2,333 research outputs found
A Couplet from Flavored Dark Matter
We show that a couplet, a pair of closely spaced photon lines, in the X-ray
spectrum is a distinctive feature of lepton flavored dark matter models for
which the mass spectrum is dictated by Minimal Flavor Violation. In such a
scenario, mass splittings between different dark matter flavors are determined
by Standard Model Yukawa couplings and can naturally be small, allowing all
three flavors to be long-lived and contribute to the observed abundance. Then,
in the presence of a tiny source of flavor violation, heavier dark matter
flavors can decay via a dipole transition on cosmological timescales, giving
rise to three photon lines. The ratios of the line energies are completely
determined in terms of the charged lepton masses, and constitute a firm
prediction of this framework. For dark matter masses of order the weak scale,
the couplet lies in the keV-MeV region, with a much weaker line in the eV-keV
region. This scenario constitutes a potential explanation for the recent claim
of the observation of a 3.5 keV line. The next generation of X-ray telescopes
may have the necessary resolution to resolve the double line structure of such
a couplet.Comment: 17 pages, 4 figures, 1 haik
Comparing the packing densities of yarns spun by ring, compact and vortex spinning systems using image analysis method
This study is aimed at determining the packing densities of yarns produced by different spinning systems to investigate the fibre distributions for each system. For this purpose, 100% Tencel LF yarns with 19.69 tex linear densities are produced on ring, compact and vortex spinning systems. Cross-sections have been made by hard sectioning method using a rotary microtome. Packing densities of yarns are calculated by image analysis method. Results show that the compact yarns have the highest packing densities while vortex yarns have the lowest. However, differences between the packing densities of ring and compact yarns are not found statistically significant. In this study, density values of yarns (D, g/cm3) are also measured by Uster Tester 5 to evaluate the relationship between the packing density and yarn density values. Results show that the packing density values are parallel to yarn density values
A Dusty Disk Around WD1150-153: Explaining the Metals in White Dwarfs by Accretion from the Interstellar Medium versus Debris Disks
We report the discovery of excess K-band radiation from a metal-rich DAV
white dwarf star, WD1150-153. Our near infrared spectroscopic observations show
that the excess radiation cannot be explained by a (sub)stellar companion, and
is likely to be caused by a debris disk similar to the other DAZ white dwarfs
with circumstellar debris disks. We find that the fraction of DAZ white dwarfs
with detectable debris disks is at least 14%. We also revisit the problem of
explaining the metals in white dwarf photospheres by accretion from the
interstellar medium (ISM). We use the observed interstellar column densities
toward stars in close angular proximity and similar distance as DAZ white
dwarfs to constrain the contribution of accretion from the ISM. We find no
correlation between the accretion density required to supply metals observed in
DAZs with the densities observed in their interstellar environment, indicating
that ISM accretion alone cannot explain the presence of metals in nearby DAZ
white dwarfs. Although ISM accretion will certainly contribute, our analysis
indicates that it is not the dominant source of metals for most DAZ white
dwarfs. Instead, the growing number of circumstellar debris disks around DAZs
suggests that circumstellar material may play a more dominant role in polluting
the white dwarf atmospheres.Comment: ApJ, in pres
Echoes of a decaying planetary system: the gaseous and dusty disks surrounding three white dwarfs
We have performed a comprehensive ground-based observational program aimed at
characterizing the circumstellar material orbiting three single white dwarf
stars previously known to possess gaseous disks. Near-infrared imaging
unambiguously detects excess infrared emission towards Ton 345 and allows us to
refine models for the circumstellar dust around all three white dwarf stars. We
find that each white dwarf hosts gaseous and dusty disks that are roughly
spatially coincident, a result that is consistent with a scenario in which
dusty and gaseous material has its origin in remnant parent bodies of the white
dwarfs' planetary systems. We briefly describe a new model for the gas disk
heating mechanism in which the gaseous material behaves like a "Z II" region.
In this Z II region, gas primarily composed of metals is photoionized by
ultraviolet light and cools through optically thick allowed Ca II-line
emission.Comment: 43 pages, 9 tables, 9 figures. Accepted to Ap
3D Model Atmospheres for Extremely Low-Mass White Dwarfs
We present an extended grid of mean three-dimensional (3D) spectra for
low-mass, pure-hydrogen atmosphere DA white dwarfs (WDs). We use CO5BOLD
radiation-hydrodynamics 3D simulations covering Teff = 6000-11,500 K and logg =
5-6.5 (cgs units) to derive analytical functions to convert spectroscopically
determined 1D temperatures and surface gravities to 3D atmospheric parameters.
Along with the previously published 3D models, the 1D to 3D corrections are now
available for essentially all known convective DA WDs (i.e., logg = 5-9). For
low-mass WDs, the correction in temperature is relatively small (a few per cent
at the most), but the surface gravities measured from the 3D models are lower
by as much as 0.35 dex. We revisit the spectroscopic analysis of the extremely
low-mass (ELM) WDs, and demonstrate that the 3D models largely resolve the
discrepancies seen in the radius and mass measurements for relatively cool ELM
WDs in eclipsing double WD and WD + milli-second pulsar binary systems. We also
use the 3D corrections to revise the boundaries of the ZZ Ceti instability
strip, including the recently found ELM pulsators.Comment: 11 pages, 8 figures, accepted for publication in the Astrophysical
Journa
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