Behold, the Black Hole on the Center of Our Galaxy

We dwell within the internal rim of one of many Milky Way’s spiral arms, a shimmery curve towards inky darkness. Travel for hundreds of light-years in a single route, previous numerous stars, numerous planets, and numerous moons, and also you’d attain the outer fringe of the Milky Way, the place the final bits of our galaxy give approach to the sprawling stillness of the intergalactic medium. Travel about the identical distance within the different route, previous nonetheless extra stars and planets and moons, by means of glittering clouds of mud, and also you’ll find yourself within the coronary heart of the galaxy, at one of the mysterious landmarks within the universe.

For the primary time in human historical past, you don’t need to think about it. Using telescopes highly effective sufficient to stretch our notion throughout unfathomable distances, astronomers have made a cosmic postcard: the first-ever image of the supermassive black gap on the middle of the Milky Way.

Behold Sagittarius A* (pronounced “A-star”), a celestial object that has the mass of 4 million suns however may match comfortably inside the orbit of Mercury, the closest planet to the solar.

The picture comes from observations made by a community of radio telescopes spanning 4 continents, as a part of a venture known as the Event Horizon Telescope. This is just the second time that astronomers on this effort have captured considered one of these objects in such element. The first picture, of the supermassive black gap on the middle of the close by galaxy Messier 87, or M87 for brief, was launched in 2019 with nice fanfare. Einstein had predicted the existence of black holes—unseen factors within the void the place gravity warps the very material of area—greater than a century earlier, and right here, finally, was photographic proof of 1. That picture marked an incredible achievement within the discipline of science. But this one, of Sagittarius A*, feels slightly totally different, extra particular. Astronomers consider that supermassive black holes are on the middle of most large galaxies, which implies that the universe is stuffed with these objects. But this one is the closest to us. This one is ours.

“I don’t think I ever had an emotional attachment to M87,” Feryal Özel, an astrophysicist at the University of Arizona who works on the Event Horizon Telescope, told me. Özel has spent most of her career studying Sagittarius A*, trying to understand its distinct nature and quirks. This one, she said, “I feel like I know.”

And still, we are not truly seeing Sagittarius A*, not really. Astronomers can’t take a real picture—in the way us non-astronomers would consider it—because black holes are, by definition, invisible. So the photo released today doesn’t show the black hole itself. Astronomers have captured Sagittarius A* in silhouette. The image reveals the shadow that the immensely dense black hole casts against the glowing cosmic gas swirling around it. Like the black hole in M87, Sagittarius A* resembles a donut. In fact, it bears an uncanny resemblance to the cherry and cheese danishes served at the press conference that astronomers held in Washington, D.C. to reveal the result.

Astronomers made the observations that produced this image in the spring of 2017. Eight ground-based telescopes—two each in Hawaii and Chile, and one each in Arizona, Mexico, Spain, and Antarctica—scanned the skies in tandem for several days. The observations, stored on hundreds of computer disk drives, were then shipped to labs in the United States and Germany, where scientists pored over the data like archaeologists at a dig site, brushing away the noise to excavate the signal of a supermassive black hole. They had followed a similar process to reveal M87’s black hole, which was observed during the same run in 2017.

But drawing out Sagittarius A* was far more difficult. The supermassive black hole in M87 is 1,500 times more massive than Sagittarius A*, which means that the cosmic material around it orbits rather slowly, flickering on the timescale of days. The stuff around the smaller Sagittarius A* moves faster, changing within hours or even minutes, which makes the environment more challenging to capture, Özel told me. On top of that, although Sagittarius A* is only 27,000 light-years from Earth—and “only” is quite appropriate when you consider that the black hole in M87 is 55 million light-years from Earth—our supermassive black hole is harder to see. “We’re looking through everything that is between us and the center of the galaxy, whereas for M87, we’re looking out and away from the Milky Way,” Özel said. All the cosmic stuff between us and the galactic center can cause the light coming from the galactic center to appear distorted in the data. “We had to really understand this effect and subtract it from our images correctly,” Özel said.

The new image is further proof that the supermassive black hole at the center of the galaxy is, well, exactly that. Einstein published the theories that predicted the existence of such objects in 1916, but the first real observation campaigns didn’t begin until the 1970s. In that decade, astronomers detected a mysterious, compact source of radio emissions in the galactic center that seemed like it could be a black hole, “but not many people believed us then,” Reinhard Genzel, an astrophysicist at the Max Planck Institute for Extraterrestrial Physics who studies Sagittarius A* but was not involved in the latest research, told me. It would take decades of additional research to show that there’s no other explanation for the mysterious object at the Milky Way’s core. In recent years, teams led by Genzel and the UCLA astrophysicist Andrea Ghez have captured in great detail some of the stars closest to the black hole, which, from our perspective, appear to swing wildly around an invisible point in space. In 2020, Genzel and Ghez shared the Nobel Prize in physics for providing the most convincing evidence for the existence of the Milky Way’s central black hole.

And the galactic center, researchers have learned, is a weird place. They were surprised to discover, for example, that most of the stars clustered near Sagittarius A* are young rather than old, a discovery that goes against everything astronomers understand about star formation. “That means that the stars must have been formed very close to the black hole,” Tuan Do, an astrophysicist at UCLA who studies the galactic center, told me. But Sagittarius A* “creates enormous amounts of gravity in this region, so gas clouds that form stars should be ripped apart in this region.” Perhaps long ago, tens of millions of years in the past, the black hole was ringed by a swirling disk of gas that rotated so fast that pockets of it ignited into stars. That environment is gone today; Sagittarius A*, as far as supermassive black holes go, is considered to be relatively quiet.

Quiet does not mean boring. Although Einstein’s theories led to the discovery of black holes, scientists still don’t know whether the rules of gravity as we understand them apply in such extreme, unknowable conditions. The 2019 result showed that the shadow of an event horizon is, as predicted, spherical. But “our best theories still are falling short,” Ghez told me. “Black holes represent that fundamental breakdown in our understanding of how gravity works,” she said. Sagittarius A* is stretching some nearby celestial objects like taffy, as black holes are wont to do, but those objects are hundreds of times bigger than models predict. And scientists are still a long way from understanding what transpires in the interior of a black hole, beyond that point of no return.

Even in this very strange part of our cosmic neighborhood, some evidence suggests, stars could host planets, worlds shaped by the distinct chaos of their environment. “We do see binary star systems at the galactic center, which means two stars are able to stay bound together, despite the strong tidal forces of the black hole and the chaotic environment,” Jessica Lu, an astrophysicist at UC Berkeley who studies star formation in the galactic center, told me. “So perhaps planets can form and survive as well.” At the galactic center, the few, empty light-years separating our sun from its nearest stellar neighbor would be brimming with stars. And in a night sky at the center of the Milky Way, those stars would appear as bright as full moons. “We could visit them in reasonable amounts of time, and our star might be in danger of being hit by another star,” Do said. “We’d probably all be astronomers, because we’d care way more about what’s happening in the sky.”

For Ghez, the brand new image of Sagittarius A* is a crucial contribution to astrophysics. That’s her reply when she’s considering like a scientist. When she takes a second to contemplate the work in one other, extra sentimental means, she appreciates “the fact that we as humans, that are so finite and small, can have this understanding of things that are so immense.” And not solely that, however to really feel some form of kinship with it. “I love to talk about our galaxy, as opposed to the Milky Way,” she stated. “It’s our home.”

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