Astrum Space - The Largest Observatory Ever Made Just Detected Something And It Blew Our Minds | Astrum Sleep Space
Episode Date: July 31, 2025Join with me today as we learn about the secrets of gargantuan gravitational waves, and the ingenious new method astronomers have used to detect them.A huge thanks to our Patreons who help make these ...videos possible. Sign-up here: https://bit.ly/4aiJZNF
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Tune into the universe with the right equipment and you will hear it humming, no matter where you look in the sky.
Of course, it's not possible for sound travel in the vacuum of space.
Instead, we are talking about the hum of gravitational waves.
You might already be familiar with a similar signal discovered decades ago.
It's called the cosmic microwave background, and it is the afterglow of the Big Bang.
This glow of microwave light was a groundbreaking discovery.
It was the smoking gun that solidified the Big Bang's place as the leading theory of our
universe is beginning.
Yet, this light signal had a glaring weakness.
Despite it being the earliest light of our universe, it was a very light of our universe.
It was emitted almost 400,000 years after the Big Bang.
If we want to go back earlier, we will need a background signal made not of light, but of the
ripples of the fabric of space-time.
In 2023, astronomers at the Nanograv collaboration have announced that, by using a clever
trick, they may have detected just that.
Using exotic stars as a galactic-sized gravitational wave detector, they measured the faint hum of
space-time itself.
This hum of gravitational waves might just be the reverberations of the very creation of our
universe.
I'm Alex McColgan and you're listening to the Astrum Podcast.
Join me today as we learn about the secrets of gargantuan gravitational waves and the ingenious
new method astronomers have used to detect them.
You may have already heard about the LIGO detector and how it uses lasers to precisely measure
the minuscule changes in the length of a tunnel caused by gravitational waves passing through.
These gravitational waves stretch and squish space-time, causing changes in the time it takes
for light to travel from one end of the tunnel to the other.
But detectors like LIGO are only sensitive to a specific kind of gravitational waves.
Like light waves and sound waves, gravitational waves can come in different frequencies,
and LIGO is only able to listen in to one part of this spectrum, the high frequencies.
That's when these binaries are spiraling in on each other rapidly, completing hundreds
of rotations per second before colliding in a great bang.
But that is also why LIGO cannot listen in on the much earlier stages of these binaries,
And the objects are orbiting each other at a much greater distance.
Because these orbits are much slower, the gravitational waves they produce are of a lower
frequency and energy.
So you could say, rather than a great bang, they give off a faint hum, combining into one
collective signal.
Bigger black holes give greater contributions to this signal.
The loudest contributors would consist of pairs of supermassive black holes, the kind
you'd find at the center of galaxies.
These binaries, which consist of black holes billions of times the mass of our sun, are expected
to be rare because they only form when something truly spectacular happens, the merger of
two galaxies.
When galaxies merge, because of the vast amounts of empty interstellar space in them, they
mostly phase through each other.
Very few, if any, actual collisions of stars or planets happen.
But the stars gravitationally attract one another and merge into one collective galaxy.
And the nuclei of these galaxies, the supermassive black holes, form binaries that continue
orbiting one another long after the galaxy merger appears to be complete.
It's these remnants of galaxy mergers that we would hear most strongly in the ultra-low frequency
range, specifically around the nanohertz range. Yet, just like how the human ear cannot hear sounds
with ultra-low frequencies, LIGO is deaf to this cosmic cacophony. If we could listen in,
we would gain new insight into galaxy mergers and black holes. But that's not all. One of the
most exciting things about the gravitational wave background is that it is a window to the very
first moments of our universe's existence.
Let's quickly recap what we know about the cosmic microwave background.
This microwave light is the earliest light that we can detect because for the first
400,000 years, the universe was opaque to light.
What does it mean for the universe to be opaque?
Initially, the universe was far too hot for neutral matter to exist.
and protons were unable to bind together and form neutral atoms simply because they had too
much energy. This state of matter is called plasma, the same stuff that stars are made of,
and the universe was filled with it.
Light gets trapped in plasma, unable to move through space without bumping into the charged
electrons and protons, being continuously absorbed and emitted.
But once the universe expanded and cooled down enough for the protons, the protons, and they
electrons and electrons to coalesce into neutral hydrogen and helium atoms, it suddenly became transparent.
The light was finally freed.
This light was then stretched by the expansion of the universe until it red shifted into
microwave light.
This is why the cosmic microwave background is the earliest light of the universe.
But gravitational waves are not made of light.
They are made of spacetime itself.
Plasma is no obstacle to them.
To gravitational waves, the universe has been transparent from almost the very instant of
the Big Bang itself.
They can penetrate past this plasma barrier and offer us a glimpse of the very first moments
of the universe's creation.
Because these primordial gravitational waves have been travelling for so long, even if they
were originally produced with a high frequency, they would be greatly stretched by the expansion
of space-time.
They would be redshifted into ultra-low frequency gravitational waves, the same kind that
would come from black hole binaries.
Together, these multiple sources will give us a so-called stochastic gravitational wave
background existing over a range of low frequencies.
How can astronomers retrieve this treasure trove of information about black holes, the Big
Bang, and more?
