Milky Way's black hole spews out cosmic 'spitballs'

Milky Way's black hole spews out cosmic 'spitballs'

Milky Way's black hole spews out cosmic 'spitballs'

A supermassive black hole in the centre of the Milky Way galaxy flings out planet-sized 'spitballs' formed from fragments of stars shredded by it, scientists have found.

Every few thousand years, an unlucky star wanders too close to the black hole whose powerful gravity rips the star apart, sending a long streamer of gas whipping outwards.

New research shows that not only can the gas gather itself into planet-size objects, but those objects then are flung throughout the galaxy in a game of cosmic "spitball."

"A single shredded star can form hundreds of these planet-mass objects. We wondered: Where do they end up? How close do they come to us? We developed a computer code to answer those questions," said Eden Girma, undergraduate student at Harvard University in the US.

Calculations show that the closest of these planet-mass objects might be within a few hundred light-years of Earth.

It would have a weight somewhere between Neptune and several Jupiters. It would also glow from the heat of its formation, although not brightly enough to have been detected by previous surveys.

Future instruments like the Large Synoptic Survey Telescope and James Webb Space Telescope might spot these far-flung oddities, researchers said.

She also finds that the vast majority of the planet-mass objects - 95 per cent - will leave the galaxy entirely due to their speeds of about 10,000 kilometres per second.

Since most other galaxies also have giant black holes at their cores, it is likely that the same process is at work in them.

"Other galaxies like Andromeda are shooting these 'spitballs' at us all the time," said James Guillochon of the Harvard-Smithsonian Centre for Astrophysics (CfA).

Although they might be planet-size, these objects would be very different from a typical planet.

They are literally made of star-stuff, and since different ones would develop from different pieces of the former star, their compositions could vary.

They also form much more rapidly than a normal planet. It takes only a day for the black hole to shred the star (in a process known as tidal disruption), and only about a year for the resulting fragments to pull themselves back together.

This is in contrast to the millions of years required to create a planet like Jupiter from scratch.

Once launched, it would take about a million years for one of these objects to reach Earth's neighbourhood.

The challenge will be to tell it apart from free-floating planets that are created during the more mundane process of star and planet formation.

"Only about one out of a thousand free-floating planets will be one of these second-generation oddballs," said Girma.