Astrum Space - The Star Explosion So Powerful, We Felt It 2 Billion Light Years Away | Astrum Sleep Space
Episode Date: October 2, 2025The Brightest Explosion of All Time (B.O.A.T) could explain how the universe's heavy elements are formed. Astrum's newsletter has launched! Want to know what's happening in space? Sign up ...here: https://astrumspace.kit.comA huge thanks to our Patreons who help make these videos possible. Sign-up here: https://bit.ly/4aiJZNF
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In October 2022, a brilliant flash pierced the cosmos, brighter and more intense than anything human civilization had ever seen.
And that's not an exaggeration. The strength of the blast blinded our gamma-ray detectors the world over
and unleashed more energy in a matter of seconds than our sun will emit over its entire 9 billion-year lifespan.
Over the 18 months that followed, it became the most widely.
studied gamma-ray burst in history, creatively dubbed the boat for the brightest of all time.
As researchers began to decipher its cause, their findings unraveled one mystery after another.
Scientists have been cataloguing gamma-ray burst for decades, but this one was closer,
brighter, and unexplainably devoid of some key signatures you'd expect to see.
It also raises some far-reaching questions about our standard
model, the possibility of a dark matter particle, and how heavy elements like gold are made.
I'm Alex McColgan and you're listening to the Astrum podcast. Join me today as we dive into the
mystery of the biggest and brightest gamma ray burst of all time. What caused such a colossal
explosion? How is it different from other gamma ray bursts before it? And what can it teach us about
our understanding of the universe and the particles that?
constituted. Gamma ray bursts are brief, intense flashes of high-energy gamma radiation
lasting from milliseconds to several minutes. The first of its kind was detected in 1967,
when American satellites designed for detecting covert Soviet nuclear testing picked
up an unusual pattern of electromagnetic energy. Since then, gamma-ray bursts have been of tremendous
interest to the cosmological community, as they allow scientists to study.
studies of matter and physics that are not reproducible on Earth.
Essentially, they provide researchers with a glimpse of how stars are formed and evolve across
the whole timeline of the universe.
There are two different kinds of gamma-ray bursts. Short gamma-ray bursts last less than two
seconds and are attributed to either the collision of two neutron stars or the merger of a
neutron star and a black hole. They can be followed by a kilonova.
an emission of bright light resulting from the radioactive decay of chemical elements.
This decay creates even heavier elements, an important feature of novae, which we'll discuss
more later.
Anything lasting longer than two seconds is classed as a long gamma-ray burst.
These are thought to be caused by the explosive deaths of massive stars and their subsequent supernovae.
The collapse core may form either a neutron star or a black hole.
These typically occur close to the edges of the observable universe because they are characteristic
of low metallicity stars which formed when there were less heavy elements around.
When we see one of these, we are witnessing events from billions of years ago.
In the case of both long and short gamma ray bursts, the newly formed black hole blasts out jets
in opposing directions, containing particles accelerated close to the speed of light. When these particles interact
with surrounding matter, they emit the gamma rays we detect.
So what made the boat so special?
Let's start by analyzing some of its key characteristics.
Firstly, the boat lasted 10 whole minutes and was detectable for 10 hours after the fact.
It occurred in the Sagittah constellation only 2 billion light years away, which is much
closer than other gamma ray bursts we've detected until now.
In fact, such a bright explosion so close to Earth is thought to be a one in 10,000 year
event, meaning the last time one happened, humans had barely started farming.
As is the case with other long gamma-ray bursts, we know a collapsing and exploding star was
behind it, but this is where things start to get fuzzy.
A supernova alone isn't enough to explain the magnitude of the gamma rays emitted.
The boat was a whopping 70 times stronger than any other gamma-ray burst detected.
Initially, the theory was that this must be the supernova of a ginormous star, the likes of
which we rarely see.
However, upon closer inspection of the afterglow, scientists found that the supernova behind
the boat was shockingly ordinary.
To get a clearer picture, astronomers pointed the James Webb Space Telescope in the
boat's direction.
