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Tag Archives: Holes
Holes exposed in Ukraine air defence, as Lavrov slams NATO – Euronews
- Holes exposed in Ukraine air defence, as Lavrov slams NATO Euronews
- Ukrainian special ops forces who stormed a Russian trench in an intense video did ‘everything right’ and took their enemy by surprise, US infantry veteran says Yahoo Sports
- Azerbaijani Defense Ministry Says Its Positions Came Under Small Arms Fire In Border Area Radio Free Europe / Radio Liberty
- Ukrainian artillerymen praise US howitzers outside Russian-held town Reuters
- ISW explains how Ukrainian forces could use delayed counteroffensive Yahoo News
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Depleted-uranium rounds could put holes in Russian tanks, wreak havoc inside – Business Insider
- Depleted-uranium rounds could put holes in Russian tanks, wreak havoc inside Business Insider
- US Announces $325M Weapons Package For Ukraine As Counteroffensive Gets Underway News On 6/KOTV
- The US will send depleted uranium munitions to Ukraine – a health physicist explains their military, health and environmental effects The Conversation Indonesia
- US releases further $205 million in Ukraine aid FRANCE 24 English
- NATO Meeting Fails To Approve First Defense Plans Since Cold War Radio Free Europe / Radio Liberty
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Unprecedented Image of Black Hole’s Powerful Jet and Shadow Captured by Astronomers – SciTechDaily
- Unprecedented Image of Black Hole’s Powerful Jet and Shadow Captured by Astronomers SciTechDaily
- Light flare brighter than a trillion suns points to a binary black hole system Interesting Engineering
- Flare of light brighter than a trillion suns reveals location of rare double black hole galaxy Livescience.com
- Flash of Light Brighter Than a Trillion Stars Leads to Supermassive Black Hole Breakthrough SciTechDaily
- First Observations Of Secondary Supermassive Black Hole Within Famous Double-Hole Quasar IFLScience
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Stephen Hawking’s famous theory of how black holes die could mean our entire universe is doomed to evaporate, a new study found – Yahoo! Voices
- Stephen Hawking’s famous theory of how black holes die could mean our entire universe is doomed to evaporate, a new study found Yahoo! Voices
- Everything in the Universe Is Doomed To Evaporate – Hawking’s Radiation Theory Isn’t Limited to Black Holes SciTechDaily
- The universe is evaporating right in front of our eyes, finds major new study indy100
- Stephen Hawking’s most famous prediction could mean that everything in the universe is doomed to evaporate, new study says Yahoo Life
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Stephen Hawking’s famous theory of how black holes die could mean our entire universe is doomed to evaporate, a new study found – Yahoo! Voices
- Stephen Hawking’s famous theory of how black holes die could mean our entire universe is doomed to evaporate, a new study found Yahoo! Voices
- Stephen Hawking’s most famous prediction could mean that everything in the universe is doomed to evaporate, new study says Livescience.com
- Everything in the Universe Is Doomed To Evaporate – Hawking’s Radiation Theory Isn’t Limited to Black Holes SciTechDaily
- The universe is evaporating right in front of our eyes, finds major new study indy100
- Hawking was right: All large objects will eventually evaporate Interesting Engineering
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Black Hole’s Deep Gravitational Sinkhole Twists Unlucky Star Into Donut Shape
This animation depicts a star experiencing spaghettification as it’s sucked in by a supermassive black hole during a ‘tidal disruption event’. Credit: ESO/M. Kornmesser
A Deep Gravitational Sinkhole Swallows Unlucky Bypassing Star
Black holes have such a voracious gravitational pull that they even swallow light. This makes them hungry monsters lurking in the eternal darkness. There’s no escape if you happen to stumble across one in the inky blackness of space. That’s no worry for astronauts who have yet to travel farther than the Moon. But entire stars can face that peril if they wind up in the wrong place at the wrong time.
Hubble astronomers got a front-row seat to such an interstellar demolition derby when they were alerted to a flash of high-energy radiation from the core of a galaxy 300 million light-years away. Like a police officer arriving quickly at the scene of an accident, Hubble vision was trained on the mayhem before the collision was over. Hubble is too far away to see the doomed star getting sucked in. Instead, Hubble astronomers took the fingerprints of starlight coming from the mishap. These spectra tell a forensic story of a star falling into a cosmic blender. It was shredded, and pulled toward the black hole like a piece of stretched taffy. This process formed a donut-shaped ring of gas around the
This sequence of artist’s illustrations shows how a black hole can devour a bypassing star.
