Astrum Space - We Are Currently Passing Through a 1 Million Degree Supernova Graveyard
Episode Date: August 21, 2025Did you know our solar system is cruising through a giant bubble of superheated plasma, carved out by at least 15 nearby supernova explosions? In this video, we’re investigating the ancient expandin...g structure of the Local Hot Bubble, while racing towards its very centre. 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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When 15 supernovae go off close together, both in time and proximity, it makes quite a bang.
It should be of no surprise that such a violent event should fundamentally transform the region of space around where it occurred.
Interstellar dust was swept aside from the forces of those concurrent blasts, creating a monumental void of low-density matter,
and a shockwave that continues to hurtle across the galaxy to this day at a rate of 6 km
a second.
In its wake, plasma, reaching 1 million degrees Celsius in temperature.
This simultaneous Swiss cheesing and heating up of the interstellar medium is what is now called
a hot bubble, and represents both the end of stars and their beginning.
This is not some distant structure that lurks in a far away corner of the universe.
Our solar system isn't even heading right towards it.
We are in it, charging for its point of origin head first.
Welcome to our local hot bubble.
What scientists now realize is the local environment that exists around our solar system.
It is a neighborhood we are still exploring.
exploring, but its nature is becoming clearer and clearer. So what do we know about the local
hot bubble? How did it form? And what more is there to be discovered? I'm Alex McColgan and you're
watching Astrom. Join me today as we walk in the aftermath of exploding stars and discuss how
scientists even determined we were in the heart of a cataclysm to begin with. The local hot
bubble was not always something we knew about.
First identified in the 1970s from observations of low energy X-ray emissions that were detected
over the entire sky, the local hot bubble was hypothesized to be a large cavity in the
interstellar medium, called a super bubble filled with tenuous, million degree, low density, gas.
In the 1990s, scientists found that X-ray emissions could happen anywhere.
where neutral atoms interacted with the solar wind, challenging the idea that the emissions
must point to a large hot bubble.
But soon, evidence would reveal that the hypothesis from decades earlier was indeed correct.
In 2014, NASA confirmed the existence of the LHB through the diffuse X-ray emission from the
local galaxy mission, known as DXL.
While soft background radiation can come from other sources, like from comets, for example,
the mission found that only 40% of the fog of low energy x-rays came from within our solar
system.
This affirmed that the dominant source was diffuse x-ray emissions emanating from the million-degree
region of interstellar plasma, known as the LHB.
Although this confirmed the bubble, questions remained about what could create such
a massive void, and what might explain the thousands of surrounding young stars.
The prevailing answer proved to be both violent and fascinating.
Recent research suggests that the local hot bubble was the aftermath of around 15 supernova
explosions that occurred sequentially within a span of a few million years, erupting
in relatively close proximity to one another. Scientists estimated that the first
Most of these massive stellar explosions went off roughly 14 million years ago, each expelling
enormous amounts of energy, pushing out the surrounding interstellar material and heating
the remaining gas to extreme temperatures.
Evidence of these ancient explosions has been preserved in our Earth's geological record
in deep sea sediment deposits in the form of a special isotope called IN60. This radioactive
The radioactive isotope can come from a few different sources, but the most common source of
iron 60 is believed to be supernova explosions.
We know that the source of the isotope is extraterrestrial, because the Earth itself has no
way of producing iron 60 on its own, and matching deposits have been found on the moon as well.
The reason that this radioactive isotope is special is because we know how long its half-life
is.
We know that it decays into Cobalt 60, another radioactive isotope, before it finally decays
into nickel 60, a stable element.
Iron 60 has a half-life of 2.6 million years, and Cobalt 60 has a fairly short half-life of just
5.3 years. Because of this, when we find a deposit that contains these elements,
Scientists can compare the amounts of iron 60, cobalt 60, and nickel 60, like an elemental
clock, to reveal when that material was deposited on our planet.
And luckily for us, international research teams have found several such deposits over the last
couple of decades.
In 2016, iron 60 deposits were found in deep-sea cross samples taken from the Pacific, Indian,
and Atlantic oceans, indicating.
creating two distinct spikes in the radioactive debris appointed to several supernova events
in the not so distant past, and not too far from our solar system, just 326 light years away.
