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Tag Archives: Astronomers
Astronomers capture rare “bizarre” star explosion that could help uncover “the mysteries of the universe” – CBS News
- Astronomers capture rare “bizarre” star explosion that could help uncover “the mysteries of the universe” CBS News
- Supernova explosion 4 billion light-years away revealed using gravitational lensing VideoFromSpace
- Einstein’s Theory in Action: Supernova Explosion Revealed by Rare “Cosmic Magnifying Glasses” SciTechDaily
- A tiny galaxy brightening up a distant supernova Nature.com
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Astronomers discover 2nd-ever ‘Tatooine’ star system with multiple planets orbiting multiple suns – Livescience.com
- Astronomers discover 2nd-ever ‘Tatooine’ star system with multiple planets orbiting multiple suns Livescience.com
- New Tatooine-like exoplanet discovered orbiting twin suns. Meet BEBOP-1c. Space.com
- Direct from `Star Wars`: Tatooine-like planet that orbits twin stars discovered WION
- Astronomers Discover BEBOP-1c: Tatooine-Like Exoplanet Orbits Twin Stars in a Multiplanetary System SciTechDaily
- New Solar System Found Where Planets Orbit Two Suns—Just like Luke Skywalker’s Home in Star Wars Good News Network
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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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Astronomers find rare star system that will lead to gold-producing explosion
Astronomers at the National Science Foundation’s NOIRLab made the first confirmed detection of a star system that will one day form a kilonova, an ultra-powerful and gold-producing explosion created by merging neutron stars.
Researchers said on Tuesday that they used data from the SMARTS 1.5-meter Telescope at Cerro Tololo Inter-American Observatory in Chile to uncover the first example of the phenomenally rare type of binary star system. The findings are published in the journal Nature.
The arrangement, known as CPD-29 2176, is so astonishingly rare that only about 10 such systems are believed to exist in the Milky Way galaxy.
CPD-29 2176, is located about 11,400 light-years from Earth and was first identified by NASA’s Neil Gehrels Swift Observatory.
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The SMARTS 1.5m telescope in Chile
(Rodrigo Hinojosa )
Upon further observation with the telescope, the scientists were able to deduce the orbital characteristics and types of stars that make up this system: a neutron star that was created by an ultra-stripped supernova and a closely orbiting massive star that is in the process of becoming an ultra-stripped supernova itself.
An ultra-stripped supernova is the end-of-life explosion of a massive star that has had much of its outer atmosphere stripped away by a companion star.
An artist’s impression of the first confirmed detection of a star system that will one day form a kilonova – the ultra-powerful, gold-producing explosion created by merging neutron stars.
(NOIRLab)
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“The current neutron star would have to form without ejecting its companion from the system. An ultra-stripped supernova is the best explanation for why these companion stars are in such a tight orbit,” the paper’s lead author, Noel Richardson of Embry-Riddle Aeronautical University, said in a statement. “To one day create a kilonova, the other star would also need to explode as an ultra-stripped supernova so the two neutron stars could eventually collide and merge.”
This long-exposure photograph shows the motion of stars during the night above the Blanco 4-meter telescope (left) and the SMARTS 1.5-meter telescope (right) at Cerro Tololo Inter-American Observatory in Chile, a program of the NSF’s National Optical-Infrared Astronomy Research Laboratory.
(Credit: CTIO//NOIRLab/NSF/AURA/D. Munizaga)
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It will take at least a million years for the massive star to end its life as a titanic supernova explosion and leave behind a second neutron star. The authors said the stellar remnant and the pre-existing neutron star will need to draw together before merging and noted that the resulting kilonova explosion will produce much more powerful gravitational waves and leave behind a large amount of heavy elements, including silver and gold.
Astronomers Find Rare Star System That Will Trigger a Kilonova
The universe has no shortage of oddities, and researchers at the National Science Foundation’s NOIRLab have observed another one in the form of a particular binary star system. The system, called CPD-29 2176, will eventually trigger a kilonova, a celestial event in which two neutron stars collide in a massive explosion that forms heavy elements, including gold and platinum.
