1,083 research outputs found
Direct Detection of Extra-Solar Comets is Possible
The dust tails of comets similar to Hale-Bopp can scatter as much optical
light as does the Earth. Space-based observatories such as the Terrestrial
Planet Finder or Darwin that will detect extra-solar terrestrial planets also
will be able to detect extra-solar comets.Comment: 17 pages, 4 figures, AJ, in pres
Observational constraints on circumstellar dust
There is an enormous range in the properties of stars that are losing mass. The red giants responsible for injecting roughly half or more of the material into the interstellar medium are reviewed. The physical properties are described for the out flowing gases. Broadband observation constaints on the dust are described by use of spectrum analysis. Circumstellar dust is identified by carbon-carbon and carbon-hydrogen bonds
Water Fractions in Extrasolar Planetesimals
With the goal of using externally-polluted white dwarfs to investigate the
water fractions of extrasolar planetesimals, we assemble from the literature a
sample that we estimate to be more than 60% complete of DB white dwarfs warmer
than 13,000 K, more luminous than 3 10 L and within
80 pc of the Sun. When considering all the stars together, we find the summed
mass accretion rate of heavy atoms exceeds that of hydrogen by over a factor of
1000. If so, this sub-population of extrasolar asteroids treated as an ensemble
has little water and is at least a factor of 20 drier than CI chondrites, the
most primitive meteorites. In contrast, while an apparent "excess" of oxygen in
a single DB can be interpreted as evidence that the accreted material
originated in a water-rich parent body, we show that at least in some cases,
there can be sufficient uncertainties in the time history of the accretion rate
that such an argument may be ambiguous. Regardless of the difficulty associated
with interpreting the results from an individual object, our analysis of the
population of polluted DBs provides indirect observational support for the
theoretical view that a snow line is important in disks where rocky
planetesimals form.Comment: Accepted for publication in the Astronomical Journal, 22 pages, 4
figures, 1 tabl
Two Extrasolar Asteroids with Low Volatile-Element Mass Fractions
Using ultraviolet spectra obtained with the Cosmic Origins Spectrograph on
the Hubble Space Telescope, we extend our previous ground-based optical
determinations of the composition of the extrasolar asteroids accreted onto two
white dwarfs, GD 40 and G241-6. Combining optical and ultraviolet spectra of
these stars with He-dominated atmospheres, 13 and 12 polluting elements are
confidently detected in GD 40 and G241-6, respectively. For the material
accreted onto GD 40, the volatile elements C and S are deficient by more than a
factor of 10 and N by at least a factor of 5 compared to their mass fractions
in primitive CI chondrites and approach what is inferred for bulk Earth. A
similar pattern is found for G241-6 except that S is undepleted. We have also
newly detected or placed meaningful upper limits for the amount of Cl, Al, P,
Ni and Cu in the accreted matter. Extending results from optical studies, the
mass fractions of refractory elements in the accreted parent bodies are similar
to what is measured for bulk Earth and chondrites. Thermal processing, perhaps
interior to a snow line, appears to be of central importance in determining the
elemental compositions of these particular extrasolar asteroids.Comment: 37 pages, 13 figures, 5 tables, ApJ, accepte
The Discovery of the Most Metal-Rich White Dwarf: Composition of a Tidally Disrupted Extrasolar Dwarf Planet
Cool white dwarf stars are usually found to have an outer atmosphere that is
practically pure in hydrogen or helium. However, a small fraction have traces
of heavy elements that must originate from the accretion of extrinsic material,
most probably circumstellar matter. Upon examining thousands of Sloan Digital
Sky Survey spectra, we discovered that the helium-atmosphere white dwarf SDSS
J073842.56+183509.6 shows the most severe metal pollution ever seen in the
outermost layers of such stars. We present here a quantitative analysis of this
exciting star by combining high S/N follow-up spectroscopic and photometric
observations with model atmospheres and evolutionary models. We determine the
global structural properties of our target star, as well as the abundances of
the most significant pollutants in its atmosphere, i.e., H, O, Na, Mg, Si, Ca,
and Fe. The relative abundances of these elements imply that the source of the
accreted material has a composition similar to that of Bulk Earth. We also
report the signature of a circumstellar disk revealed through a large infrared
excess in JHK photometry. Combined with our inferred estimate of the mass of
the accreted material, this strongly suggests that we are witnessing the
remains of a tidally disrupted extrasolar body that was as large as Ceres.Comment: 7 pages in emulateapj, 5 figures, accepted for publication in Ap
Ancient planetary systems are orbiting a large fraction of white dwarf stars
Infrared studies have revealed debris likely related to planet formation in
orbit around ~30% of youthful, intermediate mass, main sequence stars. We
present evidence, based on atmospheric pollution by various elements heavier
than helium, that a comparable fraction of the white dwarf descendants of such
main sequence stars are orbited by planetary systems. These systems have
survived, at least in part, through all stages of stellar evolution that
precede the white dwarf. During the time interval (~200 million years) that a
typical polluted white dwarf in our sample has been cooling it has accreted
from its planetary system the mass of one of the largest asteroids in our solar
system (e.g., Vesta or Ceres). Usually, this accreted mass will be only a
fraction of the total mass of rocky material that orbits these white dwarfs;
for plausible planetary system configurations we estimate that this total mass
is likely to be at least equal to that of the Sun's asteroid belt, and perhaps
much larger. We report abundances of a suite of 8 elements detected in the
little studied star G241-6 that we find to be among the most heavily polluted
of all moderately bright white dwarfs.Comment: 31 pages, 4 figures, 5 tables. Accepted for the Astrophysical
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