The galaxy next to ours is being torn apart, study suggests

The galaxy next to ours might be getting torn apart, a study has suggested.
The Small Magellanic Cloud, or SMC – a relatively small galaxy that neighbours ours – appears to be getting torn to bits by the gravitational pull of a neighbouring galaxy, the new research suggests.
'When we first got this result, we suspected that there might be an error in our method of analysis,' said Kengo Tachihara, from Nagoya University in Japan. 'However, upon closer examination, the results are indisputable, and we were surprised.'
The SMC is one of our nearest neighbours, which allows researchers to keep close tabs on the roughly 7,000 massive stars that make up the galaxy. Those stars are more than eight times the mass of our Sun, and usually last for just a few million years before they explode into supernovae.
As they watched those stars, researchers noticed that they appeared to be getting pulled apart by the Large Magellanic Cloud, or LMC, which itself neighbours the galaxy.
'The stars in the SMC were moving in opposite directions on either side of the galaxy, as though they are being pulled apart,' said Tachihara. 'Some of these stars are approaching the LMC, while others are moving away from it, suggesting the gravitational influence of the larger galaxy.
'This unexpected movement supports the hypothesis that the SMC is being disrupted by the LMC, leading to its gradual destruction.'
Researchers also noticed that the SMC does not appear to be rotating. Usually, young massive stars move around along with the gas that they were born from – but the SMC's stars do not appear to be moving in that way, suggesting that the gas itself is not rotating as expected.
That could lead to a new understanding not only of the SMC but also the way it interacts with galaxies including our own.
Further the research could help us better understand the conditions and story of the early universe. The SMC is useful for understanding the cosmos when it was younger than it is today, because it shares some characteristics with early galaxies.
'We are unable to get a 'bird's-eye view' of the galaxy in which we live,' said Tachihara. 'As a result, the SMC and the LMC are the only galaxies in which we can observe the details of stellar motion. This research is important because it allows us to study the process of star formation in connection with the motion of stars throughout the galaxy.'
The work is described in a new paper, 'Evidence of Galactic Interaction in the Small Magellanic Cloud Probed by Gaia-selected Massive Star Candidates', published in The Astrophysical Journal Supplement Series.

Try Our AI Features

Explore what Daily8 AI can do for you:

Learn with AIFact CheckingText to SpeechAI Summary

Related Articles

Forbes

10 hours ago

• Forbes

ESA's Solar Orbiter Should Solve Mystery Of Sun's Outermost Atmosphere

ESA's Solar Orbiter mission will face the Sun from within the orbit of Mercury at its closest ... More approach. The European Space Agency's Solar Orbiter mission recently stunned the world with the first-ever full images of our Sun's South pole, proving that this was going to be a mission like no other. Using an orbital gravity assist from the planet Venus, the Solar Orbiter mission spacecraft was able to maneuver into an orbit that has taken it to an angle 17 degrees below the Sun's equator. Over the coming years, the spacecraft will tilt its orbit even further, so the best views are yet to come, says ESA. The 1.2-billion-euro Solar Orbiter mission, with NASA participation, should finally help us understand the origin of the Sun's solar winds as well as our understanding of the Sun's poles. And arguably most importantly, it should solve the puzzle of why our star's outermost atmosphere, or corona, is heated to millions of degrees Kelvin and is thus so much hotter than the Sun's own surface. By contrast, our Sun's visible photosphere, or surface, averages only 5,500 degrees K. With Solar Orbiter, we are clearly seeing energy releases on the nano-flare scale, Daniel Mueller, a solar physicist and ESA project scientist for both ESA's SOHO and Solar Orbiter missions to the Sun, tells me in his office in The Netherlands. But the question is, would these nano-flares continue like that infinitely, or is there a certain lower limit to the production of these nano-flares, Mueller wonders. The puzzle is whether these nano-flares are enough to heat up the Sun's corona to the temperatures with which it is routinely measured. A Unique View Launched in 2020, from its highly elliptical orbit just inside Mercury's perihelion, the closest point in our innermost planet's solar orbit, the ESA spacecraft offers the best views yet of our own yellow dwarf star. We can see on scales down to about 200 kilometers on the Sun, which shows us a lot of dynamics of our star, says Mueller. And thanks to its newly tilted orbit around the Sun, the European Space Agency-led Solar Orbiter spacecraft is the first to image the Sun's poles from outside the ecliptic plane (the imaginary geometric plane in which our Earth orbits the Sun), says ESA. We observed the Sun's North pole at the end of this past April, says Mueller. But we passed the Southern pole first and then the Northern pole six weeks later, he says. At the moment, as seen from Earth, the Solar Orbiter is almost behind the Sun, so the data downlink has slowed to a trickle. But by early October, Mueller expects to have downloaded all the data from Solar Orbiter's Spring polar observations of the Sun. And within a matter of two to three months after the data is on the ground, the first scientific results will have been written up and submitted to journals for publication, says Mueller. These observations are also key to understanding the Sun's magnetic field and why it flips roughly every 11 years, coinciding with a peak in solar activity, says ESA. The spacecraft's instruments show that the Sun's South pole is a bit of a magnetic mess now, with both North and South polarity magnetic fields present, ESA notes. Ready To Flip Right now, there is not a clear dominant magnetic polarity, but a mix of the two, says Mueller. And that is exactly what you would expect to find during the maximum of the Sun's activity cycle, when the magnetic field is about to flip, he says. The real applications are for space weather predictions. Case in point, better space weather forecasting may have saved many of Elon Musk's 523 Starlink satellites that reentered Earth's atmosphere between 2020 and 2024. This period coincides with the rising phase of solar cycle 25, which has shown itself to be more intense than the previous solar cycle, the authors of a 2025 paper appearing in the journal Frontiers in Astronomy and Space Sciences write. Our results indisputably show that satellites reenter faster with higher geomagnetic activity, the authors note. There was a big solar storm that caused the earth's upper Earth atmosphere to expand, so, the satellites experienced more drag, and therefore didn't make it to orbit, says Mueller. One option may have been simply to hold off on launches until this increased period of solar activity enabled a less risky geomagnetic environment in Earth's upper atmosphere. The hope is that the Solar Orbiter mission and other missions like it will lead to better and more reliable space weather predictions that could potentially save hundreds of millions of dollars in the commercial satellite industry. Solar Orbiter should do its share in solving both pure solar physics conundrums as well as in more practical applications like space weather. The good news is that the spacecraft still has plenty of fuel left. Our current funding goes until the end of 2026, but because we had a picture-perfect launch provided by United Launch Alliance and NASA, we saved a lot of fuel, says Mueller. So, the onboard fuel reserves are so large that we can keep going for a long time, he says.