CPD-29 2176 is located around 11,400 light-years from Earth and was found by researchers using NASA’s Neil Gehrels Swift Observatory. Astronomers then conducted more observations at NOIRLab’s Cerro Tololo Inter-American Observatory in Chile. CPD-29 2176 is home to one neutron star and one massive star that is in the process of going supernova, only to become a second neutron star in the future. Eventually, the two neutron stars will collide, producing a kilonova, an explosion that is thought to produce bursts of gamma rays and large amounts of gold and platinum. The paper documenting the research team’s find is published today in Nature.
“We know that the Milky Way contains at least 100 billion stars and likely hundreds of billions more. This remarkable binary system is essentially a one-in-ten-billion system,” said André-Nicolas Chené in a NOIRLab press release. Chené is a NOIRLab astronomer and an author on the study. “Prior to our study, the estimate was that only one or two such systems should exist in a spiral galaxy like the Milky Way.”
While many stars implode was a powerful supernova when they die, the dying star in CPD-29 2176 is becoming an ultra-stripped supernova. An ultra-stripped supernova lacks the vast amount of force that a typical supernova has, since the dying star has had much of its mass stripped by its companion. The researchers think that the neutron star in the system was also formed with an ultra-stripped supernova and argue that this is the reason that CPD-29 2176 is able to remain as a binary—a typical supernova would have enough power to kick a companion star out of its orbit.
“The current neutron star would have to form without ejecting its companion from the system. An ultra-stripped supernova is the best explanation for why these companion stars are in such a tight orbit,” said lead author Noel D. Richardson, a physics and astronomy professor at Embry-Riddle Aeronautical University, in the NOIRLab release. “To one day create a kilonova, the other star would also need to explode as an ultra-stripped supernova so the two neutron stars could eventually collide and merge.”
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It will take around one million years for the star undergoing ultra-stripped supernova to turn into a neutron star. It is then when the two stars will begin to spiral into each other, eventually resulting in the metal-producing kilonova, according to the research. In these dramatic cosmic endings, we can look forward to the creation of the same elements that make life possible.
More: Watch Four Planets Spin Around a Star 130 Million Light-Years Away
Astronomers identify 1st twin stars doomed to collide in kilonova explosion
Although massive stars usually die with spectacular explosions, a handful fizzle out like dud firecrackers.
Astronomers have identified the remnants of one such dud firecracker in SGR 0755-2933, a neutron star about 11,400 light-years from Earth in the southern constellation of Puppis. In new research, scientists say that earlier in its lifetime, this star transferred abnormally high amounts of mass to its binary companion — so much so that it was not left with enough material for an explosive death. Instead, it ended in a quiet “ultra-stripped” supernova, a rare cosmic event that leaves a super-dense remnant called a neutron star in its wake.
“This remarkable binary system is essentially a one-in-10-billion system,” André-Nicolas Chené, an astronomer at the National Science Foundation’s NOIRLab research center and a co-author of the new study, said in a statement.
Related: Right place, right time: Hubble telescope captured a supernova as it exploded
The neutron star and its closely orbiting binary companion — a star that the researchers also predict will someday collapse to become a neutron star — mark the first clear example of a star system that will ultimately trigger a kilonova, a cosmic explosion during which two neutron stars merge.
Although a kilonova was first detected in 2017, astronomers then recorded only the aftermath of the event, thanks to observations of light and gravitational waves. The new research is the first time scientists have identified a binary star system that they know will end in a kilonova explosion.
Moreover, astronomers previously thought that only one or two such systems would exist in spiral galaxies like our Milky Way. Researchers of the latest study have now increased that estimate to 10, noting that these observations help them better understand the history, evolution and atypically calm deaths of stars in such systems.