1. A normal star passes near a supermassive black hole in the center of a galaxy.
2. The star’s outer gasses are pulled into the black hole’s gravitational field.
3. The star is shredded as tidal forces pull it apart.
4. The stellar remnants are pulled into a donut-shaped ring around the black hole, and will eventually fall into the black hole, unleashing a tremendous amount of light and high-energy radiation.
Credit: NASA, ESA, Leah Hustak (STScI)
Hubble Finds Hungry Black Hole Twisting Captured Star Into Donut Shape
Black holes are gatherers, not hunters. They lie in wait until a hapless star wanders by. When the star gets close enough, the black hole’s gravitational grasp violently rips it apart and sloppily devours its gasses while belching out intense radiation.
Astronomers using
These are termed “tidal disruption events.” But the wording belies the complex, raw violence of a black hole encounter. There is a balance between the black hole’s gravity pulling in star stuff, and radiation blowing material out. In other words, black holes are messy eaters. Astronomers are using Hubble to find out the details of what happens when a wayward star plunges into the gravitational abyss.
Hubble can’t photograph the AT2022dsb tidal event’s mayhem up close, since the munched-up star is nearly 300 million light-years away at the core of the galaxy 
Astronomers using NASA’s Hubble Space Telescope have recorded a star’s final moments in detail as it gets gobbled up by a black hole. Credit: NASA’s Goddard Space Flight Center, Lead Producer: Paul Morris
About 100 tidal disruption events around black holes have been detected by astronomers using various telescopes. NASA recently reported that several of its high-energy space observatories spotted another black hole tidal disruption event on March 1, 2021, and it happened in another galaxy. Unlike Hubble observations, data was collected in X-ray light from an extremely hot corona around the black hole that formed after the star was already torn apart.
“However, there are still very few tidal events that are observed in ultraviolet light given the observing time. This is really unfortunate because there’s a lot of information that you can get from the ultraviolet spectra,” said Emily Engelthaler of the Center for Astrophysics | Harvard & Smithsonian (
The Hubble spectroscopic data are interpreted as coming from a very bright, hot, donut-shaped area of gas that was once the star. This area, known as a torus, is the size of the solar system and is swirling around a black hole in the middle.
“We’re looking somewhere on the edge of that donut. We’re seeing a stellar wind from the black hole sweeping over the surface that’s being projected towards us at speeds of 20 million miles per hour (three percent the speed of light),” said Maksym. “We really are still getting our heads around the event. You shred the star and then it’s got this material that’s making its way into the black hole. And so you’ve got models where you think you know what is going on, and then you’ve got what you actually see. This is an exciting place for scientists to be: right at the interface of the known and the unknown.”
The results were reported during a press conference on January 12, 2022, at the 241st meeting of the American Astronomical Society in Seattle, Washington.
The Hubble Space Telescope is a project of international cooperation between NASA and ESA. NASA’s Goddard Space Flight Center in Greenbelt, Maryland, manages the telescope. The Space Telescope Science Institute (STScI) in Baltimore, Maryland, conducts Hubble and Webb science operations. STScI is operated for NASA by the Association of Universities for Research in Astronomy, in Washington, D.C.
Scientists Have Discovered a Monstrous Pair of Supermassive Black Holes That Are Destined to Collide
Scientists have discovered a pair of supermassive black holes that are doomed to merge into one enormous singularity. The findings could help astronomers understand what will happen when our own Milky Way merges with the Andromeda galaxy in 4.5 billion years.
Supermassive black holes are thought to lurk in the heart of every major galaxy, growing larger as they draw in and devour enormous quantities of dust, gas, and stars from the surrounding space environment. When wandering galaxies collide with one another, the monstrous singularities at their cores are also thrown into closer proximity.
The newly discovered black holes were found by scientists observing the aftermath of one such galactic merger that is taking place some 480 million light-years from Earth in the constellation Cancer.
The energetic pair were spotted feeding on the maelstrom of material disturbed by the cosmic crash, and represent the closest black holes ever discovered by humanity that are locked in the act of merging.
Scientists used the Atacama Large Millimeter/Submillimeter Array (ALMA), to peer through the bright, dusty space environment at the heart of the merger in order to identify the black holes. The chaotic duo – known collectively as UGC4211 – were then targeted by a collection of seven powerful observatories, including the orbital Hubble Space Telescope.
Data from these observations revealed that the black holes had masses of 125 and 200 million times the mass of our Sun, according to a release from the Simons Foundation in New York. These celestial heavyweights are separated by a distance of just 750 light-years, and will likely merge in a few hundred million years.
The scientists behind the paper detailing the discovery – which was published in The Astrophysical Journal Letters – used the data to estimate the amount of supermassive black holes that could be merging throughout the universe. The team estimated that a surprisingly high population likely exists, and that the extreme forces at play during the mergers are likely creating a background chorus of powerful gravitational waves.
