Astronomers have found cosmic clumps so dark, dense and dusty that they throw the deepest shadows ever recorded.
Image credit: NASA /JPL-Caltech /University of Zurich
The clumps were discovered within a huge cosmic cloud of gas and dust. Infrared observations from NASA's Spitzer Space Telescope of these blackest-of-black regions in the cloud paradoxically light the way to understanding how the brightest stars form.
The large cloud looms in the center of this image of the galactic plane from Spitzer. The zoom oval to the right shows details of the cloud, revealing the dense clumps.
A new study takes advantage of the shadows cast by these dark clumps to measure the cloud's overall structure and mass.
These dense, clumpy pockets of star-forming material within the cloud are so thick with dust that they scatter and block not only visible light, but almost all background infrared light as well.
"The map of the structure of the cloud and its dense cores we have made in this study reveals a lot of fine details about the massive star and star cluster formation process," said Michael Butler, a postdoctoral researcher at the University of Zurich in Switzerland and lead author of the study, published in The Astrophysical Journal Letters.
The dusty cloud, the results suggest, will likely evolve into one of the most massive young clusters of stars in our galaxy.
The densest clumps will blossom into the cluster's biggest, most powerful stars, called O-type stars, the formation of which has long puzzled scientists.
These hulking stars have major impacts on their local stellar environments while also helping to create the heavy elements needed for life.
The blue callout image reveals the overall darkness of the cloud, calculated using Spitzer’s infrared observations at a wavelength of 8 microns. Artifacts left by individual stars have been removed from the data.
The background image combines data from Spitzer surveys. Blue represents 3.6-micron light and green shows light of 8 microns, both captured by Spitzer's infrared array camera.
Red is 24-micron light detected by Spitzer's Multiband Imaging Photometer (MIPS). The red spot in the center of the zoom oval, unrelated to the new study's findings, is a young star whose radiating heat has lit up a surrounding cocoon of dust.
Read more on this story here
Image credit: NASA /JPL-Caltech /University of Zurich
The clumps were discovered within a huge cosmic cloud of gas and dust. Infrared observations from NASA's Spitzer Space Telescope of these blackest-of-black regions in the cloud paradoxically light the way to understanding how the brightest stars form.
The large cloud looms in the center of this image of the galactic plane from Spitzer. The zoom oval to the right shows details of the cloud, revealing the dense clumps.
A new study takes advantage of the shadows cast by these dark clumps to measure the cloud's overall structure and mass.
These dense, clumpy pockets of star-forming material within the cloud are so thick with dust that they scatter and block not only visible light, but almost all background infrared light as well.
"The map of the structure of the cloud and its dense cores we have made in this study reveals a lot of fine details about the massive star and star cluster formation process," said Michael Butler, a postdoctoral researcher at the University of Zurich in Switzerland and lead author of the study, published in The Astrophysical Journal Letters.
The dusty cloud, the results suggest, will likely evolve into one of the most massive young clusters of stars in our galaxy.
The densest clumps will blossom into the cluster's biggest, most powerful stars, called O-type stars, the formation of which has long puzzled scientists.
These hulking stars have major impacts on their local stellar environments while also helping to create the heavy elements needed for life.
The blue callout image reveals the overall darkness of the cloud, calculated using Spitzer’s infrared observations at a wavelength of 8 microns. Artifacts left by individual stars have been removed from the data.
The background image combines data from Spitzer surveys. Blue represents 3.6-micron light and green shows light of 8 microns, both captured by Spitzer's infrared array camera.
Red is 24-micron light detected by Spitzer's Multiband Imaging Photometer (MIPS). The red spot in the center of the zoom oval, unrelated to the new study's findings, is a young star whose radiating heat has lit up a surrounding cocoon of dust.
Read more on this story here
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