“For quite some time, astronomers speculated about the exact conditions that could eventually lead to a kilonova,” Chené said in the statement. “These new results demonstrate that, in at least some cases, two sibling neutron stars can merge when one of them was created without a classical supernova explosion.”
The sibling star is massive, orbits the primary neutron star every 60 days, and has a name like a license plate: CPD-29 2176. Scientists behind the latest research studied this sibling star to understand the formation of the current star system, as well as what might unfold in its future.
“This is not just a simple binary system”
Clarissa Pavao, an undergraduate student at the Embry-Riddle Aeronautical University in Arizona, found the system while scouring data captured by the Cerro Tololo Inter-American Observatory in Chile. In particular, she was plotting the spectra of the sibling star, an analysis of how much light a star emits at particular wavelengths. After cleaning noise from the data, she noticed one simple line in the spectra that suggested the massive star had a highly circular orbit — an unusual feature in binary star systems.
This was a key finding that helped the team conclude that the primary neutron star ended as a dud supernova, the astronomers said.
Usually, when one of the stars in a binary system burns through its hydrogen and nears the end of its main-sequence stage, it begins transferring mass to its companion star. The resulting end-of-life explosion often kicks companion stars out of the systems and into highly elliptical orbits.
But this did not seem to have occurred in the intriguing system. To better understand what might have happened at the end of SGR 0755-2933’s life, astronomers waded through thousands of models that described binary star systems resembling the one they were studying. They only found two that matched.
The team then traced the star’s history and concluded it behaved, for the most part, like any other massive star running out of fuel: Toward the end of its life, the star began transferring mass to its companion and dwindled into a low-mass star with a helium core, as scientists expected. In this process, however, the star lost so much mass that its end-of-life supernova “didn’t even have enough energy to kick the orbit into the more typical elliptical shape seen in similar binaries,” Noel Richardson, an astronomer at Embry-Riddle and lead author of the new study, said in a statement.
The dying star also did not have enough energy to kick its companion out of the system, which is why the two stars continue to have tight orbits, according to the study.
In addition to learning more about kilonova events, the new research will help astronomers better understand the origins of some of the heaviest elements in our universe.
The quiet supernova occurred only a few million years ago, and astronomers expect the CPD-29 2176 system to remain as it is for at least one million years more. Their models show that, much like the primary neutron star, the sibling star too will then become an ultra-stripped supernova and eventually collapse into a neutron star.
Millions of years from now, the team predicts that the two neutron stars will spiral slowly toward each other in a cosmic dance, ultimately colliding in a kilonova explosion. Such explosions are known to be a source of immense quantities of heavy elements like platinum, xenon, uranium and gold “that get hurled into the universe,” Richardson said.
Astronomers have long suspected that heavy metals released during such events hovered in the interstellar medium until they coalesced into asteroids, which then bombarded Earth as it formed and deposited the precious metals we see today. The 2017 kilonova event alone sent at least 100 Earth’s worth of precious heavy metals out there, so it looks like a failed supernova isn’t such a loss to the universe after all.
The research is described in a paper (opens in new tab) published Wednesday (Feb. 1) in the journal Nature.
Follow Sharmila Kuthunur on Twitter @Sharmilakg. Follow us on Twitter @Spacedotcom and on Facebook.
Astronomers Discover an Exoplanet Spiraling Toward Its Destruction
Ashley Chontos, Princeton’s Henry Norris Russell Postdoctoral Fellow in Astrophysics, was part of a team discovering that Kepler-1658b is spiraling to its doom around its aging star, providing a chance to learn more about the fate of other worlds as their solar systems evolve. Chontos also led 2019 effort to confirm that this object was an exoplanet, not the false positive it had believed to be for a decade. Credit: Gabriel Perez Diaz/Instituto de Astrofísica de Canarias
The impending demise of Kepler-1658b as it orbits its aging star offers an opportunity for scientists to gain insight into the fate of other planets and their evolving solar systems.