Gravitational waves are effectively ripples in spacetime that can be created by the movements of massive bodies such as merging black holes. As a gravitational wave sweeps outward from its source, it squeezes and stretches all matter in its path, creating a disturbance that is measurable on Earth using cutting-edge laser-based instruments.
“There might be many pairs of growing supermassive black holes in the centres of galaxies that we have not been able to identify so far,” said Ezequiel Treister, an astronomer at the Universidad Católica de Chile and co-author of the new paper in a new statement. “If this is the case, in the near future we will be observing frequent gravitational wave events caused by the mergers of these objects across the Universe.”
The discovery will also allow scientists to better understand what will happen to the Milky Way in the distant future. Billions of years from now our galaxy will merge with its larger spiral neighbour – the Andromeda galaxy.
“The Milky Way-Andromeda collision is in its very early stages and is predicted to occur in about 4.5 billion years,” commented senior research scientist at Eureka Scientific, and lead author of the new study, Michael Koss, in the release from the National Radio Astronomy Observatory website.
“What we’ve just studied is a source in the very final stage of collision, so what we’re seeing presages that merger and also gives us insight into the connection between black holes merging and growing and eventually producing gravitational waves.”
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Image Credit: ALMA (ESO/NAOJ/NRAO); M. Weiss, NRAO/AUI/NSF
Two supermassive black holes, very close together, found by astronomers
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Two supermassive black holes have been spotted feasting on cosmic materials as two galaxies in distant space merge — and are the closest to colliding black holes astronomers have ever observed.
Astronomers spotted the pair while using the Atacama Large Millimeter/Submillimeter Array of telescopes, or ALMA, in northern Chile’s Atacama Desert, to observe two merging galaxies about 500 million light-years from Earth.
The two black holes were growing in tandem near the center of the coalescing galaxy resulting from the merger. They met when their host galaxies, known as UGC 4211, collided.
One is 200 million times the mass of our sun, while the other is 125 million times the mass of our sun.
While the black holes themselves aren’t directly visible, both were surrounded by bright clusters of stars and warm, glowing gas — all of which is being tugged by the holes’ gravitational pull.
Over time, they will start circling one another in orbit, eventually crashing into one another and creating one black hole.
After observing them across multiple wavelengths of light, the black holes are located the closest together scientists have ever seen — only about 750 light-years apart, which is relatively close, astronomically speaking.
The results were shared at the 241st meeting of the American Astronomical Society being held this week in Seattle, and published Monday in The Astrophysical Journal Letters.
The distance between the black holes “is fairly close to the limit of what we can detect, which is why this is so exciting,” said study coauthor Chiara Mingarelli, an associate research scientist at the Flatiron Institute’s Center for Computational Astrophysics in New York City, in a statement.
Galactic mergers are more common in the distant universe, which makes them harder to see using Earth-based telescopes. But ALMA’s sensitivity was able to observe even their active galactic nuclei — the bright, compact regions in galaxies where matter swirls around black holes. Astronomers were surprised to find a binary pair of black holes, rather than a single black hole, dining on the gas and dust stirred up by the galactic merger.
“Our study has identified one of the closest pairs of black holes in a galaxy merger, and because we know that galaxy mergers are much more common in the distant Universe, these black hole binaries too may be much more common than previously thought,” said lead study author Michael Koss, a senior research scientist at the Eureka Scientific research institute in Oakland, California, in a statement.
“What we’ve just studied is a source in the very final stage of collision, so what we’re seeing presages that merger and also gives us insight into the connection between black holes merging and growing and eventually producing gravitational waves,” Koss said.
If pairs of black holes — as well as merging galaxies that lead to their creation — are more common in the universe than previously thought, they could have implications for future gravitational wave research. Gravitational waves, or ripples in space time, are created when black holes collide.
It will still take a few hundred million years for this particular pair of black holes to collide, but the insights gained from this observation could help scientists better estimate how many pairs of black holes are close to colliding in the universe.
“There might be many pairs of growing supermassive black holes in the centers of galaxies that we have not been able to identify so far,” said study coauthor Ezequiel Treister, an astronomer at Universidad Católica de Chile in Santiago, Chile, in a statement. “If this is the case, in the near future we will be observing frequent gravitational wave events caused by the mergers of these objects across the Universe.”
Space-based telescopes like Hubble and the Chandra X-ray Observatory and ground-based telescopes like the European Southern Observatory’s Very Large Telescope, also in the Atacama Desert, and the W.M. Keck telescope in Hawaii have also observed UGC 4211 across different wavelengths of light to provide a more detailed overview and differentiate between the two black holes.