Yahoo

a day ago

• Yahoo

Earth's Magnetic Field Might Weirdly Be Controlling the Air We Breathe, Scientists Say

"Hearst Magazines and Yahoo may earn commission or revenue on some items through these links." Here's what you'll learn when you read this story: Earth's oxygenated atmosphere and magnetic field make life possible, but scientists have discovered that there's a hidden link between the two that's stronger than we originally imagined. Comparing 540 million years of data from charcoal deposits and magnetic crystals formed from ancient volcanic eruptions, scientists found that the processes creating both increase at the same rate over time, and even experience the same jump in activity levels around 330 million years ago. Scientists aren't yet certain which mechanism is impacting the other—or if there is a third mechanism impacting them both. If you list all of the things that had to go right to make life on Earth possible, our minuscule existence (cosmically speaking) seems all the more amazing. Our Sun is a G-type star with moderate radiation output that doesn't tidally lock our planet. The Earth is situated in our Sun's habitable zone. The planet has maintained a robust atmosphere for hundreds of millions of years, and the dynamo at the planet's heart generates a magnetic field that protects us from the most harmful effects of space radiation. Earth truly is a paradise for life. Although scientists have known about these life-giving aspects of Earth for centuries, they're still discovering surprising connections between them. In a new study published last week in the journal Science Advances, scientists from NASA, the University of Washington, and the University of Leeds in the U.K. discovered a surprising connection between two of Earth's most important life-sustaining features—its oxygenated atmosphere and its magnetic field. It's hardly surprising that the existence of one of these features might impact the existence of the other. After all, Mars (which is also in the Sun's habitable zone) used to have an atmosphere, but without a robust magnetic field, the Red Planet eventually lost that atmosphere to the unrelenting lashing of solar winds. However, the authors of this new paper found that, on Earth, the correlation between these two systems runs much deeper than we previously imagined. 'We find that both exhibit strong linearly increasing trends, coupled with a large surge in magnitude between 330 and 220 million years ago,' the authors wrote. 'Our findings suggest unexpected strong connections between the geophysical processes in Earth's deep interior, the surface redox budget, and biogeochemical cycling.' Analyzing data stretching back to the Cambrian some 541 million years ago, the researchers found that the rise in Earth's magnetic field and the rise in its oxygen levels were very closely aligned—slowly increasing overtime, except for one bout of increased activity lasting from 330 million to 220 million years ago. To map this comparison over the course of hundreds of millions of years, the researchers couldn't rely on direct data—there is no such record for atmospheric oxygen levels, for example. However, they could track the strength of wildfires, which show up as charcoal deposits in the geologic record. This would provide a clue, since a stronger, longer-lasting fire means that there was more oxygen in the atmosphere to fuel said fire. To compare this record with Earth's magnetic field history, the team analyzed certain magnetic crystals that formed in ancient volcanoes and—due to their composition—essentially act like a 'compass frozen in time,' according to Nature. Once plotted side-by-side, the team noticed that the two processes largely increased in lockstep with one another, and even experienced the same increase 330 million years ago. Interestingly, this coincides with the formation of Pangea, though scientists aren't sure exactly if the formation of the supercontinent is related to the increase or a coincidence, as the data does stretch back far enough to compare levels to other supercontinents in Earth's history. So, what's going on here? Well, the researchers aren't exactly sure, but they have a few guesses. The most likely one is that Earth's magnetic field directly impacts oxygen levels, as it protects Earth (and oxygen-producing plants) from solar radiation. However, it's also possible that increased oxygenation coupled with plate tectonics—which drive oxygen toward the liquid outer core that produces the magnetic field—could also play a role. The authors also aren't ruling out the idea that a third, currently unknown mechanism could provide an explanation for this steadily upward trend. 'One single mind cannot comprehend the whole system of the Earth,' Ravi Kopparapu, a co-author of the study from NASA, told Live Science. 'We're like kids playing with Legos, with each of us having a separate Lego piece. We're trying to fit all of it together and see what's the big picture.' While 540 million years is an unfathomably long time compared to our human lifespan (or even our species' existence), it's only around 12 percent of Earth's entire existence, so these trends could simply be coincidental. All we can do is continue searching for answers among the clues that we do have, and try to grasp just how wondrous our home planet really is. You Might Also Like The Do's and Don'ts of Using Painter's Tape The Best Portable BBQ Grills for Cooking Anywhere Can a Smart Watch Prolong Your Life?

