Giant Galaxy Seen In 3D By NASA’s Hubble Space Telescope & Keck Observatory
Though we live in a vast three-dimensional universe, celestial objects seen through a telescope look flat because everything is so far away. Now for the first time, astronomers including Texas A&M University’s Dr. Jonelle Walsh have measured the three-dimensional shape of one of the biggest and closest elliptical galaxies to the Earth, M87 — a galaxy that turns out to be “triaxial,” or potato-shaped.
This stereo vision was made possible by combining the power of NASA’s Hubble Space Telescope and the ground-based W.M. Keck Observatory on Maunakea, Hawaii.
“Using extensive data from a new instrument on the Keck II Telescope, we report the first robust detection of a misaligned rotation in M87 and the first measurement of M87’s intrinsic shape, which shows that M87 is not as symmetric as previously thought,” said Walsh, an assistant professor in the Department of Physics and Astronomy and a member of the Texas A&M’s George P. and Cynthia Woods Mitchell Institute for Fundamental Physics and Astronomy.
In most cases, astronomers must use their intuition to figure out the true shapes of deep-space objects. For example, the whole class of huge galaxies called “ellipticals” look like blobs in pictures. Determining the true shape of giant elliptical galaxies will help astronomers understand better how large galaxies and their central large black holes form and grow together over time.
Scientists made the 3D plot by measuring the motions of stars that swarm around the galaxy’s supermassive central black hole. The stellar motion was used to provide new insights into the shape of the galaxy and its rotation, and it also yielded a new measurement of the black hole’s mass. Tracking the stellar speeds and position allowed researchers to determine the mass of the black hole at the galaxy’s core to a high precision, estimating it at 5.4 billion times the mass of the sun.
Hubble observations in 1995 first measured the M87 black hole as being 2.4 billion solar masses, which astronomers deduced by clocking the speed of the gas swirling around the black hole. When the Event Horizon Telescope, an international collaboration of ground-based telescopes, released the first-ever image of the same black hole in 2019, the size of its pitch-black event horizon allowed researchers to calculate a mass of 6.5 billion solar masses using Einstein’s theory of general relativity.
The stereo model of M87 and the more precise mass of the central black hole could help astrophysicists learn the black hole’s spin rate.
“Now that we know the direction of the net rotation of stars in M87 and have an updated mass of the black hole, we can combine this information with data from the Event Horizon Telescope to constrain the spin,” said Chung-Pei Ma, a UC Berkeley astronomer and an investigator on the research.
Because M87 probably grew from the merger of many other galaxies, that’s the likely reason its central black hole is so large: It assimilated the central black holes of one or more galaxies it swallowed.
Ma, together with UC Berkeley graduate student Emily Liepold (lead author on the paper published in The Astrophysical Journal Letters) and Walsh, who holds the Mitchell-Heep-Munnerlyn Endowed Career Enhancement Professorship in Physics and Astronomy at Texas A&M, were able to determine the 3D shape of M87, thanks to a new precision instrument mounted on the Keck II Telescope. They pointed Keck at 62 adjacent locations of the galaxy, mapping out the spectra of stars over a region about 70,000 light-years across. This region spans the central 3,000 light-years where gravity is largely dominated by the supermassive black hole. Though the telescope cannot resolve individual stars because of M87’s great distance, the spectra can reveal the range of velocities to calculate mass of the object they’re orbiting.
“It’s sort of like looking at a swarm of 100 billion bees,” Ma said. “Though we are looking at them from a distance and can’t discern individual bees, we are getting very detailed information about their collective velocities.”
The researchers took the data between 2020 and 2022, as well as earlier star brightness measurements of M87 from Hubble, and compared them to computer model predictions of how stars move around the center of the triaxial-shaped galaxy. The best fit to this data allowed them to calculate the black hole’s mass.
“Knowing the 3D shape of the ‘swarming bees’ enabled us to obtain a more robust dynamical measurement of the mass of the central black hole that is governing the bees’ orbiting velocities,” Ma said.
In the 1920s, astronomer Edwin Hubble first classified galaxies according to their shapes. Flat disk spiral galaxies could be viewed from various projection angles of the sky: face-on, oblique or edge-on. But the “blobby-looking” galaxies were more problematic to characterize. Hubble came up with the term elliptical. They could only be sorted out by how great the ellipticity was. They didn’t have any apparent dust or gas inside of them for better distinguishing between them. Now, a century later, astronomers have a stereoscopic look at a prototypical elliptical galaxy.
“While there is a 40-year history of dynamical measurements of the M87 black hole, we relaxed assumptions about the galaxy’s intrinsic shape for the first time and obtained a new determination of the black hole’s mass, ” Walsh said. “The work is an important advancement in the modeling of galaxy dynamics for the most massive galaxies in the universe.”
This story was originally published by the Space Telescope Science Institute.
This story source was originally published by Texas A&M Arts & Sciences.