Inside the Flame Nebula
Stars are often born in clusters, in giant clouds of gas and dust.
Astronomers have studied two star clusters using NASA's Chandra X-ray
Observatory and infrared
telescopes and the results show that the simplest ideas for the birth of these
clusters cannot work, as described in our latest press
release.
This composite image shows one of the clusters, NGC 2024, which is found in
the center of the so-called Flame Nebula about 1,400 light years
from Earth. In this image, X-rays from Chandra are seen as purple,
while infrared data from NASA's Spitzer Space Telescope are colored red, green,
and blue.
A study of NGC 2024 and the Orion Nebula Cluster,
another region where many stars
are forming, suggest that the stars on the outskirts of these clusters are older
than those in the central regions. This is different from what the simplest idea
of star formation predicts, where stars are born first in the center of a
collapsing cloud of gas and dust when the density is large enough.
The research team developed a two-step process to make this discovery. First,
they used Chandra data on the brightness of the stars in X-rays to determine
their masses. Next, they found out how bright these stars were in infrared light
using data from Spitzer, the 2MASS telescope, and the United Kingdom Infrared
Telescope. By combining this information with theoretical models, the ages of
the stars throughout the two clusters could be estimated.
According to the new results, the stars at the center of NGC 2024 were about
200,000 years old while those on the outskirts were about 1.5 million years in
age. In Orion, the age spread went from 1.2 million years in the middle of the
cluster to nearly 2 million years for the stars toward the edges.
Explanations for the new findings can be grouped into three broad categories.
The first is that star formation is continuing to occur in the inner regions.
This could have happened because the gas in the outer regions of a star-forming
cloud is thinner and more diffuse than in the inner regions. Over time, if the
density falls below a threshold value where it can no longer collapse to form
stars, star formation will cease in the outer regions, whereas stars will
continue to form in the inner regions, leading to a concentration of younger
stars there.
Another suggestion is that old stars have had more time to drift away from
the center of the cluster, or be kicked outward by interactions with other
stars. Finally, the observations could be explained if young stars are formed in
massive filaments of gas that fall toward the center of the cluster.
The combination of X-rays from Chandra and infrared data is very powerful for
studying populations of young stars in this way. With telescopes that detect
visible light, many stars are obscured by dust and gas in these star-forming
regions, as shown in this optical
image of the region.
NASA's Marshall Space Flight Center in Huntsville, Ala., manages the Chandra
program for NASA's Science Mission Directorate in Washington. The Smithsonian
Astrophysical Observatory in Cambridge, Mass., controls Chandra's science and
flight operations.
Image credit: X-ray: NASA/CXC/PSU/K.Getman, E.Feigelson, M.Kuhn & the
MYStIX team; Infrared:NASA/JPL-Caltech
NASA
Guillermo Gonzalo Sánchez Achutegui
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