The Circinus Galaxy, a galaxy about 13 million light-years away, contains an active supermassive black hole that continues to influence its evolution. The largest source of infrared light from the region closest to the black hole itself was thought to be outflows, or streams of superheated matter that fire outward.
Image: Circinus Galaxy (Hubble and Webb)
This image from NASA’s Hubble Space Telescope shows
the Circinus galaxy. A close-up of its core from NASA’s James Webb Space
Telescope shows the inner face of the hole of the donut-shaped disk of gas disk
glowing in infrared light. The outer ring appears as dark spots.
Image: NASA, ESA, CSA, Enrique Lopez-Rodriguez
(University of South Carolina), Deepashri Thatte (STScI); Image Processing:
Alyssa Pagan (STScI); Acknowledgment: NSF's NOIRLab, CTIO
Now, new observations by NASA’s
James Webb Space Telescope, seen here with a new image from NASA’s Hubble Space
Telescope, provide evidence that reverses this thinking, suggesting that most
of the hot, dusty material is actually feeding the central black hole. The
technique used to gather this data also has the potential to analyze the
outflow and accretion components for other nearby black holes.
The research, which includes the
sharpest image of a black hole’s surroundings ever taken by Webb, published Tuesday in Nature.
Outflow question
Supermassive black holes like those
in Circinus remain active by consuming surrounding matter. Infalling gas and
dust accumulates into a donut-shaped ring around the black hole, known as a
torus. As supermassive black holes gather matter from the torus’ inner walls,
they form an accretion disk, similar to a whirlpool of water swirling around a
drain. This disk grows hotter through friction, eventually becoming hot enough
to emit light.
This glowing matter can become so
bright that resolving details within the galaxy’s center with ground-based
telescopes is difficult. It’s made even harder due to the bright, concealing
starlight within Circinus. Further, since the torus is incredibly dense, the
inner region of the infalling material, heated by the black hole, is obscured
from our point of view. For decades, astronomers contended with these
difficulties, designing and improving models of Circinus with as much data as
they could gather.
Image: Circinus Galaxy Center
(Artist's Concept)
This artist’s concept depicts the central engine of
the Circinus galaxy, visualizing the supermassive black hole fed by a thick,
dusty torus that glows in infrared light.
Artwork: NASA, ESA, CSA, Ralf Crawford (STScI)
“In order to study the supermassive
black hole, despite being unable to resolve it, they had to obtain the total
intensity of the inner region of the galaxy over a large wavelength range and
then feed that data into models,” said lead author Enrique Lopez-Rodriguez of
the University of South Carolina.
Early models would fit the spectra
from specific regions, such as the emissions from the torus, those of the
accretion disk closest to the black hole, or those from the outflows, each
detected at certain wavelengths of light. However, since the region could not
be resolved in its entirety, these models left questions at several
wavelengths. For example, some telescopes could detect an excess of infrared
light, but lacked the resolution to determine where exactly it was coming from.
“Since the ‘90s, it has not been
possible to explain excess infrared emissions that come from hot dust at the
cores of active galaxies, meaning the models only take into account either the
torus or the outflows, but cannot explain that excess,” said Lopez-Rodriguez.
Such models found that most of the
emission (and, therefore, mass) close to the center came from outflows. To test
this theory, then, astronomers needed two things: the ability to filter the
starlight that previously prevented a deeper analysis, and the ability to
distinguish the infrared emissions of the torus from those of the outflows.
Webb, sensitive and technologically sophisticated enough to meet both
challenges, was necessary to advance our understanding.
Webb’s innovative technique
To look into the center of
Circinus, Webb needed the Aperture Masking Interferometer tool on its NIRISS
(Near-Infrared Imager and Slitless Spectrograph) instrument.
On Earth, interferometers usually
take the form of telescope arrays: mirrors or antennae that work together as if
they were a single telescope. An interferometer does this by gathering and
combining the light from whichever source it is pointed toward, causing the
electromagnetic waves that make up light to “interfere” with each other (hence,
“interfere-ometer”) and creating interference patterns. These patterns can be
analyzed by astronomers to reconstruct the size, shape, and features of distant
objects with much greater detail than non-interferometric techniques.
The Aperture Masking Interferometer
allows Webb to become an array of smaller telescopes working together as an
interferometer, creating these interference patterns by itself. It does this by
utilizing a special aperture made of seven small, hexagonal holes, which, like
in photography, controls the amount and direction of light that enters the
telescope’s detectors.
“These holes in the mask are
transformed into small collectors of light that guide the light toward the
detector of the camera and create an interference pattern,” said Joel
Sanchez-Bermudez, co-author based at the National University of Mexico.
With new data in hand, the research
team was able to construct an image from the central region's interference
patterns. To do so, they referenced data from previous observations to ensure
their data from Webb was free of any artifacts. This resulted in the first
extragalactic observation from an infrared interferometer in space.
"By using an advanced imaging
mode of the camera, we can effectively double its resolution over a smaller
area of the sky," Sanchez-Bermudez said. "This allows us to see
images twice as sharp. Instead of Webb’s 6.5-meter diameter, it’s like we are
observing this region with a 13-meter space telescope."
The data showed that contrary to
the models predicting that the infrared excess comes from the outflows, around
87% of the infrared emissions from hot dust in Circinus come from the areas
closest to the black hole, while less than 1% of emissions come from hot dusty
outflows. The remaining 12% comes from distances farther away that could not
previously be told apart.
“It is the first time a
high-contrast mode of Webb has been used to look at an extragalactic source,”
said Julien Girard, paper co-author and senior research scientist at the Space
Telescope Science Institute. “We hope our work inspires other astronomers to
use the Aperture Masking Interferometer mode to study faint, but relatively
small, dusty structures in the vicinity of any bright object.”
Video:
Circinus Galaxy Zoom
This zoom-in video shows the location of the Circinus
galaxy on the sky. It begins with a ground-based photo of the constellation
Circinus by the late astrophotographer Akira Fujii. The video closes in on the
Circinus galaxy, using views from the Digitized Sky Survey and the Dark...
Video: NASA, ESA, CSA, Alyssa Pagan (STScI);
Acknowledgment: CTIO, NSF's NOIRLab, DSS, Akira Fujii
Universe of black holes
While the mystery of Circinus’
excess emissions has been solved, there are billions of black holes in our
universe. Those of different luminosities, the team notes, may have an
influence on whether most of the emissions come from a black hole’s torus or their
outflows.
“The intrinsic brightness of
Circinus’ accretion disk is very moderate,” Lopez-Rodriguez said. “So it makes
sense that the emissions are dominated by the torus. But maybe, for brighter
black holes, the emissions are dominated by the outflow.”
With this research, astronomers now
have a tested technique to investigate whichever black holes they want, so long
as they are bright enough for the Aperture Masking Interferometer to be useful.
Studying additional targets will be essential to building a catalog of emission
data to figure out if Circinus’ results were unique or characteristic of a
pattern.
“We need a statistical sample of
black holes, perhaps a dozen or two dozen, to understand how mass in their
accretion disks and their outflows relate to their power,” Lopez-Rodriguez
said.
The James Webb Space Telescope is
the world’s premier space science observatory. Webb is solving mysteries in our
solar system, looking beyond to distant worlds around other stars, and probing
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).
To learn more about Webb, visit: https://science.nasa.gov/webb
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Source: NASA’s Webb Delivers Unprecedented Look Into Heart of Circinus Galaxy - NASA Science