“Each wavelength tells a different part of the story,” Treister said. “All of these data together have given us a clearer picture of how galaxies such as our own turned out to be the way they are, and what they will become in the future.”
Understanding more about the end stages of galaxy mergers could provide more insight about what will happen when our Milky Way galaxy collides with the Andromeda galaxy in about 4.5 billion years.
Scientists find pair of black holes dining together in nearby galaxy merger
While studying a nearby pair of merging galaxies using the Atacama Large Millimeter/submillimeter Array (ALMA)—an international observatory co-operated by the U.S. National Science Foundation’s National Radio Astronomy Observatory (NRAO)—scientists discovered two supermassive black holes growing simultaneously near the center of the newly coalescing galaxy.
These super-hungry giants are the closest together that scientists have ever observed in multiple wavelengths. What’s more, the new research reveals that binary black holes and the galaxy mergers that create them may be surprisingly commonplace in the universe.
The results of the new research were published today in The Astrophysical Journal Letters, and presented in a press conference at the 241st meeting of the American Astronomical Society (AAS) in Seattle, Washington.
At just 500 million light-years away from Earth in the constellation Cancer, UGC4211 is an ideal candidate for studying the end stages of galaxy mergers, which occur more frequently in the distant universe, and as a result, can be difficult to observe. When scientists used the highly sensitive 1.3mm receivers at ALMA to look deep into the merger’s active galactic nuclei—compact, highly luminous areas in galaxies caused by the accretion of matter around central black holes—they found not one, but two black holes gluttonously devouring the byproducts of the merger. Surprisingly, they were dining side-by-side with just 750 light-years between them.
“Simulations suggested that most of the population of black hole binaries in nearby galaxies would be inactive because they are more common, not two growing black holes like we found,” said Michael Koss, a senior research scientist at Eureka Scientific and the lead author of the new research.
Koss added that the use of ALMA was a game-changer, and that finding two black holes so close together in the nearby universe could pave the way for additional studies of the exciting phenomenon. “ALMA is unique in that it can see through large columns of gas and dust and achieve very high spatial resolution to see things very close together. Our study has identified one of the closest pairs of black holes in a galaxy merger, and because we know that galaxy mergers are much more common in the distant universe, these black hole binaries too may be much more common than previously thought.”
If close-paired binary black hole pairs are indeed commonplace, as Koss and the team posit, there could be significant implications for future detections of gravitational waves.
Ezequiel Treister, an astronomer at Universidad Católica de Chile and a co-author of the research said, “There might be many pairs of growing supermassive black holes in the centers of galaxies that we have not been able to identify so far. If this is the case, in the near future we will be observing frequent gravitational wave events caused by the mergers of these objects across the universe.”
Pairing ALMA data with multi-wavelength observations from other powerful telescopes like Chandra, Hubble, ESO’s Very Large Telescope, and Keck added fine details to an already-compelling tale. “Each wavelength tells a different part of the story. While ground-based optical imaging showed us the whole merging galaxy, Hubble showed us the nuclear regions at high resolutions. X-ray observations revealed that there was at least one active galactic nucleus in the system,” said Treister. “And ALMA showed us the exact location of these two growing, hungry supermassive black holes. All of these data together have given us a clearer picture of how galaxies such as our own turned out to be the way they are, and what they will become in the future.”
So far, scientists have mostly studied only the earliest stages of galaxy mergers. The new research could have a profound impact on our understanding of the Milky Way Galaxy’s own impending merger with the nearby Andromeda Galaxy. Koss said, “The Milky Way-Andromeda collision is in its very early stages and is predicted to occur in about 4.5 billion years. What we’ve just studied is a source in the very final stage of collision, so what we’re seeing presages that merger and also gives us insight into the connection between black holes merging and growing and eventually producing gravitational waves.”
“This fascinating discovery shows the power of ALMA and how multi-wavelength astronomy can generate important results that expand our understanding of the universe, including black holes, active galactic nuclei, galaxy evolution and more,” says Joe Pesce, NSF program director for the National Radio Astronomy Observatory. “With the advent of gravitational wave detectors, we have an opportunity to expand our observational powers even further by combining all these capabilities. I don’t think there’s really a limit to what we can learn.”
More information:
These results will be presented during a press conference at the 241st proceedings of the American Astronomical Society on Monday, January 9th at 2:15pm Pacific Standard Time (PST).
Provided by
National Radio Astronomy Observatory
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Scientists find pair of black holes dining together in nearby galaxy merger (2023, January 9)
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