Snuggling up to our galaxy\u2019s supermassive black hole<\/h3>\n
For years, astronomers have been keeping a close eye on the supermassive black hole at the center of our Milky Way galaxy, named Sagittarius A* (pronounced Sagittarius A-star), or Sgr A* for short.<\/p>\n
It\u2019s long been thought that objects in extremely close proximity to this supermassive black hole would be pulled into its powerful gravitational well. For example, a sunlike star closer than the distance of Mercury\u2019s orbit around our sun \u2014 far less than Earth\u2019s distance from the sun \u2014 would be swallowed by the black hole and ultimately torn apart. Now scientists from the University of Cologne have performed a new study on some of the closest objects we know, in orbit around Sgr A*. They pointed out on November 28, 2025, that these objects, though close to the supermassive black hole, aren\u2019t close enough to be shredded by its powerful gravity. Plus, they now believe the most famous of these objects \u2013 called G2 \u2013 isn\u2019t a dust cloud, as originally thought. Instead, G2 is likely more starlike, perhaps with dusty outer layers.<\/p>\n
So they found that orbiting close to a black hole is not a death sentence. Instead, if objects are far enough away, they can maintain stable orbits around a supermassive black hole.<\/p>\n
The international team of astronomers, led by Florian Peissker at the University of Cologne, published its peer-reviewed paper in the December 2025 issue of Astronomy and Astrophysics<\/em>.<\/p>\n The astronomers used the Enhanced Resolution Imager and Spectrograph (ERIS) at the Very Large Telescope (VLT) facility in Chile to monitor activity around Sagittarius A*. They focused on a few objects in particular, all belonging to what they call the \u201cS-cluster,\u201d a dense group of young, high-velocity stars orbiting Sgr A*.<\/p>\n One object they studied was G2, which astronomers had long suspected was a large gas and dust cloud. G2 made headlines about a decade ago when it survived its closest passage by the supermassive black hole and continued on its elliptical orbit. It came within about 163 AU \u2014 about 100 to 200 times the Earth-Sun distance \u2014 from Sgr A*. These observations, and more since, indicate a star inside a dust cloud.<\/p>\n The team also looked at D9, a binary star system discovered in 2024. Despite its proximity to the violent tidal forces of the nearby black hole, D9 remains in a stable orbit. The inner binary \u2014 two stars orbiting each other with a separation of ~1.6 AU and period ~372 days \u2014 remains tightly bound to each other, easily resisting tidal forces from Sgr?A*. Thus, although D9 is \u201cclose\u201d to Sgr A* in the sense of being within the dense star cluster at the galactic center, it\u2019s far outside the zone of destruction.<\/p>\n What\u2019s more, the nearby gravitational force from Sgr A* hasn\u2019t nudged the D9 stars into colliding and forming one massive star.<\/p>\n In addition, the team monitored stellar objects X3 and X7. These stars also have more stable orbits than previous models predicted.<\/p>\n The following is a table of some of the closest known \u201cS-cluster,\u201d stars \/ binaries with their periapse distances (a periapsis is the point in an orbit where a celestial body is closest to the central body it is orbiting).<\/p>\n Lead author Peissker said:<\/p>\n The fact that these objects move in such a stable manner so close to a black hole is fascinating. Our results show that Sagittarius A* is less destructive than was previously thought. This makes the center of our galaxy an ideal laboratory for studying the interactions between black holes and stars.<\/p>\n<\/blockquote>\n Co-author Michal Zajacek from Masaryk University in Brno, the Czech Republic, added:<\/p>\n The supermassive black hole at the center of the Milky Way has not only the capability to destroy stars, but it can also stimulate their formation or the formation of pretty exotic dusty objects, most likely via mergers of stellar binaries.<\/p>\n<\/blockquote>\n The astronomers plan to make more observations with ERIS and the upcoming Extremely Large Telescope. They hope to track the evolution of these objects and understand how stars survive in such close proximity to a supermassive black hole.<\/p>\n To give a sense of the extreme danger near Sgr A*, Naoufal Souitat of the Southwest Research Institute calculated that an object skimming just a million miles above the black hole\u2019s event horizon would need to travel nearly 600,000 miles per hour to avoid being pulled in. That\u2019s only slightly faster than the Sun\u2019s orbit around the Milky Way. In reality, the objects studied, like G2 and the binary D9, stay thousands of times farther out \u2014 tens to thousands of astronomical units away \u2014 safely beyond the black hole\u2019s \u201cdeath zone.\u201d Their survival shows that proximity to a supermassive black hole does not automatically mean destruction; stars and star-like systems can maintain stable, enduring orbits even in the heart of our galaxy.<\/p>\n Bottom line: Scientists studied stars in the \u201cS-cluster,\u201d a dense group of young, high-velocity stars orbiting our galaxy\u2019s central supermassive black hole. They found these stars in stable orbits.<\/p>\n Source: Closing the gap: Follow-up observations of peculiar dusty objects close to Sgr A* using ERIS<\/p>\n Via University of Cologne<\/p>\n <\/div>\nHow close to Sagittarius A*?<\/h3>\n
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Violence versus stability<\/h3>\n
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How close to a supermassive black hole is safe?<\/h3>\n
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