An international team of astronomers has undertaken a groundbreaking search for an intermediate-mass black hole within the globular star cluster Omega Centauri. These elusive black holes, which are neither as massive as supermassive ones found in galactic centers nor as lightweight as others, represent a significant gap in our understanding of black hole formation and evolution.
Using over 500 images from NASA’s Hubble Space Telescope collected over two decades, the team meticulously tracked the movements of seven rapidly moving stars in the cluster’s core. Their findings aim to shed light on the presence and nature of intermediate-mass black holes, crucial for advancing our comprehension of cosmic phenomena.
Omega Centauri, with its approximately 10 million gravitationally bound stars, has provided astronomers with compelling new evidence suggesting the presence of an intermediate-mass black hole exerting gravitational influence on these stellar bodies. This finding is significant as only a handful of other candidates for intermediate-mass black holes have been identified thus far. Scientists are particularly intrigued by such discoveries within Omega Centauri, a cluster ten times more massive than other large globular clusters and nearly as massive as a small galaxy.
Among the myriad questions raised by these observations: How prevalent are intermediate-mass black holes, and do they play a role in the formation of supermassive black holes? How do these intermediate-mass black holes come into existence, and do dense star clusters like Omega Centauri serve as their preferred habitats? Leveraging data from over 1.4 million stars within Omega Centauri, meticulously compiled from two decades of Hubble Space Telescope images initially intended for instrument calibration, astronomers have crafted an extensive catalog that serves as a cornerstone for their ongoing investigations.
Maximilian Häberle from the Max Planck Institute for Astronomy in Germany, leading the investigation, highlighted the discovery of seven unusually fast-moving stars within Omega Centauri. According to Häberle, these stars exhibit velocities so high that they would typically escape the cluster’s gravitational pull and not return. This behavior strongly suggests the presence of an exceptionally massive object, likely a black hole, exerting gravitational influence to retain them near the cluster’s center. Based on their calculations, this black hole would need to have a mass of at least 8,200 times that of our Sun.
Previous studies have proposed the existence of an intermediate-mass black hole (IMBH) in Omega Centauri. However, alternative research suggested that the cluster’s mass might be attributed to a central concentration of stellar-mass black holes instead. These studies argued that the absence of fast-moving stars exceeding the escape velocity made an IMBH scenario less plausible in comparison.
This discovery represents the most direct evidence yet of an intermediate-mass black hole (IMBH) in Omega Centauri, remarked Nadine Neumayer, team lead from the Max Planck Institute for Astronomy in Germany, who initiated the study alongside Anil Seth from the University of Utah, Salt Lake City. This finding is particularly exciting because there are very few other black holes known with a similar mass. The black hole in Omega Centauri could be the prime example of an IMBH in our cosmic vicinity. Located at a distance of 17,700 light-years from Earth, if confirmed, this candidate black hole would be closer to us than the 4.3-million-solar-mass black hole at the center of the Milky Way, which is situated 26,000 light-years away.
Omega Centauri, visible to the naked eye from Earth’s southern hemisphere, is a favorite among stargazers. Positioned just above the Milky Way’s plane, the cluster appears nearly as large as the full Moon under optimal viewing conditions in dark rural areas. Originally cataloged as a single star by Ptolemy nearly 2,000 years ago and later recognized as a nebula by Edmond Halley in 1677, it was identified as a globular cluster by the English astronomer John Herschel in the 1830s. The discovery paper led by Häberle et al. has been published online today in the journal Nature.