Can we build a better LIGO and detect how the Earth is bobbing up and down in the
these gargantuan gravitational waves. Well, LIGO works by sending two beams of light being
sent along perpendicular tunnel arms. The beams are reflected by mirrors at the ends of each
of those tunnels, and they return to the starting point, and are compared with each other.
This is so that if spacetime gets distorted along one direction, the information from the
other direction can be used to get a sense of how much it has changed. Unfortunately, if we
were to design a new LIGO to detect these gravitational waves, we would need to have tunnel
arms that are much larger than anything we could build on Earth.
This is because the frequency of a wave is inversely proportional to its wavelength.
Ultra-low frequency waves have an ultra-long wavelength and would require us to look at changes
over a much greater distance to notice the effects of these gravitational waves.
for nanohertz waves, that is, one full fluctuation taking a billion seconds, a quick calculation,
wavelength equals speed of wave over frequency, tells us that the wavelength would be around
10 to the power 17 meters. For a sense of scale, the distance between the Earth and the Sun,
or an astronomical unit, is 10 to the power 11 meters. A light year is around 10 to the power 16
16 meters. The wavelengths we are discussing are tens of light years long. Clearly, we cannot
build anything suitable for this task on Earth, or even in the solar system. We need to
go beyond our stellar neighborhood. But rather than wait for humanity to ascend beyond
the confines of our solar system and become a space-faring civilization, astronomers at
nanograph have used a clever trick.
The key to this trick involved pulsars, ultra-dense neutron stars which are able to spin
with remarkable stability.
They emit light along their poles, and we can detect the pulses that we receive as those
vast beams of light swoop around and hit the earth again and again.
These pulses come with such precise certainty that they are used as clocks of the cosmos,
able to keep time across vast distances.
Therefore, we can use already identified pulsars to supply us with reliable signals from thousands
of light years away.
The pulsars are like the mirrors at the end of the LIGO arms, but rather than sending us back
a signal we send across, they are generating their own.
Nanograph have cleverly concocted an imaginary interferometer that stretches for thousands
of light years, and all we need to use it are the good old radio telescopes that we've
been using for decades. But our calculations will only be as good as our observations.
When choosing pulsars to observe, we need to make sure that they are suitable for the task.
The best candidates are handpicked and added to a group called a pulsar timing array.
For nanograv, they have made use of 68 pulsars which were chosen for the following special
properties. They had to be spread all across the sky.
we can figure out how these massive gravitational waves are affecting space time in all directions.
Also, they had to be millisecond pulsars, which means they complete millions of rotations per second.
These fast spinning pulsars are expected to be the most stable and dependable when it comes to the
regularity of their pulses. In fact, their stability even rivals that of some atomic clocks.
We could not ask for better timekeepers to be dotted across space and time.
This regularity means that we can take measurements of the time their pulses arrive and
continue taking these measurements over multiple years to see if there are any changes happening.
Of course, the times of arrival can vary due to all sorts of factors, such as the change
in distance between the Earth and the pulsar, as both objects continue moving around space,
but we can take this into account quite easily.
However, there are less predictable factors, such as random fluctuations in the interstellar
gas the light is travelling through, causing delays that aren't coming from the stretching
of space-time.
How do we get rid of the random noise in our data from pulsars located thousands of light years
away?
With statistics, we can isolate the gravitational wave background from the random noise by considering
correlations between pairs of pulsars in the pulsar timing array.
Like LIGO, one tunnel isn't sufficient.
We need two pulsars on each end of our imaginary tunnels.
If similar fluctuations show up with two pulsars, it is unlikely that the random noise
aligned in such a way to make it appear, by chance, that they are acting in unison.
It is far more likely that there is a common cause underlying both those fluctuations, such
as the possibility that the photons from the two pulsars are riding the same gravitational
wave that are washing by them both.
We can then, on a graph, relate these correlations of pulsar pairs with their angular distance
in the sky.
If there is no gravitational wave background, we expect there to be no correlation, and the
graph to show a straight line at zero.
However, if the data shows a special curve called a Hellings and Downs curve, that would indicate
that a gravitational wave background is responsible for the variances.
what nanograv have succeeded in doing.
On the 28th of June, 2023, based on over 15 years of continuous observations of their 68 pulsars,
they announced strong evidence for the gravitational wave background.
This is the proof that we've been waiting for.
The error bars in the data appear quite large, but the researchers have calculated that the data
shows that the existence of a gravitational wave background is statistically significant
at the 3-Sigma level.
This means that there's only a 1 in 1,000 chance that this is a false alarm and that this data
was the result of mere chance.
In physics, the 5-sigma level is considered the gold standard for a discovery, but 3-Sigma
is still very strong evidence.
As they collect and analyze more data, astronomers will be able to reduce those error bars and
finally announce an official discovery.
So, what secrets does this gravitational wave background reveal?
While we cannot pick apart the sources of the collective noise just yet, we hope that these
techniques will eventually allow us to listen in to specific supermassive black hole binaries
and figure out what the signal can tell us about the creation of the universe.
Until then, astronomers will continue to use their galaxy size detector to calculate how
we are bobbing up and down in the turbulent sea of spacetime.
Well, that's all we have time for today.
I hope you've enjoyed listening to this podcast on studying gravitational waves.
If you like what you've heard, please feel free to follow us for more podcasts on other
fascinating space topics.
But for now, I'm Alex McColligan, and this has been Astrom.
All the best, and see you next time.