Astronomers have made a groundbreaking discovery of an
The discovery of an exoplanet whose orbit is decaying as it orbits an aging star provides a new understanding of the gradual process of planetary orbital decay by offering the first glimpse of a solar system in its final stages. The fate of being consumed by a star is believed to be the ultimate destiny for many planets, including Earth in about 5 billion years. According to scientists, the exoplanet Kepler-1568b has less than 3 million years left before it meets its demise.
Ashley Chontos, Princeton’s Henry Norris Russell Postdoctoral Fellow in Astrophysics, was part of a team discovering that Kepler-1658b is spiraling to its doom around its aging star, providing a chance to learn more about the fate of other worlds as their solar systems evolve. Credit: Stephanie Reif, Princeton University Department of Astrophysical Sciences
“We’ve had theorists predict the fates of stars and their planets for decades, but we’ve never before had observations to test them against,” said Ashley Chontos, the Henry Norris Russell Postdoctoral Fellow in Astrophysics at Princeton. “We can also think about this in terms of our own solar system. How long will Earth survive once the sun fuses all its hydrogen into helium? We have some ideas, but ultimately it’s hard to say for certain. These single-planet systems are really important for helping anchor these different theories.”
Chontos is the second author on a new study in the Astrophysical Journal Letters describing the researchers’ observations of the doomed exoplanet.
The first author is Shreyas Vissapragada, a 51 Pegasi b Fellow at Harvard University and the Smithsonian Institution. “We’ve previously detected evidence for exoplanets in-spiraling toward their stars, but we have never before seen such a planet around an evolved star,” he said.
For stars similar to the sun, “evolved” refers to those that have fused all their hydrogen into helium and moved into the next stage of their life. In this case, the star has begun expanding into a subgiant. “Theory predicts that evolved stars are very effective at sapping energy from their planets’ orbits, and now we can test those theories with observations,” Vissapragada said.
The ill-fated exoplanet is designated Kepler-1658b. As its name indicates, astronomers discovered it with the Kepler space telescope, a pioneering planet-hunting mission that launched in 2009. This world was the very first new exoplanet candidate Kepler ever observed, at which point it was dubbed KOI 4.01 — the 4th Object of Interest identified by Kepler. (KOIs 1, 2, and 3 had been identified before Kepler’s launch.)
Early on, KOI 4.01 was dismissed as a false positive. A decade would pass before Chontos, looking at seismic waves moving through its star, realized that the reason the data didn’t fit the model was that the scientists thought they were modeling a
Why? The same phenomenon is responsible for the daily rise and fall of Earth’s oceans: tides.
Tides are generated by when orbiting bodies tug on each other, whether Earth and the moon or Kepler-1658b and its star. Both bodies exert gravitational pulls on each other, but the bigger body always wins, meaning that the smaller body flexes more.
The tugging distorts each body’s shape, and as the planet and star respond to these changes, energy is released. Depending on the distances between them, their sizes, and their rotation rates, these tidal interactions can result in bodies pushing each other away — the case for the Earth and the slowly outward-spiraling Moon — or inward, as with Kepler-1658b toward its star.
There is still a lot researchers do not understand about these dynamics, particularly in star-planet scenarios, so the astrophysicists are eager to learn more from the Kepler-1658 system.
Chontos, who came to Princeton only a few months ago, said that she is looking forward to discussing her findings with the theorists and other astrophysicists here.
“I’m a first-generation, non-traditional student,” Chontos said. “I didn’t apply to Princeton for undergrad or grad school, because I had this vision in my head of what people would be like — and I couldn’t have been more wrong, in the best possible way. They’re doing everything right. There’s a reason why our department has something like 60 postdocs. And at coffee hours and colloquia, I have the opportunity to talk with the people who wrote the theory papers that inspire me.’”
