29 research outputs found
Constraints on Inner Disk Evolution Timescales: A Disk Census of the eta Chamaeleontis Young Cluster
We present new L' (3.8-micron) observations of stars in the nearby (~97 pc)
young (~6 Myr) compact cluster around eta Chamaeleontis, obtained with the
European Southern Observatory's Very Large Telescope in Paranal, Chile. Our
data, combined with J,H, Ks photometry from the 2-Micron All Sky Survey, reveal
that only two of the 12 members surveyed harbor L'-band excesses consistent
with optically thick inner disks; both are also likely accretors. Intriguingly,
two other stars with possible evidence for on-going accretion, albeit at very
low rates, do not show significant infrared excess: this may imply substantial
grain growth and/or partial clearing of the inner disk region, as expected in
planet formation scenarios. Our findings suggest that eta Cha stars are in an
epoch when disks are rapidly evolving, perhaps due to processes related to
planet building, and provide further constraints on inner disk lifetimes.Comment: accepted for publication in Astrophysical Journal Letter
First Evidence of a Precessing Jet Excavating a Protostellar Envelope
We present new, sensitive, near-infrared images of the Class I protostar,
Elias 29, in the Ophiuchus cloud core. To explore the relationship between the
infall envelope and the outflow, narrowband H2 1-0 S(1), Br-gamma, and
narrowband K-continuum filters were used to image the source with the
Wide-Field Infrared Camera on the Hale 5m telescope and with Persson's
Auxiliary Nasmyth Infrared Camera on the Baade 6.5 m telescope. The source
appears as a bipolar, scattered light nebula, with a wide opening angle in all
filters, as is typical for late-stage protostars. However, the pure H2
emission-line images point to the presence of a heretofore undetected
precessing jet. It is argued that high-velocity, narrow, precessing jets
provide the mechanism for creating the observed wide-angled outflow cavity in
this source.Comment: 11 pages, 1 figure, 1 tabl
A Near-Infrared L Band Survey of the Young Embedded Cluster NGC 2024
We present the results of the first sensitive L band (3.4 micron) imaging
study of the nearby young embedded cluster NGC 2024. Two separate surveys of
the cluster were acquired in order to obtain a census of the circumstellar disk
fraction in the cluster. From an analysis of the JHKL colors of all sources in
our largest area, we find an infrared excess fraction of > 86%. The JHKL colors
suggest that the infrared excesses arise in circumstellar disks, indicating
that the majority of the sources which formed in the NGC 2024 cluster are
currently surrounded by, and likely formed with circumstellar disks. The excess
fractions remain very high, within the errors, even at the faintest L
magnitudes from our deeper surveys suggesting that disks form around the
majority of the stars in very young clusters such as NGC 2024 independent of
mass. From comparison with published JHKL observations of Taurus, we find the K
- L excess fraction in NGC 2024 to be consistent with a high initial incidence
of circumstellar disks in both NGC 2024 and Taurus. Because NGC 2024 represents
a region of much higher stellar density than Taurus, this suggests that disks
may form around most of the YSOs in star forming regions independent of
environment. We find a relatively constant JHKL excess fraction with increasing
cluster radius, indicating that the disk fraction is independent of location in
the cluster. In contrast, the JHK excess fraction increases rapidly toward the
central region of the cluster, and is most likely due to contamination of the K
band measurements by bright nebulosity in the central regions of the cluster.
We identify 45 candidate protostellar sources in the central regions of the NGC
2024 cluster, and find a lower limit on the protostellar phase of early stellar
evolution of 0.4 - 1.4 X 10^5 yr, similar to that in Taurus.Comment: 37 pages, 8 figures, 3 tables, To appear in the Astronomical Journa
A Disk Census for Young Brown Dwarfs
Recent surveys have identified sub-stellar objects down to planetary masses
in nearby star-forming regions. Reliable determination of the disk frequency in
young brown dwarfs is of paramount importance to understanding their origin.
Here we report the results of a systematic study of infrared L'-band
(3.8-micron) disk excess in ~50 spectroscopically confirmed objects near and
below the sub-stellar boundary in several young clusters. Our observations,
using the ESO Very Large Telescope, Keck I and the NASA Infrared Telescope
Facility, reveal that a significant fraction of brown dwarfs harbor disks at a
very young age. Their inner disk lifetimes do not appear to be vastly different
from those of disks around T Tauri stars. Our findings are consistent with the
hypothesis that sub-stellar objects form via a mechanism similar to solar-mass
stars.Comment: accepted for publication in The Astronomical Journa
A Significant Population of Candidate New Members of the Ï Ophiuchi Cluster
We present a general method for identifying the pre-main-sequence population of any star-forming region, unbiased with respect to the presence or absence of disks, in contrast to samples selected primarily via their mid-infrared emission from Spitzer surveys. We have applied this technique to a new, deep, wide-field, near-infrared imaging survey of the Ï Ophiuchi cloud core to search for candidate low-mass members. In conjunction with published Spitzer IRAC photometry and least-squares fits of model spectra (COND, DUSTY, NextGen, and blackbody) to the observed spectral energy distributions, we have identified 948 candidate cloud members within our 90% completeness limits of J = 20.0, H = 20.0, and Ks = 18.50. This population represents a factor of ~3 increase in the number of known young stellar objects in the Ï Ophiuchi cloud. A large fraction of the candidate cluster members (81% ± 3%) exhibit infrared excess emission consistent with the presence of disks, thus strengthening the possibility of their being bona fide cloud members. Spectroscopic follow-up will confirm the nature of individual objects, better constrain their parameters, and allow an initial mass function to be derived
Mid-Infrared Observations of Class I/Flat-Spectrum Systems in Six Nearby Molecular Clouds
We have obtained new mid-infrared observations of 65 Class I/Flat-Spectrum
(F.S.) objects in the Perseus, Taurus, Chamaeleon I/II, Rho Ophiuchi, and
Serpens dark clouds. We detected 45/48 (94%) of the single sources, 16/16
(100%) of the primary components, and 12/16 (75%) of the secondary/triple
components of the binary/multiple objects surveyed. The composite spectral
energy distributions (SEDs) for all of our sample sources are either Class I or
F.S., and, in 15/16 multiple systems, at least one of the individual components
displays a Class I or F.S. spectral index. However, the occurrence of mixed
pairings, such as F.S. with Class I, F.S. with Class II, and, in one case, F.S.
