- “Beyond What’s Possible” – Webb Space Telescope Discovers Mysterious Ancient Galaxies SciTechDaily
- James Webb Space Telescope tracks a galaxy’s history back to just after the Big Bang Space.com
- Discovery of unexpected ultramassive galaxies may not rewrite cosmology, but still leaves questions Phys.org
- JWST Discovers Another “Beyond Possible” Galaxy And We Have To Rethink Everything IFLScience
- James Webb Space Telescope Has Discovered an Enormous Remnant of the Early Universe That Astronomers Say Shouldn’t Exist The Debrief
Tag Archives: galaxies
The James Webb Space Telescope has captured images of ancient galaxies that shouldn’t exist. A cosmologist explains what could be going on. – BBC Science Focus Magazine
- The James Webb Space Telescope has captured images of ancient galaxies that shouldn’t exist. A cosmologist explains what could be going on. BBC Science Focus Magazine
- James Webb Space Telescope detects a ‘baby galaxy’ Interesting Engineering
- Distant galaxies are gobbling up an unexpected amount of gas New Scientist
- James Webb Space Telescope is Peering Back in Time and Upending Our Understanding of the Universe The Debrief
- Webb Telescope Spots Thousands of ‘Impossible’ Milky Way Lookalikes From Early Universe | Weather.com The Weather Channel
- View Full Coverage on Google News
James Webb Space Telescope reveals ancient galaxies were more structured than scientists thought – Space.com
- James Webb Space Telescope reveals ancient galaxies were more structured than scientists thought Space.com
- James Webb telescope spots thousands of Milky Way lookalikes that ‘shouldn’t exist’ swarming across the early universe Livescience.com
- James Webb Space Telescope sees early galaxies defying ‘cosmic rulebook’ of star formation Yahoo! Voices
- Webb Suggests Ancient Galaxies Were Metal-Poor and Full of Gas Gizmodo
- Finally! Astronomers are Starting to See the First Galaxies Coming Together With JWST Universe Today
- View Full Coverage on Google News
NASA’s James Webb Space Telescope captures spectacular image of ultra-bright merging galaxies – Fox News
- NASA’s James Webb Space Telescope captures spectacular image of ultra-bright merging galaxies Fox News
- Stunning James Webb Space Telescope photo shows merging galaxies shining with light of a trillion suns Fox Weather
- New James Webb photo shows the Fornax constellation like we’ve never seen it before Yahoo News
- Merging galaxies shine with the light of a trillion suns in gorgeous James Webb Space Telescope photo Space.com
- Cosmic Collision Ignites a Trillion-Sun Spectacle: James Webb Space Telescope Unveils Arp 220 SciTechDaily
- View Full Coverage on Google News
Lackluster supernova reveals a rare pair of stars in the Milky Way
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An unusual star system created more of a fizz and less of a bang when it exploded in a supernova.
The lackluster explosion, known as an “ultra-stripped” supernova, led researchers to discover the two stars 11,000 light-years away from Earth.
It’s the first confirmed detection of a star system that will one day create a kilonova – when neutron stars collide and explode, releasing gold and other heavy elements into space. The rare stellar pair is believed to be one of only about 10 like it in the Milky Way galaxy.
The discovery was a long time coming.
In 2016, NASA’s Neil Gehrels Swift Observatory detected a large flash of X-ray light, which originated from the same region in the sky where a hot, bright Be-type star was located.
Astronomers were curious if the two could potentially be linked, so data was captured using the Cerro Tololo Inter-American Observatory’s 1.5-meter telescope in northern Chile.
One of those interested in using this data to learn more about the star was Dr. Noel D. Richardson, now an assistant professor of physics and astronomy at Embry-Riddle Aeronautical University.
In 2019, Clarissa Pavao, an undergraduate student at the university, approached Richardson while taking his astronomy class to ask if he had any projects she could work on to gain experience with astronomy research. He shared the telescope data with her and throughout the pandemic, Pavao learned how to work with the data from the telescope in Chile and clean it up to reduce distortion.
“The telescope looks at a star and it takes in all the light so that you can see the elements that make up this star — but Be stars tend to have disks of matter around them,” Pavao said. “It’s hard to see directly through all that stuff.”
She sent her initial results — which resembled something like a scatterplot — to Richardson, who recognized that she had pinned down an orbit for the double-star system. Follow-up observations helped them verify the orbit of the binary star system, named CPD-29 2176.
But that orbit wasn’t what they were expecting. Typically, binary stars whirl around one another in an oval-shaped orbit. In CPD-29 2176, one star orbits the other in a circular pattern that repeats about every 60 days.