Near infrared spectrograph revealed that the supernova behind the boat was actually pretty
average. It wasn't nearly as bright as you'd expect given the gamma-ray burst that accompanied
it. So what could have caused such a flash? One idea is that we simply perceive the flash
as bigger and brighter because of Earth's relative position to the blast. Imagine a flashlight
shining in the dark, diffuse and soft. It lights the parts of the parts of the Earth's relative position to the blast. Imagine a flashlight shining in the dark, diffuse and soft. It lights the
path one to two meters ahead of you. Now, imagine capturing all that light and focusing it into
a singular laser beam. You wouldn't illuminate the path as widely, but it would reach hundreds
of meters into the distance. And if Earth was in the direct path of that laser, it would
register a super bright reading. That doesn't mean the laser released more energy than the flashlight,
it just means the way it was concentrated and then detected resulted in a higher reading.
The same concept can be applied to these gamma-ray bursts.
If a massive star is spinning super fast when it collapses, then the shape and structure of the
near light-speed jets it emits will be more narrow and focused, and therefore brighter.
In fact, the jets seen from the boat are some of the narrowest we've ever seen.
But not only were these particle jets brighter than expected, scientists also detected way
more of them going faster than expected. They travelled with such fervour that after 2 billion
years traversing the cosmos, they arrived here and momentarily disrupted the Earth's atmosphere.
Sitting just 50 to 1,000 kilometres above the surface of our planet, Earth's ionosphere is rich
in electrically charged particles. When the boat struck, it left a mark comparable to that of a major
solar flare, pushing the ionosphere down into lower altitudes.
If photons from an explosion, 2 billion light years away, can have this kind of effect
on our planet, I don't really want to think about what happens if something like that
in our neighbourhood explodes.
The large high altitude air shower observatory in Dowicheng County, China, managed to capture
data on tens of thousands of photons over the course of the initial blast and into the afterglow.
This is a quantity unlike anything seen before in gamma-ray astronomy.
In fact, it's so far out of pocket that some astrophysicists think that they might be pointing
towards something missing from our models.
According to our current understanding, it's very unlikely these super high-energy photons
are travelling for 2 billion years.
Cosmic microwave background radiation, interactions with intergalactic dust, or redshifting
caused by the expansion of the universe are all factors that can interfere with the photons
trajectory.
One hypothesis put forward is that photons convert themselves into a hypothetical particle
called an axiom, and then convert back into gamma rays upon reaching our galaxy's magnetic
field.
Axions are thought to be an ultra-light particle responsible for dark matter.
Their existence is currently purely hypothetical.
have no evidence for them, and even if we did, they would lie outside the standard model
of particle physics.
We don't have time to dive into detail in today's podcast, but I might take a deeper look
at them in a future episode.
Okay, so far we've established that boat was caused by a massive star collapsing and turning
into a black hole, which incidentally is known as a collapsar.
Aside from generating a long gamma-ray burst,
collapsars are also known for generating something else.
Gold.
Wait, wait, how is gold connected to gamma rays?
Good question.
To understand that, let's take a minute to discuss how elements are made.
The core of a star is a super high pressure environment,
some 200 billion times higher than the atmospheric pressure on Earth.
In these conditions, nuclear fusion reactions create heavier elements out of lighter ones.
For example, one helium atom comes from fusing four hydrogen atoms together.
Elements 2 through 26 on the periodic table, that's helium to iron, are made this way,
a process known as stellar nucleosynthesis.
However, once you get to iron, it isn't energetically favourable to continue making bigger
and bigger elements this way.
So how do we account for the rest of the periodic table?
Where do these heavier elements like gold come from?
At the moment, we know two different ways these elements are formed.
The first was recently confirmed by the James Webb Space Telescope.
When two ultra-dense neutron stars collide, they emit an immense amount of neutron particles.
Surrounding material captures these neutrons, making their atoms temporarily unstable.
In order to stabilize, the neutrons undergo radioactive decay into protons, creating new, heavier
elements.
