Researchers from the University of Turku in Finland found that the rotation axis of a[{”attribute=””>blackholeinabinarysystemistiltedmorethan40degreesrelativetotheaxisofstellarorbitThefindingchallengescurrenttheoreticalmodelsofblackholeformation[{”attribute=””>blackholeinabinarysystemistiltedmorethan40degreesrelativetotheaxisofstellarorbitThefindingchallengescurrenttheoreticalmodelsofblackholeformation
The observation by the researchers from Tuorla Observatory in Finland is the first reliable measurement that shows a large difference between the axis of rotation of a black hole and the axis of a binary system orbit. The difference between the axes measured by the researchers in a binary star system called MAXI J1820+070 was more than 40 degrees.
Often for the space systems with smaller objects orbiting around the central massive body, the own rotation axis of this body is to a high degree aligned with the rotation axis of its satellites. This is true also for our solar system: the planets orbit around the Sun in a plane, which roughly coincides with the equatorial plane of the Sun. The inclination of the Sun rotation axis with respect to orbital axis of the Earth is only seven degrees.
“The expectation of alignment, to a large degree, does not hold for the bizarre objects such as black hole X-ray binaries. The black holes in these systems were formed as a result of a cosmic cataclysm – the collapse of a massive star. Now we see the black hole dragging matter from the nearby, lighter companion star orbiting around it. We see bright optical and X-ray radiation as the last sigh of the infalling material, and also radio emission from the relativistic jets expelled from the system,” says Juri Poutanen, Professor of Astronomy at the University of Turku and the lead author of the publication.
https://www.youtube.com/watch؟v=WfapWdqWYIo
An artist’s impression of the X-ray binary system MAXI J1820 + 070 that contains a black hole (a small black point in the center of the gaseous disk) and a companion star. A narrow jet is directed along the axis of rotation of the black hole, which is strongly skewed from the axis of rotation of the orbit. The picture was produced with a breeze. Credit: R. Hynes
By following these jets, the researchers were able to determine the direction of the black hole’s rotation axis very precisely. When the amount of gas falling from the companion star into the black hole later began to decrease, the temperature of the system cooled, and a large portion of the light in the system came from the companion star. In this way, the researchers were able to measure the inclination of the orbit using spectroscopic techniques, and this roughly coincided with the inclination of the ballistics.
“To determine the 3D orientation of the orbit, one also needs to know the angle of the system’s position in the sky, which means how the system rotates with respect to the direction north in the sky. This was measured using polarimetry techniques,” says Juri Potanin.
The results published in Science open interesting prospects towards studies of the formation of black holes and the evolution of such systems, since it is difficult to obtain such severe disequilibrium in many scenarios of black hole formation and binary evolution.
The difference of more than 40 degrees between the orbital axis and the rotation of the black hole was completely unexpected. Scientists often assumed that this difference was very small when they modeled the behavior of matter in a curved timespace around a black hole. Existing models are already complex, and now the new findings are forcing us to add a new dimension to it,” says Potanin.
Reference: “Orbit-orbit black hole rotation imbalance in X-ray binary MAXI J1820+070” by Guri Potanin, Alexandra Veledina, Andrei V Berdyugina, Svetlana V Berdyugina, Helen Germak, Peter J. Juncker, Gary J. E. Kagava, Ilya Kozenkov, Vadim Kravtsov Filippo Perola, Manisha Shrestha, Manuel A. Perez-Torres, and Serge S. Tsygankov, Feb 24, 2022 Available here. to know.
DOI: 10.1126 / science.abl4679
The main discovery was made using the in-house built DIPol-UF polarimeter installed at the Northern Optical Telescope, jointly owned by the University of Turku with
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