Tag Archives: intermediatemass

Intermediate-Mass Black Hole Devours Stars in NGC 6099

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Researchers have identified a newly found intermediate mass black hole designated NGC 6099 HLX-1, situated in a dense star cluster at the edge of the elliptical galaxy NGC 6099, nearly 40,000 light-years from the galaxy’s core.

X-ray and infrared imagery of NGC 6099 HLX-1. Image credits: NASA/CXC/Inst. Astronomy, Taiwan / YC Chang / ESA / STSCI / HST / J. Depasquale.

NGC 6099 is roughly 450 million light-years distant from the constellation Hercules.

Astronomers first detected an unusual X-ray source in a photo of the galaxy captured by NASA’s Chandra X-Ray Observatory in 2009.

This source has since been studied further with ESA’s XMM-Newton Space Observatory.

“X-ray sources exhibiting such high luminosity are uncommon outside a galaxy’s nucleus and can be significant indicators for locating elusive central black holes,” states Dr. Yi-chi Chang, an astronomer at the National Tsing Hua University.

“These objects bridge a critical gap in the understanding of black holes, linking stellar mass black holes and supermassive black holes.”

The X-ray emissions from NGC 6099 HLX-1 reach a temperature of 3 million degrees, which aligns with events of tidal disruption.

Utilizing the NASA/ESA Hubble Space Telescope, astronomers discovered signs of a small cluster of stars encircling the black hole.

This cluster feasts on matter as the stars are densely grouped, just a few months away (approximately 500 billion miles).

The intriguing intermediate mass black hole peaked in brightness in 2012, after which its luminosity steadily decreased until 2023.

However, the optical and X-ray observations across this timeframe do not align, complicating interpretation.

The black hole may have disrupted captured stars, creating a plasma disk that exhibits variability, or it might have birthed a disk that flickers as gas spirals inward.

“If an intermediate mass black hole is consuming a star, how long does it take to digest the gas?” questions Dr. Roberto Soria, an astronomer from the National Institute of Astrophysics in Italy.

“In 2009, HLX-1 was relatively bright. By 2012, it was approximately 100 times brighter, but then its brightness declined again.”

. “Now, we need to observe and see if it enters multiple cycles and identify any peaks in activity.

The researchers stress the importance of examining central mass black holes to reveal the origins of larger supermassive black holes.

Two alternative theories are suggested. One posits that large galaxies grow by merging with other substantial galaxies, positioning intermediate mass black holes as components that help formulate even larger black holes. Intermediate mass black holes in galactic centers also expand during these collisions.

Hubble’s observations indicated a correlation: the larger the galaxy, the larger the black holes residing within. One fresh insight from this discovery suggests that galaxies may host intermediate mass black holes, existing within the halos of galaxies without necessarily spiraling toward the center.

Another theory suggests that gas clouds in primordial dark matter halos might collapse directly into supermassive black holes without first forming stars.

Observations indicating Webb’s distant black holes often appear disproportionately large compared to their host galaxies lend support to this hypothesis.

However, since smaller sizes are elusive, there may exist an observational bias toward detecting very large black holes in the early universe.

In truth, there’s considerable diversity in the methods by which black holes are generated in our dynamic universe.

Ultra-massive black holes collapsing within dark matter may evolve distinctly from those within dwarf galaxies, where accretion could be the primary growth mechanism.

“If fortune favors you, you might spot a wandering black hole suddenly brightening in X-rays due to a tidal disruption event,” Dr. Soria remarked.

“Conducting statistical studies will elucidate the frequency of these intermediate mass black holes, how often they consume stars, and the mechanisms by which galaxies have expanded through the amalgamation of smaller galaxies.”

Survey findings were published in the Astrophysical Journal.

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Yi-chi Chang et al. 2025. Multi-wavelength studies of high-light X-ray sources near NGC6099: A powerful IMBH candidate. APJ 983, 109; doi:10.3847/1538-4357/adbbee

Source: www.sci.news

Astronomers find intermediate-mass black hole in largest globular cluster in Milky Way

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Using more than 500 images from the NASA/ESA Hubble Space Telescope, astronomers have found evidence of a 20,000-solar-mass black hole at the center of Earth. Omega CentauriIt is a globular cluster located in the constellation Centaurus, 5,430 parsecs (17,710 light years) from the Sun.

Omega Centauri is about 10 times more massive than other large globular clusters. Image credit: NASA / ESA / Hubble / Maximilian Häberle, MPIA.

Astronomers know that stellar-mass black holes (black holes with masses between 10 and 100 times that of the Sun) are the remnants of dying stars, and that supermassive black holes, with masses more than a million times that of the Sun, exist at the center of most galaxies.

But the universe is littered with what appear to be more mysterious types of black holes.

These intermediate-mass black holes, with masses between 100 and 10,000 times that of the Sun, are so difficult to measure that their very existence is sometimes debated.

Only a few intermediate-mass black hole candidates have been discovered so far.

Determining the black hole population is an important step towards understanding the formation of supermassive black holes in the early universe.

“Omega Centauri is a special example among globular clusters in the Milky Way,” said astronomer Maximilian Höberle of the Max Planck Institute for Astronomy and his colleagues.

“Omega Centauri is widely accepted to be the stripped core of an accreted dwarf galaxy due to its high mass, complex stellar population and kinematics.”

“These factors, combined with its proximity, make the planet a prime target in the search for intermediate-mass black holes.”

Omega Centauri is made up of about 10 million stars, making it about 10 times more massive than any other large globular cluster.

In the study, the authors measured the velocities of 1.4 million stars from images of the cluster taken by the Hubble Space Telescope.

Although most of these observations were intended for calibration of Hubble's instruments rather than for scientific use, they proved to be an ideal database for the team's research activities.

“We looked for fast-moving stars that are expected to be near concentrated masses such as black holes,” said astronomer Holger Baumgart of the University of Queensland.

“Identifying these stars was the smoking gun we needed to prove the existence of black holes, and we've done just that.”

“We found seven stars that shouldn't be there,” Dr Hebel said.

“They're moving so fast that they're likely to escape the herd and never come back.”

“The most likely explanation is that a very massive object is gravitationally tugging on these stars, keeping them near the center.”

“The only objects this massive are black holes, which have a mass at least 8,200 times that of the Sun.”

“This discovery is the most direct evidence to date for the presence of an intermediate-mass black hole at Omega Centauri,” said Dr Nadine Neumayer, an astronomer at the Max Planck Institute for Astronomy.

“This is extremely exciting because very few other black holes with similar masses are known.”

“The black hole at Omega Centauri may be the best example of an intermediate-mass black hole in our cosmic neighborhood.”

Team paper Published in the journal Nature.

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M. Heberle others2024. Stars moving at high speed around the intermediate-mass black hole at Omega Centauri. Nature 631, 285-288; Source: 10.1038/s41586-024-07511-z

Source: www.sci.news