with Class III, is surprisingly frequent. Such behaviour is not consistent with
that of multiple systems among T Tauri stars (TTS), where the companion of a
classical TTS also tends to be a classical TTS, although other mixed pairings
have been previously observed among Class II objects. Based on an analysis of
the spectral indices of the individual binary components, there appears to be a
higher proportion of mixed Class I/F.S. systems (65-80%) than that of mixed
Classical/Weak-Lined TTS (25-40%), demonstrating that the envelopes of Class I/
F.S. systems are rapidly evolving during this evolutionary phase. We report the
discovery of a steep spectral index secondary companion to ISO-ChaI 97,
detected for the first time via our mid-infrared observations. In our previous
near- infrared imaging survey of binary/multiple Class I/F.S. sources, ISO-ChaI
97 appeared to be single. With a spectral index of Alpha >= 3.9, the secondary
component of this system is a member of a rare class of very steep spectral
index objects, those with Alpha > 3. Only three such objects have previously
been reported, all of which are either Class 0 or Class I.Comment: 31 pages, 4 figures, 6 table
A Mid-Infrared Study of the Young Stellar Population in the NGC 2024 Cluster
We present the results of the first broadband 10.8 um survey of the NGC 2024
cluster. The mid-infrared data were combined with our previously published JHKL
photometry in order to construct spectral energy distributions for all detected
sources. The main scientific goals were to investigate the nature of the young
stellar objects (YSOs) in the cluster, and to examine the efficiency of
detecting circumstellar disk sources from near-infrared JHKL color-color
diagrams. Out of 59 sources surveyed having K-band magnitudes K < 10.5, we
detected 35 (~59%) at 10 um. Combining these detections, and upper limits for
the non-detections, with existing JHKL data, we identify 1 Class I, 6 flat
spectrum, 28 Class II and 5 Class III sources. We find a circumstellar disk
fraction for NGC 2024 of ~85% +/- 15%, which confirms earlier published
suggestions that the majority, if not all, of the stars in NGC 2024 formed with
disks, and these disks still exist at the present time. In addition, all but
one of the disk sources identified in our survey lie in the infrared excess
region of the JHKL color-color diagram for the cluster. This demonstrates that
JHKL color-color diagrams are extremely efficient in identifying YSOs with
disks. Of the 14 sources with K - L colors suggestive of protostellar objects,
\~29% are protostellar in nature, while ~7% are true Class I YSOs. This may be
due to extinction producing very red K - L colors in Class II YSOs, thus making
them appear similar in color to protostars. This suggests caution must be
applied when estimating the sizes and lifetimes of protostellar populations
within star forming regions based on K - L colors alone. Finally, we calculate
the luminosities of the Class II YSOs in NGC 2024, rho Oph and Taurus and
discuss the results.Comment: 30 pages, 8 figures, paper to appear in March A
Circumstellar Disks in the IC 348 Cluster
We report the results of the first sensitive L-band (3.4 micron) imaging
survey of the young IC 348 cluster in Perseus. In conjunction with previously
acquired JHK (1.25, 1.65, 2.2 micron) observations, we use L-band data to
obtain a census of the circumstellar disk population to m_K=m_L<=12.0 in the
central 110 square arcmin region of the cluster. An analysis of the JHKL colors
of 107 sources indicates that 65% +/- 8% of the cluster membership possesses
(inner) disks. This fraction is lower than those (86% +/- 8% and 80% +/- 7%)
obtained from similar JHKL surveys of the younger NGC 2024 and Trapezium
clusters, suggesting that the disk fraction in clusters decreases with cluster
age. Sources with circumstellar disks in IC 348 have a median age of 0.9 Myr,
while the diskless sources have a median age of 1.4 Myr, for a cluster distance
of 320 pc. Although the difference in the median ages between the two
populations is only marginally significant, our results suggest that over a
timescale of 2 - 3 Myr, more than a third of the disks in the IC 348 cluster
disappear. Moreover, we find that at a very high confidence level, the disk
fraction is a function of spectral type. All stars earlier than G appear
diskless, while stars with spectral types G and later have a disk fraction
ranging between 50% - 67%, with the latest type stars having the higher disk
fraction. This suggests that the disks around stars with spectral types G and
earlier have evolved more rapidly than those with later spectral types. The
L-band disk fraction for sources with similar ages in both IC 348 and Taurus is
the same, within the errors, suggesting that, at least in clusters with no O
stars, the disk lifetime is independent of environment.Comment: 25 pages, 4 figures. Paper to appear in April A