The universe is filled with a dark matter web — a vast 3-D structure that the majority of galaxies and clusters of galaxies are threaded along. Although we cannot directly see dark matter (as it does not interact with light), we can see its gravitational influence on space-time and we now know this invisible mass accounts for nearly 85 percent of all matter in the cosmos.
Understanding how this dark matter web influenced the earliest galaxies to form after the Big Bang is critical for us to better appreciate the structure and evolution of the modern universe, so the discovery of a cluster of massive starburst galaxies (i.e. galaxies frantically forming new stars) embedded in a junction of dark matter lanes, some 11.5 billion years ago, could help us understand why none of these monstrous early galaxies exist in the modern universe and how massive elliptical galaxies came to be.
Until now, observing the earliest galaxies has been a problem. Typically, these starburst galaxies that existed in the earliest epochs of our universe are hard to observe as they contain huge quantities of obscuring dust. Radio telescopes find it hard to accurately pin down these galaxies’ locations. But these galaxies are known to generate a high flux of submillimeter emissions, a frequency band ALMA is highly sensitive to.
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| On the left is the image taken at sub-millimeter wavelengths with the Atacama Submillimeter Telescope Experiment (ASTE). It looks like there is one bright monstrous galaxy. In the center is an image taken at the same sub-millimeter wavelengths, but this time using ALMA. With 60 times better resolution and 10 times better sensitivity, we can see that actually there are 3 monstrous galaxies close together. On the right is the same region photographed in visible light by the Subaru Telescope. We can see that not all of the monstrous galaxies show up in this picture, or at the least that some of them must be very faint. |
Read more at Discovery News
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