Kepler-1658b’s star has evolved to the point in its stellar life cycle where it has started to expand, just as our sun is expected to, and it has entered into what astronomers call a subgiant phase. Theorists have predicted that the internal structure of evolved stars should more readily lead to the dissipation of tidal energy taken from hosted planets’ orbits compared to hydrogen-rich stars like our Sun. This would accelerate the orbital decay process, making it easier to study on human timescales.
“Even though physically, this exoplanet’s system is very dissimilar to our solar system — our home — it can still tell us a lot about the efficiency of these tidal dissipation processes, and how long these planets can survive,” said Chontos.
Kepler-1658b is about 2 billion years old and is in the last 1% of its life, she said. She and her colleagues predict that the planet will collide with its star in about 3 million years.
For more on this research, see Exoplanet Discovered Spiraling to Ultimate Obliteration Around an Aging Star.
Reference: “The Possible Tidal Demise of Kepler’s First Planetary System” by Shreyas Vissapragada, Ashley Chontos, Michael Greklek-McKeon, Heather A. Knutson, Fei Dai, Jorge Pérez González, Sam Grunblatt, Daniel Huber and Nicholas Saunders, 19 December 2022, The Astrophysical Journal Letters.
DOI: 10.3847/2041-8213/aca47e
The study was funded by the Science Mission Directorate and the
Astronomers Just Realized The Milky Way Is Too Big For Its Surroundings : ScienceAlert
Our home, the Milky Way, doesn’t seem particularly odd for a galaxy. Moderately-sized, spiral in shape, with a few kinks suggestive of a disruptive past.
But astronomers have just identified a quirk never before seen in any galaxy studied to date: the Milky Way is too big for its surroundings.
Specifically, it appears to be too large for the neighborhood it sits within known as the Local Sheet. This flattened arrangement of galaxies share similar velocities, bounded by relatively empty space called voids on either side.
Our Local Sheet, as an example of a ‘cosmological wall’, separates the Local Void in one direction from the Southern Void in the other.
The relationship between the galaxies in the Local Sheet seems to exert a strong influence over their behavior; for example, their similar velocities relative to the expansion of the Universe. Outside of the cosmological wall environment, these velocities would have a much wider range.
To determine the effect the environment has on the galaxies around us, a team of astronomers led by Miguel Aragón of the National Autonomous University of Mexico conducted an analysis using simulations from a project called IllustrisTNG, which models the physical Universe.
They weren’t expecting to find anything particularly out of the ordinary.
“The Milky Way is, in a way, special,” Aragón says. “Earth is very obviously special, the only home of life that we know. But it’s not the center of the Universe, or even the Solar System. And the Sun is just an ordinary star among billions in the Milky Way. Even our galaxy seemed to be just another spiral galaxy among billions of others in the observable Universe.”
But when they simulated a volume of space about a billion light-years across containing millions of galaxies, a different picture emerged: just a scant handful of galaxies as massive as the Milky Way could be located within a cosmological wall structure.
“The Milky Way doesn’t have a particularly special mass, or type. There are lots of spiral galaxies that look roughly like it,” says astronomer Joe Silk of Sorbonne University’s Institut d’Astrophysique de Paris in France.
“But it is rare if you take into account its surroundings. If you could see the nearest dozen or so large galaxies easily in the sky, you would see that they all nearly lie on a ring, embedded in the Local Sheet. That’s a little bit special in itself. What we newly found is that other walls of galaxies in the Universe like the Local Sheet very seldom seem to have a galaxy inside them that’s as massive as the Milky Way.”
The team’s analysis didn’t take into account Andromeda, the Milky Way’s largest galactic neighbor. Also a feature of the Local Sheet – and therefore a part of the same cosmological wall – it’s a galaxy of a similar size to the Milky Way. Since having two heavyweights in a cosmological wall would be even rarer still, their conclusions still apply.
However, the research does highlight that we might need to consider our local environment when studying the Milky Way, rather than assuming that our home hangs out in an average way in an average spot in the Universe.