The sample showed a spike of iron 60 between 3.2 and 1.7 million years ago, and another spike
between 6.5 and 8.7 million years ago.
Nuclear physicist Anton Walner, who led one of these research teams studying the deposits,
said that the fact that the more recent debris was spread across 1.5 million years suggests
that there were a series of supernovae that occurred one after another in close succession.
Astrophysicist Dieter Breitchvert, who led a second team of scientists, identified a likely
source of these supernova explosions, which would have occurred 196 to 400,000.
123 light years from the sun.
These supernovae that created our local hot bubble may have been part of an aging star cluster,
whose surviving members are now associated with the Scorpius Centora stellar group.
Using the iron 60 deposits, the team was able to trace the signals of two supernovae, one that
happened 1.5 million years ago and the other 2.3 million years ago, as the result of the deaths
of stars that were 8.8 times and 9.2 times the mass of our Sun, respectively.
In fact, our LHB is still growing today, albeit much more slowly than when the supernova exploded
millions of years ago. The speed of expansion has plateaued at about 6 kilometers per second now,
according to astrophysicist Catherine Zucker. In 2022, Zucker authored a groundbreaking paper that
reconstructed the evolution of our galactic neighborhood, tracing the chain of events that created
our local hot bubble and led to the formation of all the young stars we see nearby today.
From there, they made an incredible discovery.
Using data from the European Space Agency's Gaia Telescope, Zaka and her team were able
to construct a 3D space-time map, showing that within 500 light years of our planet, all of
the young stars and star forming regions reside on the surface of our local hot bubble.
With these 3D positions and the 3D motions of the stellar clusters, they traced back 20
million years of star formation history near our local hot bubble.
The implications were clear that all of the well-known star forming regions near our solar
system had formed along the outer edge of the local bubble as it swept up gas during the
its expansion.
Stellar nurseries are a field we're learning more about all the time, particularly as new
images are taken by our telescopes.
Here's a spectacular image of the Chameleon One Dark Cloud, one of our nearest stellar nurseries,
taken by a dark energy camera on the Victor M Blanco 4-meter telescope at Chero Tololo Inter-American
Observatory.
By studying the propagation of starlight from within it, scientists can tease out details
about how stars form, which might help us better understand the local hot bubbles impact
on our galaxy today.
You might not have seen this particular image before, as new space news is coming out all the
time, but I've talked about it in my newsletter, which I've recently launched to help you
keep up with all the breathtaking photos released by our many telescopes on Earth and in orbit,
or new breakthroughs that reshape how we understand the cosmos.
You should sign up to never miss the most exciting.
exciting news, even if the headlines do by following the link in the description below.
There are new editions that come out every Thursday.
From the local Hot Bubbles birth 14 million years ago, Zucker and her colleagues identified
four epochs of star formation on the bubble shell.
Starting about 16 million years ago, we see the birth of the Upper Centaurus Lupus, or the UCL
star cluster, followed by the lower Centaurus Crux, or LCC, star cluster.
These formed about 49 light years apart from one another, and about 14 million years ago,
these stellar populations were the source of the stars that went supernova to create our local
bubble.
About 10 million years ago, we see the first of the four star-forming epochs after the formation
of the LHB, the Upper Scorpius Association, and older Ophiuchus stellar populations are born in
the first epoch. Six million years ago, the second star-forming epoch formed Crona Australis,
and the older stars of Taurus. Then, around two million years ago, the stars in Lupus and
chameleon, as well as younger stellar populations of Taurus and Ophiuchus, came to be in the 3rd and
third epoch, and finally, our present time falls within the fourth star-forming epoch.
We can observe the dense star-forming molecular gas that surrounds the LHB, which will eventually
lead to more star clusters being born along the bubble's outer edge.
With all of this stellar creation, you might be surprised to learn that we are interlopers.
Our sun did not form inside the local bubble.
In fact, the sun was about 978 light years away when the first supernova went off in UCL and
LCC, only joining up with the LHB about 5 million years ago as its path through the galaxy
took it into the bubble.
With the trajectory shown in yellow dots, you can see our sun's location just before it
entered the bubble.
