This peculiar galaxy has two supermassive black holes at its heart

By Georgina Torbet October 28, 2023

As hard as it is to picture, with billions or even trillions of galaxies in the universe, entire galaxies can collide with each other. When that happens, one galaxy can be destroyed or the two can merge into one. But even in the case of galaxy mergers, the effects of the collision are often visible for billions of years afterward.

That’s shown in a recent image taken by the Gemini South observatory, which shows the chaotic result of a merger between two spiral galaxies 1 billion years ago.

Gemini South, one half of the International Gemini Observatory operated by NSF’s NOIRLab, captures the billion-year-old aftermath of a double spiral galaxy collision. At the heart of this chaotic interaction, entwined and caught in the midst of the chaos, is a pair of supermassive black holes — the closest such pair ever recorded from Earth. — Gemini South, one half of the International Gemini Observatory operated by NSF’s NOIRLab, captures the billion-year-old aftermath of a double spiral galaxy collision. At the heart of this chaotic interaction, entwined and caught in the midst of the chaos, is a pair of supermassive black holes — the closest such pair ever recorded from Earth. International Gemini Observatory/NOIRLab/NSF/AURA; Image processing: T.A. Rector (University of Alaska Anchorage/NSF’s NOIRLab), J. Miller (International Gemini Observatory/NSF’s NOIRLab), M. Rodriguez (International Gemini Observatory/NSF’s NOIRLab), M. Zamani (NSF’s NOIRLab)

The resulting galaxy, called NGC 7727 and located 90 million light-years away, shows the cloudy blobs of dust and gas that now swirl around the galactic core. The stretching arms of the spiral galaxies have been pulled apart by the gravitational forces of the merger, leaving behind an unstructured shape which leads this to be classified as a “peculiar galaxy.” Despite its messy appearance, parts of the newly formed galaxy are ideal locations for the formation of stars as pockets of dust and gas and pulled around and pushed together.

Recommended Videos

At the heart of almost every galaxy is an enormous supermassive black hole, but this galaxy is a little different. It has not one but two supermassive black holes, one from each of the original galaxies. One of these is 154 million times the mass of the sun, and the other just 6.3 million times the mass of the sun, and the two are located 1,600 light-years apart in their own galactic nuclei.

This galaxy won’t remain in this unusual state forever though. Eventually, the huge gravitational forces of the two supermassive black holes will pull them closer and closer together, and scientists estimate that the two will merge in around 250 million years’ time. This monumental event will send out ripples in spacetime called gravitational waves and will create an even larger supermassive black hole.

Topics

Tech News

Georgina Torbet

Space Writer

Georgina has been the space writer at Digital Trends space writer for six years, covering human space exploration, planetary…

Space

Swift Observatory spots a black hole snacking on a nearby star

Swift J0230 occurred over 500 million light-years away in a galaxy named 2MASX J02301709+2836050, captured here by the Pan-STARRS telescope in Hawaii.

Black holes can be hungry beasts, devouring anything that comes to close to them, including clouds of gas, rogue planets, and even stars. When stars get too close to a black hole, they can be pulled apart by gravity in a process called tidal disruption that breaks up the star into streams of gas. But a recent discovery shows a different phenomenon: a black hole that is "snacking" on a star. It's not totally destroying the star, but pulling off material and nibbling at it on a regular basis.

Black Hole Snack Attack

Space

See the terrifying scale of a supermassive black hole in NASA visualization

Illustration of the black hole Sagittarius A* at the center of the Milky Way.

This week is black hole week, and NASA is celebrating by sharing some stunning visualizations of black holes, including a frankly disturbing visualization to help you picture just how large a supermassive black hole is. Supermassive black holes are found at the center of galaxies (including our own) and generally speaking, the bigger the galaxy, the bigger the black hole.

Illustration of the black hole Sagittarius A* at the center of the Milky Way. International Gemini Observatory/NOIRLab/NSF/AURA/J. da Silva/(Spaceengine) Acknowledgement: M. Zamani (NSF's NOIRLab)

Space

Supermassive black hole spews out jet of matter in first-of-its-kind image

Scientists observing the compact radio core of M87 have discovered new details about the galaxy’s supermassive black hole. In this artist’s conception, the black hole’s massive jet is seen rising up from the centre of the black hole. The observations on which this illustration is based represent the first time that the jet and the black hole shadow have been imaged together, giving scientists new insights into how black holes can launch these powerful jets.

As well as pulling in anything which comes to close to them, black holes can occasionally expel matter at very high speeds. When clouds of dust and gas approach the event horizon of a black hole, some of it will fall inward, but some can be redirected outward in highly energetic bursts, resulting in dramatic jets of matter that shoot out at speeds approaching the speed of light. The jets can spread for thousands of light-years, with one jet emerging from each of the black hole's poles in a phenomenon thought to be related to the black hole's spin.

Scientists observing the compact radio core of M87 have discovered new details about the galaxy’s supermassive black hole. In this artist’s conception, the black hole’s massive jet of matter is seen rising up from the center of the black hole. The observations on which this illustration is based represent the first time that the jet and the black hole shadow have been imaged together, giving scientists new insights into how black holes can launch these powerful jets. S. Dagnello (NRAO/AUI/NSF)