The two stars, a larger one and a smaller one, were whirling around one another in a very close orbit. Over time, the larger star had begun to shed its hydrogen, releasing material onto the smaller star, which grow from 8 or 9 times the mass of our sun to 18 or 19 times the mass of our sun, Richardson said. For comparison’s sake, our sun’s mass is 333,000 times that of Earth.
The main star became smaller and smaller while building up the secondary star — and by the time it had exhausted all of its fuel, there wasn’t enough to create a massive, energetic supernova to release its remaining material into space.
Instead, the explosion was like lighting a dud firework.
“The star was so depleted that the explosion didn’t even have enough energy to kick (its) orbit into the more typical elliptical shape seen in similar binaries,” Richardson said.
What remained after the ultra-stripped supernova was a dense remnant known as a neutron star, which now orbits the rapidly rotating massive star. The stellar pair will remain in a stable configuration for about 5 to 7 million years. Because both mass and angular momentum were transferred to the Be star, it releases a disk of gas to maintain balance and make sure it doesn’t rip itself apart.
Eventually, the secondary star will also burn through its fuel, expand and release material like the first one did. But that material can’t be easily piled up on the neutron star, so instead, the star system will release the material through space. The secondary star will likely experience a similar lackluster supernova and turn into a neutron star.
Over time — that is, likely a couple billion years — the two neutron stars will merge and eventually explode in a kilonova, releasing heavy elements like gold into the universe.
“Those heavy elements allow us to live the way that we do. For example, most gold was created by stars similar to the supernova relic or neutron star in the binary system that we studied. Astronomy deepens our understanding of the world and our place in it,” Richardson said.
“When we look at these objects, we’re looking backward through time,” Pavao said. “We get to know more about the origins of the universe, which will tell us where our solar system is headed. As humans, we started out with the same elements as these stars.”
A study detailing their findings published Wednesday in the journal Nature.
Richardson and Pavao also worked with physicist Jan J. Eldridge at the University of Auckland in New Zealand, an expert on binary star systems and their evolution. Eldridge reviewed thousands of binary star models and estimated there are likely only 10 in the entirety of the Milky Way galaxy similar to the one in their study.
Next, the researchers want to work on learning more about the Be star itself, and hope to conduct follow-up observations using the Hubble Space Telescope. Pavao is also setting her sights on graduating — and continuing to work on space physics research using the new skills she has acquired.
“I never thought I would be working on the evolutionary history of binary star systems and supernovas,” Pavao said. “It’s been an amazing project.”
Webb Telescope Captures Countless Galaxies in New Image
The European Space Agency has released its image of the month for January, and it is (perhaps unsurprisingly) a stunning shot from the Webb Space Telescope.
At the bottom of the image is LEDA 2046648, a spiral galaxy over one billion light-years from Earth in the constellation Hercules. Behind LEDA is a field of more distant galaxies, ranging from spiral shapes to pinpricks of light in the distant universe.
Webb launched from French Guiana in December 2021; its scientific observations of the cosmos began in July. Webb has imaged distant galaxies, exoplanets, and even shed new light on worlds in our local solar system.
Though this image was only just released, it was taken during the commissioning process for one of Webb’s instruments, the Near-Infrared Imager and Slitless Spectrograph (NIRISS), according to an ESA release. While NIRISS was focused on a white dwarf—the core remnant of a star—Webb’s Near-Infrared Camera (NIRCam) turned its focus to LEDA 2046648 and its environs in the night sky.
One of Webb’s primary objectives in looking at the distant universe is to better understand how the first stars and galaxies formed. To that end, the telescope is looking at some of the most ancient light in the universe, primarily through its instruments NIRCam and MIRI.
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The image does contains hundreds of light sources our eye can perceive, but the infrared data from which the image was formed certainly records many more galaxies.
Webb’s deep field imagery is what enables scientists to see some of the most ancient light in the universe, often capitalizing on gravitational lensing (the magnification of distant light due to the gravitational warping of spacetime) to see particularly ancient sources.
Though this shot of LEDA 2046648 is not a deep field, it evokes a similar feeling: awe, at the huge scale of the cosmos, and (if only briefly) the realization that our minds can only comprehend a fraction of it.
More: Zoom in on Webb Telescope’s Biggest Image Yet
Webb Telescope Captures Countless Galaxies in New Image
The European Space Agency has released its image of the month for January, and it is (perhaps unsurprisingly) a stunning shot from the Webb Space Telescope.
At the bottom of the image is LEDA 2046648, a spiral galaxy over one billion light-years from Earth in the constellation Hercules. Behind LEDA is a field of more distant galaxies, ranging from spiral shapes to pinpricks of light in the distant universe.
Read more
Webb launched from French Guiana in December 2021; its scientific observations of the cosmos began in July. Webb has imaged distant galaxies, exoplanets, and even shed new light on worlds in our local solar system.
