For the First Time, Astronomers Have Detected a Radio Signal From the Massive Explosion of a Dying White Dwarf

Illustration of a binary star system with a planet and spiraling galaxy visible.

When stars like our Sun die, they tend to go out with a whimper and not a bang – unless they happen to be part of a binary (two) star system that could give rise to a supernova explosion. (Image: Anei via Dreamstime)

When stars like our Sun die, they tend to go out with a whimper and not a bang — unless they happen to be part of a binary (two) star system that could give rise to a supernova explosion.

Now, for the first time, astronomers have spotted the radio signature of just such an event in a galaxy more than 400 million light-years away. The finding, published today in Nature, holds tantalizing clues as to what the companion star must have been like.

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An explosive star death

As stars up to eight times heavier than our Sun start to run out of nuclear fuel in their core, they puff off their outer layers. This process gives rise to the colorful clouds of gas misleadingly known as planetary nebulae, and leaves behind a dense, compact hot core known as a white dwarf.

Image of white dwarf stars as seen from NASA's Hubble Space Telescope.
This image shows some of the oldest stars in the Milky Way — ancient white dwarfs — as imaged by NASA’s Hubble Space Telescope. (Image: H. Richer / University of British Columbia via NASA)

Our own Sun will undergo this transition in 5 billion years or so, then slowly cool and fade away. However, if a white dwarf somehow puts on weight, a self-destruct mechanism kicks in when it gets heavier than about 1.4 times the mass of our Sun. The subsequent thermonuclear detonation destroys the star in a distinctive kind of explosion called a Type Ia supernova.

But where would the extra mass come from to fuel such a bang?

We used to think it could be gas being stripped off a bigger companion star in a close orbit. But stars tend to be messy eaters, spilling gas everywhere. A supernova explosion would shock any spilt gas and make it glow at radio wavelengths. Despite decades of searching however, not a single young Type Ia supernova has ever been detected with radio telescopes.

Instead, we began to think Type Ia supernovae must be pairs of white dwarfs spiraling inwards and merging together in a relatively clean fashion, leaving no gas to shock — and no radio signal.

A rare type of supernova

Supernova 2020eyj was discovered by a telescope in Hawai’i on March 23, 2020. For the first seven weeks or so it behaved in much the same way as any other Type Ia supernova.

But for the next five months, it stopped fading in brightness. Around the same time, it began to show features indicating gas that was unusually rich in helium. We began to suspect Supernova 2020eyj belonged to a rare subclass of Type Ia supernovae in which the blast wave, moving at more than 10,000 kilometers per second, sweeps past gas that could only have been stripped off the outer layers of a surviving companion star.

To try to confirm our hunch, we decided to test if there was enough gas being shocked to produce a radio signal. As the supernova is too far north to observe with telescopes like the Australia Telescope Compact Array near Narrabri, we instead used an array of radio telescopes spread across the United Kingdom to observe the supernova about 20 months after the explosion.

To our great surprise, we had the first-ever clear detection of an “infant” Type Ia supernova at radio wavelengths, confirmed by a second observation some five months later. Could this be the “smoking gun” that not all Type Ia supernovae are caused by the merger of two white dwarfs?

Patience pays off

One of the more remarkable properties of Type Ia supernovae is that they all seem to reach pretty much the same peak brightness. This is consistent with them all having reached a similar critical mass before exploding.

This very attribute allowed astronomer Brian Schmidt and colleagues to reach their Nobel Prize-winning conclusion in the late 1990s: that the universe’s expansion since the Big Bang is not slowing down under gravity (as everyone had expected), but is accelerating due to the effects of what we now call dark energy.

This illustrated diagram of the planetary system G238-44 traces its destruction.
This illustrated diagram of the planetary system G238-44 traces its destruction. The tiny white dwarf star is at the center of the action. A very faint accretion disk is made up of the pieces of shattered bodies falling onto the white dwarf. The remaining asteroids and planetary bodies make up a reservoir of material surrounding the star. Larger gas giant planets may still exist in the system. Much farther out is a belt of icy bodies such as comets, which also ultimately feed the dead star. (Image: Joseph Olmsted (STScI) via NASA, ESA)

So Type Ia supernovae are important cosmic objects, and the fact we still don’t know exactly how and when these stellar explosions occur, or what makes them so consistent, has been a worry to astronomers.

In particular, if pairs of merging white dwarfs can range in total mass up to almost three times the mass of our Sun, why should they all release about the same amount of energy?

Our hypothesis (and radio confirmation) that Supernova 2020eyj occurred when enough helium gas was stripped off the companion star and onto the surface of the white dwarf to push it just over the mass limit, provides a natural explanation for this consistency.

The question now is why we haven’t seen this radio signal before in any other Type Ia supernova. Perhaps we tried to detect them too soon after the explosion, and gave up too easily. Or maybe not all companion stars are as helium-rich and prodigious in shedding their gaseous outer layers.

But as our study has shown, patience and persistence sometimes pay off in ways we never expected, allowing us to hear the dying whispers of a distant star.

Stuart Ryder, Adjunct Fellow, School of Mathematical and Physical Sciences, Macquarie University and Erik Kool, Postdoctoral Researcher in Astronomy, Stockholm University

This article is republished from The Conversation under a Creative Commons license. Read the original article.

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