Take a close look at the photo above — you just might be witnessing the birth of star. It’s a rare image that depicts the center of our galaxy, the Milky Way, and it was captured by the Atacama Pathfinder Experiment (APEX) telescope in Chile. This photo, along with a swath of others released today, complete a special survey of Earth’s southern skies by providing the broadest map to date of the coldest parts of our galaxy, where stars are born.
“The important part of the survey is that you get a new roadmap. With it, we can find all of the raw material for star formation in our Milky Way that was previously hidden from view,” said Friedrich Wyrowski, an astronomer and APEX scientist at the Max Planck Institute for Radio Astronomy in Bonn, Germany. “All of these measurements have been done in many external galaxies where we have a global view, but it’s much more difficult in our own galaxy.”
To chart this roadmap, APEX sits among the skies — 16,700 feet above sea level on Chile’s Chajnantor Plateau. There, its 39-foot dish peers into the universe and measures light radiation. Visible light has short wavelengths (400–700 nanometers). Radio waves are the opposite, with wavelengths stretching as far as millions of meters. For this survey, the APEX telescope wanted to capture light wavelengths somewhere in the middle — in the submillimeter range.
The Atacama Pathfinder Experiment (APEX) telescope is one of the tools used by European Southern Observatory to peer beyond the realm of visible light. Clusters of white penitentes — thin spikes of hardened snow or ice — can be seen in the foreground. Photo by ESO Photo Ambassador Babak Tafreshi
Aerial view of the APEX telescope on the Chajnantor Plateau in Chile’s Atacama region. Photo by Clémentine Bacri and Adrien Normier/ORA Wings for Science/ESO
The LABOCA Camera installed on the APEX telescope. LABOCA is a ‘thermometer camera’ with 295 detectors and wide field of view to measure the cold universe. Photo by European Southern Observatory
“Water vapor in our atmosphere absorbs much of the radiation from the cold dust that we want to detect. Building a telescope at a high altitude and in one of the driest places on Earth in Chile gets rid of most of this interfering water vapor,” Wyrowski said.
The result is the ATLASGAL survey, a collaborative mission between the Max Planck Institute for Radio Astronomy, the Max Planck Institute for Astronomy, European Southern Observatory, and the University of Chile. Over the last nine years, this project has aimed to complete our picture of the Milky Way, which could only be done from the Southern hemisphere.
“As soon as you go to the Southern hemisphere to a location like Chile with APEX, you get access to the whole Milky Way,” Wyrowski said. “For example, the center of our Milky Way is on the southern part of the Earth’s sky. Here in the North, it isn’t very visible above the horizon.”
ATLASGAL’s map of cold dust can now be combined with infrared readings, such as as those from NASA’s Spitzer Space Telescope, to fill in the early picture of star formation. As cold dust packs tighter and warms up, it begins emitting infrared rays, before ultimately exploding into a visible star.
“Only at submillimeter wavelengths are we able to penetrate through all the dust to see these coldest parts of the star-forming regions. That allows us to find the most massive clumps, which will lead to the formation of very luminous stars,” Wyrowski said.
The most luminous stars form rapidly in the coldest parts of the Milky Way, and they dictate the appearance and shape of our galaxy, because they have very strong outflows and winds that push around interstellar material. Ultimately, these stars will die as a supernova, again injecting lots of energy into the interstellar medium, forcing another batch of cold dust into a corner and sparking a star.
“To find all of these birthplaces for massive stars will help us understand how our Milky Way will evolve,” Wyrowski said.
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