by John Davis
Unique SOS Signal from Pulled-Apart Star Points to Medium-Sized Black Hole
Video depicts rare look at white dwarf being stretched and consumed by black hole.
Using NASA’s space telescope Chandra, a team of international astronomers believe they have captured X-ray activity depicting a small star being pulled apart by a medium-sized black hole from the edge of galaxy Messier 86.
Meet the Expert
Tom Maccarone is an associate professor in the Department of Physics in the College of Arts and Sciences.
An international team of astronomers, including Texas Tech University’s Tom Maccarone, believe they have observed a rare cosmic accident in which a small star is pulled apart by a medium-sized black hole.
The scientists used NASA’s space telescope Chandra to detect unusual X-ray activity that, after being analyzed, turned out most likely to be somewhat of a distress call from the pulled-apart star.
“This is the first time anybody has seen anything like this,” Maccarone said. “But it’s still an open question: Is this something extremely rare or are there more events like this happening all the time? Either way, evidence of intermediate-sized black holes, if this interpretation of the data can be confirmed, is a tremendous discovery.”
The X-ray signals captured on the edge of nearby galaxy Messier 86 initially revealed two small emissions with a pause of 4,000 seconds in between. Another 4,000 seconds later the quantity of X-ray radiation suddenly increased by a factor of 100 and then gradually decreased again. The activity was very similar to the signal predicted for a medium-sized member of the black holes family, which pulls apart a so-called white dwarf (the remnants of a star, like Earth’s sun).
This intermediate size would, therefore, be far heavier than the black holes that arise from supernova explosions in the present-day universe–those black holes are about 10 times as heavy as the sun. At the same time, the medium-sized black holes are far smaller than the black holes at the core of galaxies, which are 1 million to 1 billion times heavier than the sun. Both of these are regularly observed, whereas a medium-sized black hole is not.
The timescale of 4,000 seconds concurs with the time needed for the material from the star being pulled apart to rotate once around the black hole, as long as the black hole is about 10,000 times as heavy as the sun. These medium-sized black holes could have arisen early in the history of the universe from the first generation of supernovae. The space around galaxies should, therefore, be full of these, but up until now there was very limited evidence for the presence of this intermediate-type black hole.
The team of astronomers, led by Peter Jonker (Space Research Organization of the Netherlands), seems to have provided the missing evidence. The research results were published in the The Astrophysical Journal.
“This is probably the tip of the iceberg because we have found more of this strange type of X-ray flash,” Jonker said. “Aidan Glennie, a doctoral student at Oxford, is working with me on a study of two comparable signals from different galaxies. As the chances of such a black hole capturing a star and pulling it apart is very small, this means that there are probably many medium-sized black holes.”
If more medium-sized black holes are found, Jonker says that would make it more plausible that super-heavy black holes evolved from the merging of medium-sized black holes. The presence of super-heavy black holes in the early universe, in particular, is difficult to explain if there are no medium-sized black holes.
The astronomers also hope it will be possible to observe the merging process in the near future with the improved LIGO and Virgo facilities, and the e-LISA space facility. Astronomers hope to use these to measure the gravity waves transmitted by two merging medium-sized black holes.
The Department of Physics in the College of Arts & Sciences is active in a broad range of research and teaching activities designed to prepare undergraduates for challenging careers in science, education and technology. Graduates of the department have gone on to successful careers at universities, national laboratories and in industry.
The department offers the Bachelor of Science in physics with four concentrations: astrophysics, applied physics, professional concentration, and secondary education. In cooperation with the College of Engineering, the department also offers courses leading to the Bachelor of Science in engineering physics.
John Davis is a Senior Writer in the Office of Communications & Marketing at Texas Tech University.