Because the team’s simulations only considered the Milky Way’s context within a cosmological wall, perhaps future work could account for more galaxies within the Local Group. The researchers also note that the environmental context could help explain some previously unexplained phenomena, such as the unusual arrangement of satellite galaxies around Andromeda, and the peculiar lack of them around the Milky Way.
“You do have to be careful … choosing properties that qualify as ‘special’,” says astronomer Mark Neyrinck of the Basque Foundation for Science in Spain.
“If we added a ridiculously restrictive condition on a galaxy, such as that it must contain the paper we wrote about this, we would certainly be the only galaxy in the observable Universe like that. But we think this ‘too big for its wall’ property is physically meaningful and observationally relevant enough to call out as really being special.”
The research has been published in the Monthly Notices of the Royal Astronomical Society.
Astronomers Capture Radio Signal From Distant Galaxy
One of the dishes of the Giant Metrewave Radio Telescope (GMRT) near Pune, Maharashtra, India. Credit: National Centre for Radio Astrophysics
Probing galaxies at much greater distances from Earth may now be within reach.
How do stars form in distant galaxies? Astronomers have long been trying to answer this question by detecting radio signals emitted by nearby galaxies. However, these signals become weaker the further away a galaxy is from Earth, making it difficult for current radio telescopes to pick up.
Now researchers from Montreal and India have captured a radio signal from the most distant galaxy so far at a specific wavelength known as the 21 cm line, allowing astronomers to peer into the secrets of the early universe. With the help of the Giant Metrewave Radio Telescope in India, this is the first time this type of radio signal has been detected at such a large distance.
Illustration showing detection of the signal from a distant galaxy. Credit: Swadha Pardesi
“A galaxy emits different kinds of radio signals. Until now, it’s only been possible to capture this particular signal from a galaxy nearby, limiting our knowledge to those galaxies closer to Earth,” says Arnab Chakraborty, a Post-Doctoral Researcher at McGill University under the supervision of Professor Matt Dobbs.
“But thanks to the help of a naturally occurring phenomenon called gravitational lensing, we can capture a faint signal from a record-breaking distance. This will help us understand the composition of galaxies at much greater distances from Earth,” he adds.
A look back in time to the early universe
For the first time, the researchers were able to detect the signal from a distant star-forming galaxy known as SDSSJ0826+5630 and measure its gas composition. The researchers observed the atomic mass of the gas content of this particular galaxy is almost twice the mass of the stars visible to us.
Image of the radio signal from the galaxy. Credit: Chakraborty & Roy/NCRA-TIFR/GMRT
The signal detected by the team was emitted from this galaxy when the universe was only 4.9 billion years old, enabling the researchers to glimpse into the secrets of the early universe. “It’s the equivalent to a look-back in time of 8.8 billion years,” says Chakraborty, who studies cosmology at McGill’s Department of Physics.
Picking up the signal from a distant galaxy
“Gravitational lensing magnifies the signal coming from a distant object to help us peer into the early universe. In this specific case, the signal is bent by the presence of another massive body, another galaxy, between the target and the observer. This effectively results in the magnification of the signal by a factor of 30, allowing the telescope to pick it up,” says co-author Nirupam Roy, an Associate Professor in the Department of Physics at the Indian Institute of Science.
According to the researchers, these results demonstrate the feasibility of observing faraway galaxies in similar situations with gravitational lensing. It also opens exciting new opportunities for probing the cosmic evolution of stars and galaxies with existing low-frequency radio telescopes.
Reference: “Detection of H I 21 cm emission from a strongly lensed galaxy at z ∼ 1.3” by Arnab Chakraborty and Nirupam Roy, 23 December 2022, Monthly Notices of the Royal Astronomical Society.
DOI: 10.1093/mnras/stac3696
The Giant Metrewave Radio Telescope was built and is operated by NCRA-TIFR. The research was funded by McGill University and the Indian Institute of Science.