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The Royal Astronomical Society published this original story on February 5, 2026. Edits by EarthSky.<\/p>\n
Our Milky Way galaxy might not have a supermassive black hole at its center, after all. Instead, the galaxy\u2019s heart\u00a0might contain an enormous clump of mysterious dark matter. If it\u2019s true, this dark matter would exert the same gravitational influence as a black hole, astronomers said on February 5, 2026.<\/p>\n
They said they believe dark matter at the Milky Way\u2019s core can explain both the blistering speeds of stars just light-hours from the core. Plus dark matter can explain the large-scale rotation of the galaxy as a whole.<\/p>\n
The peer-reviewed Monthly Notices of the Royal Astronomical Society<\/em> published the new study on February 5, 2026.<\/p>\n The new study challenges the leading theory that Sagittarius A* \u2013 a proposed black hole at the heart of our galaxy \u2013 is responsible for the observed orbits of a group of stars, known as the S-stars. These stars whip around at tremendous speeds of up to a few thousand kilometers per second.<\/p>\n The international team of researchers have instead put forward an alternative idea: that a specific type of dark matter made up of fermions, or light subatomic particles, can create a unique cosmic structure that also fits with what we know about the Milky Way\u2019s core.<\/p>\n It would in theory produce a super-dense, compact core surrounded by a vast, diffuse halo. These, together, would act as a single, unified entity.<\/p>\n The inner core would be so compact and massive that it could mimic the gravitational pull of a black hole. It would also explain the orbits of S-stars that have been observed in previous studies, as well as the orbits of the dust-shrouded objects known as G-sources, which also exist nearby.<\/p>\n Of particular importance to the new research are the latest data from the European Space Agency\u2019s GAIA DR3 mission. This mission has meticulously mapped the rotation curve of the Milky Way\u2019s outer halo, showing how stars and gas orbit far from the center.<\/p>\n It observed a slowdown of our galaxy\u2019s rotation curve, known as the Keplerian decline. Researchers say this can be explained by their dark matter model\u2019s outer halo when combined with the traditional disk and bulge mass components of ordinary matter.<\/p>\n This, they add, strengthens the \u2018fermionic\u2019 model by highlighting a key structural difference. While traditional Cold Dark Matter halos spread out following an extended \u2018power law\u2019 tail, the fermionic model predicts a tighter structure, leading to more compact halo tails.<\/p>\n The research has been carried out by an international collaboration involving the Institute of Astrophysics La Plata in Argentina, International Centre for Relativistic Astrophysics Network and National Institute for Astrophysics in Italy, Relativity and Gravitation Research Group in Colombia and Institute of Physics University of Cologne in Germany.<\/p>\n Co-author Carlos Arg\u00fcelles, of the Institute of Astrophysics La Plata, said:<\/p>\n This is the first time a dark matter model has successfully bridged these vastly different scales and various object orbits, including modern rotation curve and central stars data.<\/p>\n We are not just replacing the black hole with a dark object; we are proposing that the supermassive central object and the galaxy\u2019s dark matter halo are two manifestations of the same, continuous substance.<\/p>\n<\/blockquote>\n Crucially, this fermionic dark matter model had already passed a significant test. A previous study by Pelle et al. (2024), also published in MNRAS, showed that when an accretion disk illuminates these dense dark matter cores, they cast a shadow-like feature strikingly similar to the one imaged by the Event Horizon Telescope collaboration for Sagittarius A*.<\/p>\n Lead author Valentina Crespi, of the Institute of Astrophysics La Plata, said:<\/p>\n This is a pivotal point. Our model not only explains the orbits of stars and the galaxy\u2019s rotation but is also consistent with the famous \u2018black hole shadow\u2019 image. The dense dark matter core can mimic the shadow because it bends light so strongly, creating a central darkness surrounded by a bright ring.<\/p>\n<\/blockquote>\n The researchers statistically compared their fermionic dark matter model to the traditional black hole model.<\/p>\n They found that while current data for the inner stars cannot yet decisively distinguish between the two scenarios, the dark matter model provides a unified framework that explains the galactic center (central stars and shadow), and the galaxy at large.<\/p>\n The new study paves the way for future observations. More precise data from instruments such as the GRAVITY interferometer, on the Very Large Telescope in Chile, and the search for the unique signature of photon rings \u2013 a key feature of black holes and absent in the dark matter core scenario \u2013 will be crucial to test the predictions of this new model, the authors say.<\/p>\n The outcome of these findings could potentially reshape our understanding of the fundamental nature of the cosmic behemoth at the heart of the Milky Way.<\/p>\n Bottom line: A new study suggests a dark matter core, and not a supermassive black hole, lies at the center of our Milky Way galaxy. The new theory also helps explain the galaxy\u2019s dark matter halo.<\/p>\n Source: The dynamics of S-stars and G-sources orbiting a supermassive compact object made of fermionic dark matter<\/p>\n Via Royal Astronomical Society<\/p>\n<\/div>\nNo supermassive black hole at the heart of our galaxy?<\/h3>\n
Data from GAIA<\/h3>\n
A dense core of dark matter plus halo<\/h3>\n
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New model fits with the famous \u2018black hole\u2019 image<\/h3>\n
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What\u2019s next for the dark matter core model?<\/h3>\n