Yahoo

a day ago

• Yahoo

Summer solstice 2025: 1st day of summer is here

Get ready for sun-soaked days and warmer weather, as the summer solstice 2025 is just around the corner. This year, the summer solstice falls on Friday, June 20. The astronomical event marks the official start of summer and the beginning of an extended period of daylight in the northern hemisphere as we transition out of the darker, colder months. The solstice occurs twice a year when one of Earth's poles reaches its maximum tilt toward the sun, according to NASA. The word "solstice" comes from the Latin solstitium, meaning "sun stands still," referring to the moment when the sun's apparent path pauses before reversing direction, according to Royal Museums Greenwich. Across the globe, cultures have long celebrated the summer solstice with unique traditions from watching the sunrise align with Stonehenge in England to dancing around maypoles in Sweden and lighting bonfires in Norway. Here's everything you need to know about the 2025 summer solstice. The 2025 summer solstice falls on Friday, June 20, at 10:42 p.m. ET, according to NASA and the Old Farmer's Almanac. This marks the longest day of the year in the northern hemisphere, when the Earth's tilt positions it closest to the Sun. June's full strawberry moon: See photos and what it means for your zodiac "The situation is reversed for the southern hemisphere, where it's the shortest day of the year," NASA states. The summer solstice occurs at the point in Earth's orbit when the sun shines most directly on the northern hemisphere, according to NASA. "Astronomers consider this the beginning of the Summer in the northern hemisphere," NASA states. While it marks the start of summer in the north, the event marks the winter solstice in the southern hemisphere, where sunlight is at its lowest angle. The longest day of the year in 2025 will occur on Friday, June 20, for those in the northern hemisphere. On this day, the sun reaches its highest point in the sky, resulting in the most daylight hours of the year. NASA notes this happens when "the sun is directly over the Tropic of Cancer," located at 23.5 degrees north latitude. Yes, astronomers recognize the summer solstice as the official first day of summer in the northern hemisphere, according to NASA. The National Centers for Environmental Information explains that solstices and equinoxes mark the start of the astronomical seasons. These events occur when the sun reaches its most extreme position relative to the equator, either directly overhead or crossing it. Meteorological seasons split the year into three-month groups based on temperature cycles and "are more closely tied to our monthly civil calendar than the astronomical seasons are," according to the agency. According to the Old Farmer's Almanac, the summer solstice doesn't always occur on the same date. It can fall on June 20, 21, or 22, depending on the year. This is because the timing of the solstice isn't tied to a fixed calendar date. Instead, it's determined by the exact moment the sun reaches its northernmost point from the celestial equator during Earth's orbit. On the day of the summer solstice, the sun reaches its highest point in the sky at noon, and its position changes very little for several days before and after, according to the National Weather Service. This results in the longest day of the year and the shortest night. While the term "longest day" doesn't refer to the number of hours in the day, it does mean the day with the most sunlight.