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Sagittarius A*: Telescopes Show the Milky Way's Black Hole is Ready for a Kick
Sagittarius A*
Visual Description:

  • A new study may help settle the question of how rapidly the Milky Way’s supermassive black hole is spinning.

  • The black hole, known as Sagittarius A* (Sgr A*), contains about 4 million times the mass of the Sun.

  • Using NASA’s Chandra X-ray Observatory and NSF’s Very Large Array, this study found Sgr A* is spinning very rapidly.

  • This high spin is warping the spacetime around Sgr A* so it appears to have the shape of an American football.

This artist’s illustration depicts the findings of a new study about the supermassive black hole at the center of our galaxy called Sagittarius A* (abbreviated as Sgr A*). As reported in our latest press release, this result found that Sgr A* is spinning so quickly that it is warping spacetime — that is, time and the three dimensions of space — so that it can look more like an American football.

These results were made with NASA’s Chandra X-ray Observatory and the NSF’s Karl G. Jansky Very Large Array (VLA). A team of researchers applied a new method that uses X-ray and radio data to determine how quickly Sgr A* is spinning based on how material is flowing towards and away from the black hole. They found Sgr A* is spinning with an angular velocity that is about 60% of the maximum possible value, and with an angular momentum of about 90% of the maximum possible value.

Black holes have two fundamental properties: their mass (how much they weigh) and their spin (how quickly they rotate). Determining either of these two values tells scientists a great deal about any black hole and how it behaves. In the past, astronomers made several other estimates of Sgr A*’s rotation speed using different techniques, with results ranging from Sgr A* not spinning at all to it spinning at almost the maximum rate.

The new study suggests that Sgr A* is, in fact, spinning very rapidly, which causes the spacetime around it to be squashed down. The illustration shows a cross-section of Sgr A* and material swirling around it in a disk. The black sphere in the center represents the so-called event horizon of the black hole, the point of no return from which nothing, not even light, can escape.

Looking at the spinning black hole from the side, as depicted in this illustration, the surrounding spacetime is shaped like an American football. The faster the spin the flatter the football.

The yellow-orange material to either side represents gas swirling around Sgr A*. This material inevitably plunges towards the black hole and crosses the event horizon once it falls inside the football shape. The area inside the football shape but outside the event horizon is therefore depicted as a cavity. The blue blobs show jets firing away from the poles of the spinning black hole. Looking down on the black hole from the top, along the barrel of the jet, spacetime is a circular shape.

A black hole’s spin can act as an important source of energy. Spinning supermassive black holes produce collimated outflows such as jets when their spin energy is extracted, which requires that there is at least some matter in the vicinity of the black hole. Because of limited fuel around Sgr A*, this black hole has been relatively quiet in recent millennia with relatively weak jets. This work, however, shows that this could change if the amount of material in the vicinity of Sgr A* increases.

X-ray Image of Sagittarius A* (Labeled)
Chandra X-ray image of Sagittarius A* and the surrounding region. Credit: NASA/CXC/Univ. of Wisconsin/Y.Bai, et al.

To determine the spin of Sgr A*, the authors used an empirically based technique referred to as the “outflow method” that details the relationship between the spin of the black hole and its mass, the properties of the matter near the black hole, and the outflow properties. The collimated outflow produces the radio waves, while the disk of gas surrounding the black hole is responsible for the X-ray emission. Using this method, the researchers combined data from Chandra and the VLA with an independent estimate of the black hole’s mass from other telescopes to constrain the black hole’s spin.

The paper describing these results led by Ruth Daly (Penn State University) is published in the January 2024 issue of the Monthly Notices of the Royal Astronomical Society and appears online at https://ui.adsabs.harvard.edu/abs/2024MNRAS.527..428D/abstract. The other authors are Biny Sebastian (University of Manitoba, Canada), Megan Donahue (Michigan State University), Christopher O’Dea (University of Manitoba), Daryl Haggard (McGill University) and Anan Lu (McGill University).

NASA's Marshall Space Flight Center manages the Chandra program. The Smithsonian Astrophysical Observatory's Chandra X-ray Center controls science operations from Cambridge, Massachusetts, and flight operations from Burlington, Massachusetts.

 

Visual Description:

This artist's illustration shows a cross-section of Sagittarius A*, pronounced as "SAJ-ee-TARE-ee-us A-star", the supermassive black hole near the center of our Milky Way galaxy.

In the middle of the image, the spinning, circular black hole is presented from the side in black. The swirling gas that surrounds Sagittarius A* is presented in white and yellow on either side of the black hole, within a rectangular-shaped dotted line, indicating the representation is a cross-section view. The shape of the spacetime surrounding Sgr A*, seen as the inner edge of the white and yellow gas on either side of the black hole, has been squashed down. The spacetime around Sgr A* thus resembles the shape of an American football.

The background of the image contains a multitude of faint stars, peeking out from within brooding, dark red, indistinct clouds.

 

Fast Facts for Sagittarius A*:
Credit  NASA/CXC/M. Weiss
Release Date  February 8, 2024
Category  Black Holes, Milky Way Galaxy
Coordinates (J2000)  RA 17h 45m 40.125s | Dec -29° 00´ 28.24"
Constellation  Sagittarius
Instrument  ACIS
Also Known As Galactic Center
References Daly, R. et al., 2024, MNRAS 527, 428–436. arXiv:2310.12108
X-ray
Distance Estimate  About 26,000 light-years
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