2,982 research outputs found
Spitzer White Dwarf Planet Limits
We present preliminary limits on the presence of planets around white dwarf
stars using the IRAC photometer on the Spitzer space telescope. Planets emit
strongly in the mid-infrared which allows their presence to be detected as an
excess at these wavelengths. We place limits of for 8 stars assuming
ages of , and for 23 stars.We describe our survey, present our
results and comment on approaches to improve our methodology.Comment: 4 pages, 3 figures, to appear in Proceedings of 15th European White
Dwarf Worksho
Magnetospherically-trapped dust and a possible model for the unusual transits at WD 1145+017
The rapidly evolving dust and gas extinction observed towards WD 1145+017 has
opened a real-time window onto the mechanisms for destruction-accretion of
planetary bodies onto white dwarf stars, and has served to underline the
importance of considering the dynamics of dust particles around such objects.
Here it is argued that the interaction between (charged) dust grains and the
stellar magnetic field is an important ingredient in understanding the physical
distribution of infrared emitting particles in the vicinity of such white
dwarfs. These ideas are used to suggest a possible model for WD 1145+017 in
which the unusual transit shapes are caused by opaque clouds of dust trapped in
the stellar magnetosphere. The model can account for the observed transit
periodicities if the stellar rotation is near 4.5 h, as the clouds of trapped
dust are then located near or within the co-rotation radius. The model requires
the surface magnetic field to be at least around some tens of kG. In contrast
to the eccentric orbits expected for large planetesimals undergoing tidal
disintegration, the orbits of magnetospherically-trapped dust clouds are
essentially circular, consistent with the observations.Comment: 5 pages, accepted to MNRAS Letter
Constraining the Surface Inhomogeneity and Settling Times of Metals on Accreting White Dwarfs
Due to the short settling times of metals in DA white dwarf atmospheres, any
white dwarfs with photospheric metals must be actively accreting. It is
therefore natural to expect that the metals may not be deposited uniformly on
the surface of the star. We present calculations showing how the temperature
variations associated with white dwarf pulsations lead to an observable
diagnostic of the surface metal distribution, and we show what constraints
current data sets are able to provide. We also investigate the effect that
time-variable accretion has on the metal abundances of different species, and
we show how this can lead to constraints on the gravitational settling times.Comment: 4 pages, 5 figures, accepted for publication in the Astrophysical
Journal Letters, updated reference
Outlaw Community Innovations
Recent studies of outlaw communities provide qualitative evidence of their existence and the organisation of the underlying innovation processes. We provide descriptive results from a large scale survey of two online outlaw communities focussing on Microsoft's XBox. In line with previous findings, we identify two types of participants in outlaw communities - user innovators and adopters. Based on 2,256 responses, we find that users modify their XBox mainly to be able to increase the set of available functions of their XBox. Users are also motivated to modify their XBox for the sake of having fun and to conduct pirate behaviour. Finally, the results from our survey suggest that user innovators are largely intrinsically motivated by fun and the intellectual stimulation of writing code for homebrew software
Discovery of Photospheric Calcium Line Strength Variations in the DAZd White Dwarf G29-38
Metals in the photospheres of white dwarfs with Teff between 12,000 and
25,000 K should gravitationally settle out of these atmospheres in 1-2 weeks.
Temporal variations in the line strengths of these metals could provide a
direct measurement of episodic metal accretion. Using archival VLT and Keck
spectroscopy, we find evidence that the DAZd white dwarf G29-38 shows
significant changes in its Ca II K line strength. At the two best-observed
epochs, we find that the Ca line equivalent width (EW) = 165 +- 4 mA (in
1996.885) and 280 +- 8 mA (in 1999.653), which is an increase of 70%. We
consider the effect that pulsation has on the Ca EWs for this known variable
star, and find that it adds an error of < 1 mA to these measurements. Calcium
line strengths at other observational epochs support variations with timescales
as short as two weeks. These Ca EW variations indicate that the metal accretion
process in G29-38, presumably from its debris disk, is episodic on timescales
of a few weeks or less, and thus the accretion is not dominated by
Poynting-Robertson drag from an optically thin, continuous disk, which has a
timescale of ~1 year.Comment: 15 pages, 4 figures, ApJ accepte
New Techniques to Determine Ages of Open Clusters Using White Dwarfs
Currently there are two main techniques for independently determining the ages of stellar populations: main-sequence evolution theory (via cluster isochrones) and white dwarf cooling theory. Open clusters provide the ideal environment for the calibration of these two clocks. Because current techniques to derive cluster ages from white dwarfs are observationally challenging, we discuss the feasibility of determining white dwarf ages from the brighter white dwarfs alone. This would eliminate the requirement of observing the coolest (i.e., faintest) white dwarfs. We discuss our method for testing this new idea, as well as the required photometric precision and prior constraints on metallicity, distance, and reddening. We employ a new Bayesian statistical technique to obtain and interpret results
Pulsational Mapping of Calcium Across the Surface of a White Dwarf
We constrain the distribution of calcium across the surface of the white dwarf star G29-38 by combining time-series spectroscopy from Gemini-North with global time-series photometry from the Whole Earth Telescope. G29-38 is actively accreting metals from a known debris disk. Since the metals sink significantly faster than they mix across the surface, any inhomogeneity in the accretion process will appear as an inhomogeneity of the metals on the surface of the star. We measure the flux amplitudes and the calcium equivalent width amplitudes for two large pulsations excited on G29-38 in 2008. The ratio of these amplitudes best fits a model for polar accretion of calcium and rules out equatorial accretion
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