A Mysterious ‘Heartbeat’ Has Been Found In A Galaxy One Billion Light-Years From Us Say Scientists

Science A Mysterious ‘Heartbeat’ Has Been Found In A Galaxy One Billion Light-Years From Us Say Scientists Jamie Carter Senior Contributor Opinions expressed by Forbes Contributors are their own. I inspire people to go stargazing, watch the Moon, enjoy the night sky New! Follow this author to improve your content experience. Got it! Jul 16, 2022, 03:10am EDT | Share to Facebook Share to Twitter Share to Linkedin Heart-shape for the stars.

My astronomy work. getty Astronomers have detected a radio signal from a far-off galaxy that flashes for up to three seconds on a regular basis. Over a billion light-years distant, the signal is called FRB 20191221A and it’s classed as a “fast radio burst”—a radio pulse.

Around 1,000 times longer than most FRBs, FRB 20191221A is now the longest-lasting and most regular radio signal known in the entire night sky. It was detected using the CHIME radio telescope in British Columbia, Canada, which detected over 500 FRBs in its first year of operation. The results were published in Nature .

Scientists think that the radio signal may be coming from a neutron star—what remains of the collapsed core of a giant star after it’s exploded as a supernova. Neutron stars spin rapidly. Though the origin of FRBs are mysterious it’s hoped that each one’s frequency, and how they differ in distance from us, could tell scientists about the exact rate at which the universe is expanding.

The first FRB was discovered in 2007. FRB 20191221A was first detected on December 21, 2019. “It was unusual,” said Daniele Michilli, a postdoc in MIT’s Kavli Institute for Astrophysics and Space Research.

“Not only was it very long, lasting about three seconds, but there were periodic peaks that were remarkably precise, emitting every fraction of a second — boom, boom, boom—like a heartbeat. ” Artwork illustrating a fast-radio burst. Magnetars are types of neutron stars that have exceedingly .

. . [+] powerful magnetic fields, trillions of times stronger than Earth’s own field and even more powerful than regular neutron stars.

Recently, astronomers have suggested that asteroids might be orbiting some of these objects, leading to the emission of fast-radio bursts (FRBs). The idea is that asteroids orbiting within the magnetar’s wind – a stream of fast particles emitted from its surface – carve a wake in the wind, leading to the generation of an electric current around the wake. When the magnetar’s wind crosses the wake, a magnetic disturbance is created which generates an extremely intense, narrow beam of radio energy.

In 2020, astronomers detected the first FRB from a magnetar – called SGR 1935+2154 – located within our own galaxy. The entire event was over in a fraction of a second. getty MORE FOR YOU New Research Finds A Connection Between Domestic Violence And These Two Personality Disorders This Scientist Helps Andean Forests And Ecuador’s Women In STEM Exceptional Fossil Preservation Suggests That Discovering Dinosaur DNA May Not Be Impossible So what could be the source of FRB 20191221A? “There are not many things in the universe that emit strictly periodic signals,” said Michilli.

“Examples that we know of in our own galaxy are radio pulsars and magnetars, which rotate and produce a beamed emission similar to a lighthouse. And we think this new signal could be a magnetar or pulsar on steroids. ” Types of neutron stars, a pulsar is a neutron stars that emits beams of radio waves and appears to pulse as the star rotates while a magnetar has extreme magnetic fields.

The FRB 20191221A signal is a million times brighter than pulsars and magnetars in the Milky Way. “From the properties of this new signal, we can say that around this source, there’s a cloud of plasma that must be extremely turbulent,” said Michilli. “Future telescopes promise to discover thousands of FRBs a month, and at that point we may find many more of these periodic signals.

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