For the first time, astronomers seen a black hole swallowing a neutron star

 

Once upon a time, in a galaxy far, far away, a black hole swallowed a neutron star. Then, 10 days later, another black hole ate up another star. The two separate events triggered ripples through time and space that eventually hit Earth.

 

Those ripples, first detected in January 2020, offered researchers two distinct looks at the never-before-measured cosmic collisions, according to research published Tuesday in the academic publication The Astrophysical Journal Letters.

 

"This is the first detection of a merger between a black hole and neutron star," said Chase Kimball, a Northwestern University graduate student and one of the study's co-authors. "The black holes swallowed the neutron stars, making bigger black holes."

 

Astrophysicists have previously observed two black holes colliding with two neutron stars in separate events, but never the two paired together.

 

LIGO detected gravitational waves from the black hole-neutron star merger. This simulation depicts what a (well protected) observer might see from nearby. https://t.co/n84kwnimlW pic.twitter.com/dxemzZbKaB

— Corey S. Powell (@coreyspowell) June 29, 2021

 

"We long thought they exist, but this is the first direct confirmation that will help fine-tune future astrophysical models of stellar populations in our universe and how their remnants interact with each other," Kimball said.

 

The collisions and ensuing gravitational waves offer a rare glimpse into how cataclysmic cosmic explosions like the black hole-neutron star collision impact the expansion and shrinking of space-time — an observation that had never been seen before in the nascent field of gravitational-wave astronomy.

 

Neutron stars are corpses of large stars 10 to 30 times as massive as the sun, and black holes are condensed space regions where gravitational forces are so strong that not even light can escape. When these astronomical objects meet, according to Kimball, they spiral around each other "like a dance," emitting gravitational waves until they finally collide.

 

The merger produces bursts of energy like gravitational waves that move through space and time — a perturbation that has been measured by detectors on Earth from theLaser Interferometer Gravitational-Wave Observatory, known as LIGO.

 

In collaboration with a smaller detector in Italy called Virgo, LIGO picked up the first black hole merging with the neutron star about 900 million light-years away from Earth on Jan. 5, 2020. The second gravitational waves were picked up farther away from the planet Jan. 15, 2020.

 

Kimball said astrophysicists would need to observe more of this rare coupling to learn more about its characteristics.

 

"How do they spin? How massive exactly are the neutron stars?" he said. "There's just so much more to learn."