53,237 research outputs found
A Cosmic Microwave Background feature consistent with a cosmic texture
The Cosmic Microwave Background provides our most ancient image of the
Universe and our best tool for studying its early evolution. Theories of high
energy physics predict the formation of various types of topological defects in
the very early universe, including cosmic texture which would generate hot and
cold spots in the Cosmic Microwave Background. We show through a Bayesian
statistical analysis that the most prominent, 5 degree radius cold spot
observed in all-sky images, which is otherwise hard to explain, is compatible
with having being caused by a texture. From this model, we constrain the
fundamental symmetry breaking energy scale to be phi_0 ~ 8.7 x 10^(15) GeV. If
confirmed, this detection of a cosmic defect will probe physics at energies
exceeding any conceivable terrestrial experiment.Comment: Accepted by Science. Published electronically via Science Express on
25 October 2007, http://www.sciencemag.org/cgi/content/abstract/114869
High energy neutrino oscillation at the presence of the Lorentz Invariance Violation
Due to quantum gravity fluctuations at the Planck scale, the space-time
manifold is no longer continuous, but discretized. As a result the Lorentz
symmetry is broken at very high energies. In this article, we study the
neutrino oscillation pattern due to the Lorentz Invariance Violation (LIV), and
compare it with the normal neutrino oscillation pattern due to neutrino masses.
We find that at very high energies, neutrino oscillation pattern is very
different from the normal one. This could provide an possibility to study the
Lorentz Invariance Violation by measuring the oscillation pattern of very high
energy neutrinos from a cosmological distance.Comment: 11 pages, 6 figure
Black hole mass estimates in quasars - A comparative analysis of high- and low-ionization lines
The inter-line comparison between high- and low-ionization emission lines has
yielded a wealth of information on the quasar broad line region (BLR) structure
and dynamics, including perhaps the earliest unambiguous evidence in favor of a
disk + wind structure in radio-quiet quasars. We carried out an analysis of the
CIV 1549 and Hbeta line profiles of 28 Hamburg-ESO high luminosity quasars and
of 48 low-z, low luminosity sources in order to test whether the
high-ionization line CIV 1549 width could be correlated with Hbeta and be used
as a virial broadening estimator. We analyze intermediate- to high-S/N,
moderate resolution optical and NIR spectra covering the redshifted CIV and
H over a broad range of luminosity log L ~ 44 - 48.5 [erg/s] and
redshift (0 - 3), following an approach based on the quasar main sequence. The
present analysis indicates that the line width of CIV 1549 is not immediately
offering a virial broadening estimator equivalent to H. At the same time
a virialized part of the BLR appears to be preserved even at the highest
luminosities. We suggest a correction to FWHM(CIV) for Eddington ratio (using
the CIV blueshift as a proxy) and luminosity effects that can be applied over
more than four dex in luminosity. Great care should be used in estimating
high-L black hole masses from CIV 1549 line width. However, once corrected
FWHM(CIV) values are used, a CIV-based scaling law can yield unbiased MBH
values with respect to the ones based on H with sample standard
deviation ~ 0.3 dex.Comment: 43 pages, 15 Figures, submitted to A&
Graphite from the viewpoint of Landau level spectroscopy: An effective graphene bilayer and monolayer
We describe an infrared transmission study of a thin layer of bulk graphite
in magnetic fields up to B = 34 T. Two series of absorption lines whose energy
scales as sqrtB and B are present in the spectra and identified as
contributions of massless holes at the H point and massive electrons in the
vicinity of the K point, respectively. We find that the optical response of the
K point electrons corresponds, over a wide range of energy and magnetic field,
to a graphene bilayer with an effective inter-layer coupling 2\gamma_1, twice
the value for a real graphene bilayer, which reflects the crystal ordering of
bulk graphite along the c-axis. The K point electrons thus behave as massive
Dirac fermions with a mass enhanced twice in comparison to a true graphene
bilayer.Comment: 4 pages, 2 figure
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