This process is known as rapid neutron capture, or R-processed nucleosynthesis.
Some calculations suggest one neutron star collision can produce up to three Earth masses
worth of heavy elements.
However, this explanation alone isn't sufficient to account for all the heavy elements
in the universe.
star collisions are rare and take a long time to happen in the order of billions of years.
On top of that, observations of very old stars show that heavy elements were already present
in parts of the universe well before most binary neutron stars would have had a chance to collide.
So how do you explain that?
There must be another source of heavy elements in the cosmos, which brings us back to our
boat.
There's another theory that collapse stars like the boat could be another source of
our process nucleosynthesis.
In their dying stages, massive stars like the one that cause the boat are surrounded by layers
of exploding gas.
These explosions leave disks of matter swirling around the resulting infant black hole.
As the black hole begins devouring the surrounding material, it can only ingest so much
at a time.
What it cannot manage is swept away in a new,
neutron dense wind. Here, the same R-processed nucleosynthesis occurs, forming heavier elements
like gold, silver, and platinum. This seems promising, but unfortunately, even factoring
in these kinds of supernovae isn't enough to account for the abundance of gold in the universe.
To make matters worse, analysis of the boat spectrum didn't show any traces of heavy elements,
raising questions about the validity of this collapsar gold-making theory.
Some scientists suggest the boat's host galaxy might have something to do with the lack of heavy
elements in the explosion.
Upon modeling the host galaxy spectrum, researchers discovered it has the lowest metallicity
of all previous host galaxies where gamma-ray bursts were detected.
In other words, maybe the environment didn't have the right building blocks to make heavier elements.
How do we know how much gold should be out there in the first place?
How do scientists predict something like the relative abundance of elements in the universe?
There are two main methods of calculating this, the spectroscopy of stellar photospheres
and meteorite analysis.
By analyzing the absorption lines in the spectra of stars, astronomers can determine the
relative abundances of elements in the photosphere of those stars.
The composition of meteorites, remnants of an early solar system, are analyzed in parallel
to determine the relative abundances of elements.
Meteorites are especially useful for measuring the abundances of volatile elements like hydrogen,
helium, and noble gases that are unrepresented in stellar photospheres.
The results of both of these methods are usually congruent, indicating we're probably doing
something right.
But this is physics, so of course nothing is so cut.
and dry.
One famous exception to this rule is lithium.
According to the standard Big Bang nuclear synthesis theory, the early universe should have produced
about three times more lithium 7 than is currently observed.
The plot thickens when we consider its isotope, lithium 6, where we observe 1,000 times more
than that predictions can account for.
This discrepancy is known as the lithium problem, and remains unsolved, presenting a significant
significant challenge to the standard cosmological model. It highlights the importance of
understanding the processes that shape the relative abundances of elements in the universe,
and suggest that our current understanding of nucleosynthesis might be incomplete.
Just because boat didn't yield gold as expected doesn't mean we should discard these
kinds of extreme gamma-ray bursts as places where heavy elements could be made.
Observations of nearby stars have provided strong evidence for an early R process that an
enrich the universe with heavy elements.
But the boat findings cannot be ignored, as they suggest there may be alternative, currently
unknown processes responsible for this elemental enrichment of our cosmos.
The results may call into question our entire model of understanding regarding collapsears
and their role in creating heavy elements.
This discovery is much bigger than just the boat or gamma rays.
It's about the literal building blocks of our universe.
as we know it. Where do our different atoms come from? And why do they exist in the proportions
they do? How much of our model is accurate and how much is missing? What role does dark matter
play in all of this? We need more time and research before we know for sure, but the boat is a great
example of how new findings keep our understanding of physics ever evolving, just like the universe
itself. Well, that's all we have time for today. I hope you've enjoyed listening to this podcast
on Boat. If you've enjoyed what you've heard, please feel free to follow us for more podcasts
on other fascinating space topics. But for now, I'm Alex McCulligan, and this has been Astrom.
All the best, and see you next time.
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