Astronomers marvel at 'perfect explosion,' a spherical cosmic fireball
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[February 16, 2023]
By Will Dunham
WASHINGTON (Reuters) - Astronomers have observed what might be the
"perfect explosion," a colossal and utterly spherical blast triggered by
the merger of two very dense stellar remnants called neutron stars
shortly before the combined entity collapsed to form a black hole.
Researchers on Wednesday described for the first time the contours of
the type of explosion, called a kilonova, that occurs when neutron stars
merge. The rapidly expanding fireball of luminous matter they detailed
defied their expectations.
The two neutron stars, with a combined mass about 2.7 times that of our
sun, had orbited each other for billions of years before colliding at
high speeds and exploding. This unfolded in a galaxy called NGC 4993,
about 140-150 million light years away from Earth in the direction of
the constellation Hydra. A light year is the distance light travels in a
year, 5.9 trillion miles (9.5 trillion km).
The existence of kilonova explosions was proposed in 1974 and confirmed
in 2013, but what they looked like was unknown until this one was
detected in 2017 and studied intensively.
"It is a perfect explosion in several ways. It is beautiful, both
aesthetically, in the simplicity of the shape, and in its physical
significance," said astrophysicist Albert Sneppen of the Cosmic Dawn
Center in Copenhagen, lead author of the research published in the
journal Nature.
"Aesthetically, the colors the kilonova emits quite literally look like
a sun - except, of course, being a few hundred million times larger in
surface area. Physically, this spherical explosion contains the
extraordinary physics at the heart of this merger," Sneppen added.
The researchers had expected the explosion to perhaps look like a
flattened disk - a colossal luminous cosmic pancake, possibly with a jet
of material streaming out of it.
"To be honest, we are really going back to the drawing board with this,"
Cosmic Dawn Center astrophysicist and study co-author Darach Watson
said.
"Given the extreme nature of the physical conditions - far more extreme
than a nuclear explosion, for example, with densities greater than an
atomic nucleus, temperatures of billions of degrees and magnetic fields
strong enough to distort the shapes of atoms - there may well be
fundamental physics here that we don't understand yet," Watson added.
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A perfectly spherical explosion, called
a kilonova, that followed the merger of two very defense objects
called neutron stars - remnants of massive stars after supernova
explosions ? that was observed 140-150 million light-years away from
Earth is seen in this handout illustration obtained by Reuters on
February 15, 2023. Albert Sneppen/Handout via REUTERS
The kilonova was studied using the European Southern Observatory's
Chile-based Very Large Telescope.
The two neutron stars began their lives as massive normal stars in a
two-star system called a binary. Each exploded and collapsed after
running out of fuel, leaving behind a small and dense core about 12
miles (20 km) in diameter but packing more mass than the sun.
Very gradually, they drew nearer to each other, orbiting at a speedy
clip. Each were stretched out and pulled apart in the final seconds
before the merger because of the power of the other's gravitational
field. Their inner parts collided at about 25% of the speed of
light, creating the most intense magnetic fields in the universe.
The explosion unleashed the luminosity of about a billion suns for a
few days.
The two briefly formed a single massive neutron star that then
collapsed to form a black hole, an even denser object with gravity
so fierce that not even light can escape.
The outer parts of the neutron stars, meanwhile, were stretched into
long streamers, with some material flung into space. During the
process, the densities and temperatures were so intense that heavy
elements were forged, including gold, platinum, arsenic, uranium and
iodine.
The researchers offered some hypotheses to explain the spherical
shape of the explosion, including energy released from the
short-lived single neutron star's enormous magnetic field or the
role of enigmatic particles called neutrinos.
"This is fundamentally astonishing, and an exciting challenge for
any theoreticians and numerical simulations," Sneppen said. "The
game is on."
(Reporting by Will Dunham, Editing by Rosalba O'Brien)
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