from cosmic sources indicates that these sources are heated to temperatures exceeding a million degrees or that they contain highly energetic particles. Recent X-ray telescopes, such as the Chandra X-ray Observatory and XMM-Newton, observed thousands of cosmic X-ray sources. These observations greatly impacted our understanding of the physics governing the evolution of structures across the universe. Here, I review and highlight some of these important results
Probing the accretion disk - jet connection via instabilities in the inner accretion flow. From microquasars to quasars
We present various instability mechanisms in the accreting black hole systems
which might indicate at the connection between the accretion disk and jet. The
jets observed in microquasars can have a persistent or blobby morphology.
Correlated with the accretion luminosity, this might provide a link to the
cyclic outbursts of the disk. Such duty-cycle type of behavior on short
timescales results from the thermal instability caused by the radiation
pressure domination. The same type of instability may explain the cyclic
radioactivity of the supermassive black hole systems. The somewhat longer
timescales are characteristic for the instability caused by the partial
hydrogen ionization. The distortions of the jet direction and complex
morphology of the sources can be caused by precession of the disk-jet axis.Comment: 2 pages, 2 figures; Proceedings of the 275 IAU Symposium "Jets at all
scales", Buenos Aires, 13-17.09.2010; eds. G. Romero, R. Sunyaev, T. Bellon
Detecting Unspecified Structure in Low-Count Images
Unexpected structure in images of astronomical sources often presents itself
upon visual inspection of the image, but such apparent structure may either
correspond to true features in the source or be due to noise in the data. This
paper presents a method for testing whether inferred structure in an image with
Poisson noise represents a significant departure from a baseline (null) model
of the image. To infer image structure, we conduct a Bayesian analysis of a
full model that uses a multiscale component to allow flexible departures from
the posited null model. As a test statistic, we use a tail probability of the
posterior distribution under the full model. This choice of test statistic
allows us to estimate a computationally efficient upper bound on a p-value that
enables us to draw strong conclusions even when there are limited computational
resources that can be devoted to simulations under the null model. We
demonstrate the statistical performance of our method on simulated images.
Applying our method to an X-ray image of the quasar 0730+257, we find
significant evidence against the null model of a single point source and
uniform background, lending support to the claim of an X-ray jet
Sherpa: a Mission-Independent Data Analysis Application
The ever-increasing quality and complexity of astronomical data underscores
the need for new and powerful data analysis applications. This need has led to
the development of Sherpa, a modeling and fitting program in the CIAO software
package that enables the analysis of multi-dimensional, multi-wavelength data.
In this paper, we present an overview of Sherpa's features, which include:
support for a wide variety of input and output data formats, including the new
Model Descriptor List (MDL) format; a model language which permits the
construction of arbitrarily complex model expressions, including ones
representing instrument characteristics; a wide variety of fit statistics and
methods of optimization, model comparison, and parameter estimation;
multi-dimensional visualization, provided by ChIPS; and new interactive
analysis capabilities provided by embedding the S-Lang interpreted scripting
language. We conclude by showing example Sherpa analysis sessions.Comment: To appear in Proc. SPIE Conf. 4477. 12 pages, 4 figure
Handbook of X-Ray Astronomy
X-ray astronomy was born in the aftermath of World War II as military rockets were repurposed to lift radiation detectors above the atmosphere for a few minutes at a time. These early flights detected and studied X-ray emission from the Solar corona. The first sources beyond the Solar System were detected during a rocket flight in 1962 by a team headed by Riccardo Giaccom at American Science and Engineering, a company founded by physicists from MIT. The rocket used Geiger counters with a system designed to reduce non-X-ray backgrounds and collimators limiting the region of sky seen by the counters. As the rocket spun, the field of view (FOV) happened to pass over what was later found to be the brightest non-Solar X-ray source; later designated See X-1. It also detected a uniform background glow which could not be resolved into individual sources. A follow-up campaign using X-ray detectors with better spatial resolution and optical telescopes identified See X-1 as an interacting binary with a compact (neutron star) primary. This success led to further suborbital rocket flights by a number of groups. More X-ray binaries were discovered, as well as X-ray emission from supernova remnants, the radio galaxies M87 and Cygnus-A, and the Coma cluster. Detectors were improved and Geiger counters were replaced by proportional counters, which provided information about energy spectra of the sources. A constant challenge was determining precise positions of sources as only collimators were available
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