Researchers have found clouds of cold gas embedded deep within larger, superheated gas clouds or Fermi bubbles at the Milky Way's center. The finding challenges current models of Fermi bubble formation and reveals that the bubbles are much younger than previously estimated.
"The Fermi bubbles are enormous structures of hot gas that extend above and below the disk of the Milky Way, reaching about 25,000 light years in each direction from the galaxy's center spanning a total height of 50,000 light years."
"Fermi bubbles are a relatively recent discovery they were first identified by telescopes that 'see' gamma rays in 2010 there are different theories about how it happened, but we do know that it was an extremely sudden and violent event, like a volcanic eruption but on a massive scale."
Bordoloi and the research team used the U.S. National Science Foundation Green Bank Telescope (NSF GBT) to observe the Fermi bubbles and get high-resolution data about the composition of the gas within and the speed at which it is moving. These measurements were twice as sensitive as previous radio telescope surveys of the Fermi bubbles and allowed them to observe finer detail within the bubbles.
Most of the gas inside the Fermi bubbles is about 1 million degrees Kelvin. However, the research team also found something surprising: dense clouds of neutral hydrogen gas, each one measuring several thousand solar masses, dotted within the bubbles 12,000 light years above the center of the Milky Way.
"These clouds of neutral hydrogen are cold, relative to the rest of the Fermi bubble," says Andrew Fox, ESA-AURA Astronomer at the Space Telescope Science Institute and co-author of the paper.
"They're around 10,000 degrees Kelvin, so cooler than their surroundings by at least a factor of 100. Finding those clouds within the Fermi bubble is like finding ice cubes in a volcano."
Their existence is surprising because the hot (more than 1 million degrees Kelvin), high-velocity environment of the nuclear outflow should have rapidly destroyed any cooler gas.
"Computer models of cool gas interacting with hot outflowing gas in extreme environments like the Fermi bubbles show that cool clouds should be rapidly destroyed, usually within a few million years, a timescale that aligns with independent estimates of the Fermi bubbles' age," Bordoloi says. "It wouldn't be possible for the clouds to be present at all if the Fermi bubbles were 10 million years old or older.
"What makes this discovery even more remarkable is its synergy with ultraviolet observations from the Hubble Space Telescope (HST)," Bordoloi says. "The clouds lie along a sightline previously observed with HST, which detected highly ionized multiphase gas, ranging in temperatures from a million to 100,000 Kelvin which is what you'd expect to see if a cold gas is getting evaporated."
The team was also able to calculate the speed at which the gases are moving, which further confirmed the age.
"These gases are moving around a million miles per hour, which also marks the Fermi bubbles as a recent development," Bordoloi says. "These clouds weren't here when dinosaurs roamed Earth. In cosmic time scales, a million years is the blink of an eye."
"We believe that these cold clouds were swept up from the Milky Way's center and carried aloft by the very hot wind that formed the Fermi bubbles," says Jay Lockman, an astronomer at the Green Bank Observatory and co-author of the paper. "Just as you can't see the motion of the wind on Earth unless there are clouds to track it, we can't see the hot wind from the Milky Way but can detect radio emission from the cold clouds it carries along."
This discovery challenges current understanding of how cold clouds can survive the extreme energetic environment of the Galactic Center, placing strong empirical constraints on how outflows interact with their surroundings. The findings provide a crucial benchmark for simulations of galactic feedback and evolution, reshaping our view of how energy and matter cycle through galaxies.
Website: International Research Awards on High Energy Physics and Computational Science.
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