Though this image was only just released, it was taken during the commissioning process for one of Webb’s instruments, the Near-Infrared Imager and Slitless Spectrograph (NIRISS), according to an ESA release. While NIRISS was focused on a white dwarf—the core remnant of a star—Webb’s Near-Infrared Camera (NIRCam) turned its focus to LEDA 2046648 and its environs in the night sky.
One of Webb’s primary objectives in looking at the distant universe is to better understand how the first stars and galaxies formed. To that end, the telescope is looking at some of the most ancient light in the universe, primarily through its instruments NIRCam and MIRI.
The image does contains hundreds of light sources our eye can perceive, but the infrared data from which the image was formed certainly records many more galaxies.
Webb’s deep field imagery is what enables scientists to see some of the most ancient light in the universe, often capitalizing on gravitational lensing (the magnification of distant light due to the gravitational warping of spacetime) to see particularly ancient sources.
Though this shot of LEDA 2046648 is not a deep field, it evokes a similar feeling: awe, at the huge scale of the cosmos, and (if only briefly) the realization that our minds can only comprehend a fraction of it.
More: Zoom in on Webb Telescope’s Biggest Image Yet
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James Webb Space Telescope finds its first exoplanet
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The James Webb Space Telescope can add another cosmic accomplishment to its list: The space observatory has been used to confirm the existence of an exoplanet for the first time.
The celestial body, known as LHS 475 b and located outside of our solar system, is almost exactly the same size as Earth. The rocky world is 41 light-years away in the Octans constellation.
Previous data collected by NASA’s Transiting Exoplanet Survey Satellite, or TESS, had suggested the planet might exist.
A team of researchers, led by staff astronomer Kevin Stevenson and postdoctoral fellow Jacob Lustig-Yaeger at Johns Hopkins University Applied Physics Laboratory in Laurel, Maryland, observed the target using Webb. They watched for dips in starlight as the planet passed in front of its host star, called a transit, and watched two transits occur.
“There is no question that the planet is there. Webb’s pristine data validate it,” Lustig-Yaeger said in a statement.
The planet’s discovery was announced Wednesday at the 241st meeting of the American Astronomical Society in Seattle.
“The fact that it is also a small, rocky planet is impressive for the observatory,” Stevenson said.
Webb is the only telescope that has the capability to characterize the atmospheres of exoplanets that are the size of Earth. The research team used Webb to analyze the planet across multiple wavelengths of light to see whether it has an atmosphere. For now, the team hasn’t been able to make any definitive conclusions, but the telescope’s sensitivity picked up on a range of molecules that were present.
“There are some terrestrial-type atmospheres that we can rule out,” Lustig-Yaeger said. “It can’t have a thick methane-dominated atmosphere, similar to that of Saturn’s moon Titan.”
The astronomers will have another chance to observe the planet again over the summer and conduct follow-up analysis on the potential presence of an atmosphere.
Webb’s detections also revealed that the planet is a few hundred degrees warmer than our planet. If the researchers detect any clouds on LHS 475 b, it may turn out to be more like Venus — which is considered to be Earth’s hotter twin with a carbon dioxide atmosphere.
“We’re at the forefront of studying small, rocky exoplanets,” Lustig-Yaeger said. “We have barely begun scratching the surface of what their atmospheres might be like.”
The planet completes a single orbit around its red dwarf host star every 2 Earth days. Given that the star is less than half the temperature of our sun, it’s possible that the planet could still maintain an atmosphere despite its close proximity to the star.
The researchers believe their discovery will just be the first of many in Webb’s future.
“These first observational results from an Earth-sized, rocky planet open the door to many future possibilities for studying rocky planet atmospheres with Webb,” said Mark Clampin, Astrophysics Division director at NASA Headquarters, in a statement. “Webb is bringing us closer and closer to a new understanding of Earth-like worlds outside the Solar System, and the mission is only just getting started.”
More Webb observations were shared at the meeting on Wednesday, including never-before-seen views of a dusty disk swirling around a nearby red dwarf star.
The telescope’s images mark the first time such a disk has been captured in these infrared wavelegnths of light, which are invisible to the human eye.
The dusty disk around the star, named AU Mic, represents the remnants of planet formation. When small, solid objects called planetesimals — a planet in the making — crashed into each other, they left behind a big, dusty ring around the star and formed a debris disk.
“A debris disk is continuously replenished by collisions of planetesimals. By studying it, we get a unique window into the recent dynamical history of this system,” said lead study author Kellen Lawson, postdoctoral program fellow at NASA’s Goddard Space Flight Center in Greenbelt, Maryland, and member of the research team that studied AU Mic.
