TY - JOUR
T1 - Near-infrared Imaging and Spectroscopic Survey of the Southern Region of the Young Open Cluster NGC 2264
AU - Mariñas, Naibí
AU - Lada, Elizabeth A.
AU - Teixeira, Paula S.
AU - Lada, Charles J.
PY - 2013/8/1
Y1 - 2013/8/1
N2 - We have obtained JHK near-IR images and JH band low-resolution spectra
of candidate members of the southern region of the young open cluster
NGC 2264. We have determined spectral types from H-band spectra for 54
sources, 25 of which are classified for the first time. The stars in our
sample cover a large range of spectral types (A8-M8). Using a cluster
distance of 780 pc, we determined a median age of 1 Myr for this region
of NGC 2264, with 90% of the stars being 5 Myr or younger. To improve
the statistical significance of our sample, we included 66 additional
cluster members within our field of view with optical spectral
classification in the literature. We derived infrared excesses using
stellar properties to model the photospheric emission for each source
and the extinction to correct FLAMINGOS near-IR and Spitzer mid-IR
photometry, and obtained a disk fraction of 51% ± 5% for the
region. Binning the stars by stellar mass, we find a disk fraction of
38% ± 9% for the 0.1-0.3 solar mass group, 55% ± 6% for
0.3-1 solar masses, and 58% ± 10% for the higher than 1 solar
mass group. The lower disk fraction for the lower mass stars is similar
to the results found in non-cluster regions like Taurus and Chamaeleon,
but differs from the older 3 Myr cluster IC 348 in which the disk
fraction is lower for the higher mass stars. This mass-dependent disk
fraction is accentuated in the sample with isochrone ages younger than 2
Myr. Here, we find that 45% ± 11% of the 0.1-0.3 solar mass stars
have disks, 60% ± 7% of the 0.3-1 solar mass stars have disks,
and all 1-3 solar mass stars have disks. Stellar masses might be an
important factor in the ability of a system to form or retain a disk
early on. However, regardless of the stellar mass, the large infrared
excesses expected from optically thick disks disappear within the first
2 Myr for all stars in our study and small excesses from optically thin
disks are found mostly in sources younger than 4 Myr.
Based on observations obtained at the KPNO.
AB - We have obtained JHK near-IR images and JH band low-resolution spectra
of candidate members of the southern region of the young open cluster
NGC 2264. We have determined spectral types from H-band spectra for 54
sources, 25 of which are classified for the first time. The stars in our
sample cover a large range of spectral types (A8-M8). Using a cluster
distance of 780 pc, we determined a median age of 1 Myr for this region
of NGC 2264, with 90% of the stars being 5 Myr or younger. To improve
the statistical significance of our sample, we included 66 additional
cluster members within our field of view with optical spectral
classification in the literature. We derived infrared excesses using
stellar properties to model the photospheric emission for each source
and the extinction to correct FLAMINGOS near-IR and Spitzer mid-IR
photometry, and obtained a disk fraction of 51% ± 5% for the
region. Binning the stars by stellar mass, we find a disk fraction of
38% ± 9% for the 0.1-0.3 solar mass group, 55% ± 6% for
0.3-1 solar masses, and 58% ± 10% for the higher than 1 solar
mass group. The lower disk fraction for the lower mass stars is similar
to the results found in non-cluster regions like Taurus and Chamaeleon,
but differs from the older 3 Myr cluster IC 348 in which the disk
fraction is lower for the higher mass stars. This mass-dependent disk
fraction is accentuated in the sample with isochrone ages younger than 2
Myr. Here, we find that 45% ± 11% of the 0.1-0.3 solar mass stars
have disks, 60% ± 7% of the 0.3-1 solar mass stars have disks,
and all 1-3 solar mass stars have disks. Stellar masses might be an
important factor in the ability of a system to form or retain a disk
early on. However, regardless of the stellar mass, the large infrared
excesses expected from optically thick disks disappear within the first
2 Myr for all stars in our study and small excesses from optically thin
disks are found mostly in sources younger than 4 Myr.
Based on observations obtained at the KPNO.
KW - circumstellar matter
KW - stars: evolution
U2 - 10.1088/0004-637X/772/2/81
DO - 10.1088/0004-637X/772/2/81
M3 - Article
SN - 0004-637X
VL - 772
SP - 81
JO - Astrophysical Journal
JF - Astrophysical Journal
IS - 2
ER -