Astronomers looking into the early universe have made a surprising discovery using NASA’s James Webb Space Telescope: a cluster of massive galaxies in the process of forming around an extremely red quasar. The result will expand our understanding of how galaxy clusters in the early universe came together and formed the cosmic web we see today.
A quasar, a special type of active
galactic nucleus (AGN),
is a compact region with a supermassive black hole at the center of a galaxy.
Gas falling into a supermassive black hole makes the quasar bright enough to
outshine all the galaxy’s stars.
The quasar Webb explored, called SDSS
J165202.64+172852.3, existed 11.5 billion years ago. It is unusually red not
just because of its intrinsic red color, but also because the galaxy’s light
has been redshifted by its vast distance. That made Webb, having unparalleled
sensitivity in infrared wavelengths, perfectly suited to examine the galaxy in
detail.
At left, the quasar SDSS J165202.64+172852.3 is highlighted in a Hubble
Space Telescope image taken in visible and near-infrared light. The images on
the right and at bottom present new observations from the James Webb Space Telescope
in multiple wavelengths. They demonstrate the distribution and motions of gas
within a newly observed galaxy cluster around the central quasar. Credits:
NASA, ESA, CSA, STScI, D. Wylezalek (Heidelberg Univ.), A. Vayner and N.
Zakamska (Johns Hopkins Univ.) and the Q-3D Team
This quasar is one of the most powerful known galactic nuclei that’s been
seen at such an extreme distance. Astronomers had speculated that the quasar’s
extreme emission could cause a “galactic wind,” pushing free gas out of its
host galaxy and possibly greatly influencing future star formation there.
To investigate the movement of the gas, dust and stellar material in the
galaxy, the team used the telescope’s Near Infrared
Spectrograph (NIRSpec). This powerful instrument
uses a technique called spectroscopy to look at the movement of various outflows and winds surrounding the
quasar. NIRSpec can simultaneously gather spectra across the telescope’s whole
field of view, instead of just from one point at a time, enabling Webb to
simultaneously examine the quasar, its galaxy and the wider surroundings.
Previous studies by NASA’s Hubble Space Telescope and other observatories
called attention to the quasar’s powerful outflows, and astronomers had
speculated that its host galaxy could be merging with some unseen partner. But
the team was not expecting Webb’s NIRSpec data to clearly indicate it was not
just one galaxy, but at least three more swirling around it. Thanks to spectra
over a broad area, the motions of all this surrounding material could be
mapped, resulting in the conclusion that the red quasar was in fact part of a
dense knot of galaxy formation.
“There are few galaxy protoclusters known at this early time. It’s hard to
find them, and very few have had time to form since the big bang,” said
astronomer Dominika Wylezalek of Heidelberg University in Germany, who led the
study with Webb. “This may eventually help us understand how galaxies in dense
environments evolve. It’s an exciting result.”
Using the observations from NIRSpec, the team was able to confirm three
galactic companions to this quasar and show how they are connected. Archival
data from Hubble hint that there may be even more. Images from Hubble’s Wide
Field Camera 3 had shown extended material surrounding the quasar and its
galaxy, prompting its selection for this study into its outflow and the effects
on its host galaxy. Now, the team suspects they could have been looking at the
core of a whole cluster of galaxies – only now revealed by Webb’s crisp
imaging.
"Our first look at the data quickly revealed clear signs of major
interactions between the neighboring galaxies,” shared team member Andrey
Vayner of Johns Hopkins University in Baltimore, Maryland. “The sensitivity of
the NIRSpec instrument was immediately apparent, and it was clear to me that we
are in a new era of infrared spectroscopy."
The three confirmed galaxies are orbiting each other at incredibly high
speeds, an indication that a great deal of mass is present. When combined with
how closely they are packed into the region around this quasar, the team
believes this marks one of the densest known areas of galaxy formation in the
early universe. “Even a dense knot of dark matter isn’t sufficient to explain
it,” Wylezalek says. “We think we could be seeing a region where two massive
halos of dark matter are merging together.” Dark matter is an invisible
component of the universe that holds galaxies and galaxy clusters together, and
is thought to form a “halo” that extends beyond the stars in these structures.
The study conducted by Wylezalek’s team is part of Webb’s investigations
into the early universe. With its unprecedented ability to look back in time,
the telescope is already being used to investigate how the first galaxies were
formed and evolved, and how black holes formed and influenced the structure of
the universe. The team is planning follow-up observations into this unexpected
galaxy proto-cluster, and hope to use it to understand how dense, chaotic
galaxy clusters like this one form, and how it’s affected by the active,
supermassive black hole at its heart.
These results will be published in the The Astrophysical Journal
Letters. This research was completed as part of Webb’s Early Release
Science program #1335.
The James Webb Space Telescope is the world's premier space science observatory. Webb will solve mysteries in our solar system, look beyond to distant worlds around other stars, and probe the mysterious structures and origins of our universe and our place in it. Webb is an international program led by NASA with its partners, ESA (European Space Agency) and CSA (Canadian Space Agency).
Source: NASA’s Webb Uncovers Dense Cosmic Knot in The Early Universe | NASA
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