Webb’s capabilities allowed astronomers to see the region close to the star. Their observations and data could provide insights that aid in the search for giant planets that form wide orbits in planetary systems, not unlike Jupiter and Saturn in our solar system.
The AU Mic disk is located 32 light-years away in the Microscopium constellation. The star is about 23 million years old, so planet formation has already ceased around the star — since that process usually takes less than 10 million years, according to the researchers. Other telescopes have spotted two planets orbiting the star.
“This system is one of the very few examples of a young star, with known exoplanets, and a debris disk that is near enough and bright enough to study holistically using Webb’s uniquely powerful instruments,” said study coauthor Josh Schlieder, principal investigator for the observing program at NASA’s Goddard Space Flight Center.
The Webb telescope was also used to peer inside NGC 346, a star-forming region located in a neighboring dwarf galaxy called the Small Magellanic Cloud.
About 2 billion to 3 billion years after the big bang that created the universe, galaxies were filled with fireworks of star formation. This peak of star formation is called “cosmic noon.”
“A galaxy during cosmic noon wouldn’t have one NGC 346, as the Small Magellanic Cloud does; it would have thousands,” said Margaret Meixner, an astronomer at the Universities Space Research Association and principal investigator of the research team, in a statement.
“Even if NGC 346 is now the one and only massive cluster furiously forming stars in its galaxy, it offers us a great opportunity to probe the conditions that were in place at cosmic noon.”
Observing how stars form in this galaxy allows astronomers to compare star formation in our own Milky Way galaxy.
In the new Webb image, forming stars can be seen pulling in ribbon-like gas and dust from a surrounding molecular cloud. This material feeds the formation of stars, and eventually, planets.
“We’re seeing the building blocks, not only of stars, but also potentially of planets,” said co-investigator Guido De Marchi, a space science faculty member of the European Space Agency, in a statement. “And since the Small Magellanic Cloud has a similar environment to that of galaxies during cosmic noon, it’s possible that rocky planets could have formed earlier in the history of the Universe than we might have thought.”
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.
Astronomers May Have Just Spotted the Universe’s First Galaxies
Scientists just announced that they’ve detected what might be some of the earliest galaxies to form in the universe, a tantalizing discovery made thanks to NASA’s new flagship James Webb Space Telescope.
“This is the first large sample of candidate galaxies beyond the reach of the Hubble Space Telescope,” astronomer Haojing Yan said yesterday at a press conference at the American Astronomical Society meeting in Seattle. Yan, who is at the University of Missouri, led the newly published study. Because the more sensitive JWST can see further into deep space than its predecessor Hubble does, it essentially sees further back in time. In the new catalog of 87 galaxies astronomers have spotted using it, some could date back to about 13.6 billion years ago, just 200 million years after the Big Bang. That’s when the galaxies emitted the light that we’re seeing today—although those systems of stars, gas, and dust would have changed dramatically since then, if they still exist at all.
While scientists have studied other faraway galaxies that date back to when the universe was still young, the discoveries by Yan and his colleagues could break those records by a few hundred million years or so. But at this point, they are all still considered “candidate galaxies,” which means that their birthdates still need confirmation.
Dating a galaxy can be a challenging matter: It involves measuring its “redshift,” how much the light it emits is stretched toward longer red wavelengths, which tells astronomers how fast the galaxy is moving away from us in the quickly expanding universe. That, in turn, tells astronomers the galaxy’s distance from Earth—or more exactly, the distance that the photons from its stars had to travel at the speed of light before reaching a space telescope near the Earth, like JWST. Light from stars in the most distant galaxy in this collection may have been emitted 13.6 billion years ago, likely fairly soon after the young galaxy came together.
These newly estimated distances will have to be confirmed with spectra, which means measuring the light the galaxies emit across the electromagnetic spectrum and pinpointing its unique signatures. Still, Yan expects many of them to be correctly dated to the early days of the cosmos: “I’ll bet $20 and a tall beer that the success rate will be higher than 50 percent,” he said.
Yan’s team imaged these galaxies with JWST’s NIRCam at six near-infrared wavelengths. To estimate their distances, the astronomers used a standard “dropout” technique: Hydrogen gas surrounding galaxies absorbs light at a particular wavelength, so the wavelengths at which an object can or can’t be seen puts a limit on how far away it is likely to be. These 87 candidate galaxies mostly look like blobs that can only be detected in the longer (and therefore redder) near-infrared wavelengths detectable by NIRCam, which could mean they’re very distant, and therefore very old.
However, it’s possible that some of them could be much closer than expected—which would mean they aren’t so old after all. For example, it could be that their light is just too faint to be detected at some wavelengths. Until Yan can collect more detailed data, he won’t know for sure.