And now, just by coincidence, our sun happens to be located near the center of the LHB.
Drifting into the heart of what was once a raging furnace, scientists became interested in mapping
out the ongoing temperature within the local bubble.
You might wonder why we're so calm if temperatures of plasma here can reach 1 million degrees
Celsius.
The key lies in that plasma's density.
This 3D map from Zucker's 22 publication shows our local hot bubble in dark blue.
The density inside our bubble is extraordinarily low, containing about 100 times less hydrogen
than the typical interstellar medium.
So while the temperature of this gas soars to around 1 million degrees Kelvin, giving rise to the
diffuse X-ray emissions we have observed around the whole sky, we don't have much to worry about.
Tracking temperatures within the local bubble has provided more evidence of its existence.
The extended RENGEN survey with an imaging telescope array, better known as the E-Rosister
X-ray telescope, has been able to gather the most detailed all-sky survey of soft X-rays
to date, and that data has been used to map the LHB and our solar neighborhood in much more
detail than before.
Launched aboard the joint Russian and German mission, Spectrum Rengen Gamma, or Spectre-R-G in 2019,
data from the E-Rosita X-ray telescope has allowed a team of scientists led by the Max Planck Institute
for extraterrestrial physics to create a 3D map of the LHB and identify a temperature gradient
where the Galactic South was slightly hotter than the Galactic North.
This temperature dichotomy could be explained by supernova explosions in the past few million years.
And by creating this bubble map, the team also found that the LHB is stretched out towards
the poles of the galactic hemisphere.
This is because the hot gas in the bubble expands out in the direction with the least resistance,
which happens to be away from the Milky Way's galactic disk.
Along with identifying temperature variations and the shape of the bubble, the team compiled this
and other data to create an even more detailed map of our galactic neighborhood.
In the new 3D map, our local hot bubble looks like a three-dimensional splatter, surrounded by
and even overlapping other galactic structures. These other structures represent known supernova
remnants like the gum nebula shown here in red, and dense molecular clouds, shown here in orange.
With the new data and 3D maps, these super bubbles seem likely to be common in our galaxy,
creating a Milky Way that's sort of like Swiss cheese.
The cavities of our Swiss cheese galaxy are blasted out by gigantic supernova explosions,
with new stars forming along the edges of the holes created by dying stars.
And, like Swiss cheese, it appears that some of these super bubbles may have tunnels connected
them to other bubbles or other structures, suggesting our local hot bubble could be part of an
intricate network of similar features throughout our galaxy.
For example, we have the Canis Majoris Tunnel, which lies on the Milky Way's Galactic
Disc, and is believed to connect our local hot bubble to the Gum Nebula, or another larger nearby
super bubble. But the 3D map also revealed another, previously unknown interstellar
tunnel, stretching towards the constellation Centaurus, possibly connecting our local bubble
to the neighboring Loop 1 Superbubble.
While these interstellar tunnels are tantalizing, our current understanding of them is limited.
Nevertheless, these tunnels of hot gas and bubbles of star formation, shaped by the death of
gigantic older stars, has me in awe of how powerful and powerful and
interconnected the evolution of our local galactic neighborhood really is.
It suggests that stars are not just born and die in isolation, but that their energetic
output continues to mold the environment for millions of years after their demise.
And as our observational tools become more sophisticated, we are beginning to uncover
the extent of these hidden structures.
So next time you look up at the night sky, you might try to
remind yourself that we are surrounded by crazy patterns, just like our local bubble in the
Milky Way that was carved out by ancient cataclysms, and that some of those stars that you see
are actually plastered along the walls of a supernova blasted cavity, which connects to other
parts of the galaxy through interstellar tunnels. Wow. Thanks for watching. I really want to
give a huge thank you to our astromnauts on Patreon. It's really becoming a thriving community
and I've loved reading all your messages and comments over there. If you'd like to join in,
then you can visit the link in the description to become an astromnaut and bring the channel more
stability than the algorithm. When you join, you'll be able to watch the whole video ad-free,
see your name in the credits, and submit questions to our team. Meanwhile, click the link to this
playlist for more Astrum content. I'll see you next time.
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