
A strange object about 40,000 light years away is either the heaviest neutron star or the lightest black hole we have ever seen, sitting in a mysterious void of objects that astronomers have never directly observed.
A neutron star forms when a star has run out of fuel and collapses under its gravity, creating a shockwave called a supernova and leaving an ultra-dense core behind. According to astrophysical calculations, these cores must remain below a certain mass, around 2.2 times the mass of the sun, or they will collapse even further, creating a black hole.
However, black holes have only been observed with a mass more than five times that of the sun, leaving a gap in scale between neutron stars and black holes. There have been some dense objects observed in this gap by gravitational wave observatories, but astronomers have never spotted them with conventional telescopes.
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Now, at the Max Planck Institute for Radio Astronomy in Germany and his colleagues have spotted an object of 2.5 solar masses by observing a pulsar that orbits it. A pulsar is a neutron star that spits out pulses of light at regular millisecond intervals due to an intense magnetic field.
Pulsars emit light with extreme regularity, but very massive nearby objects can warp these rhythms, as predicted by Albert Einstein鈥檚 theory of relativity. By observing the pulsar鈥檚 pulses for more than a year using the MeerKAT radio telescope in South Africa, Barr and his team were able to calculate the mass of the pulsar鈥檚 partner.
鈥淲hat we found in this binary system looks to be above that [upper limit for neutron star mass], which would suggest that either some new physics is going on here and this is a new kind of star, or it鈥檚 just simply a black hole and it鈥檚 the lightest stellar mass black hole found like this,鈥 says Barr.
The pulsar is located in a globular cluster, a region of tightly packed stars and more exotic objects that can pass close to each other. These unusual interactions could explain the mysterious object, says Barr.
If it is a black hole, it will let researchers test theories of gravity that they couldn鈥檛 previously. 鈥淭he pulsar is just this ludicrously precise measurement device that you鈥檝e got in orbit around the black hole and it鈥檚 not going anywhere; it鈥檚 going to be there for the next billion years,鈥 says Barr. 鈥淪o it鈥檚 this incredibly stable, natural testbed for looking at black hole physics.鈥
鈥淚f it鈥檚 a neutron star, then it鈥檚 heavier than any neutron star we鈥檝e seen,鈥 says at the University of Durham, UK. 鈥淭hat actually tells us about the ultimate densities that stars can support before they collapse under their own gravity and become black holes. We don鈥檛 know the physics of matter at these extreme densities; we don鈥檛 know what that limit is.鈥
Barr and his team plan to observe the pulsar with other telescopes over the coming years to look for clues that could reveal what the object is. If it is a black hole, then they should see the pulsar鈥檚 orbit change over time as the black hole drags spacetime around it, similar to how a ship drags smaller boats in its wake. Or, if it is a neutron star, they might be able to detect light with more sensitive instruments.
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