Into the Impossible With Brian Keating - Avi Loeb: What Is 3I/ATLAS?
Episode Date: December 23, 2025Please join my mailing list to get FREE notes and resources from this show, plus your chance to win a real meteorite: http://briankeating.com/yt Join us LIVE with Harvard astrophysicist Avi Loeb for... the final verdict on the interstellar object 3I/ATLAS, the third confirmed visitor from beyond our solar system. We examine the newly proposed 14th anomaly: the remarkably rare alignment of 3I/ATLAS’s rotation axis within about 8 degrees of the sunward direction at distances greater than 5 AU, a configuration with a probability of less than about 0.5 percent if random. This alignment has major implications for how we interpret the object’s anti-tail jet geometry, rotational dynamics, and overall physical behavior, adding to a growing list of anomalies that strain standard cometary explanations. Whether you are interested in jets, rotation periods, anti-tail physics, or what these observations imply about natural versus technological origins, this livestream offers a rigorous, evidence-driven deep dive. We will lay out the data, compare competing interpretations, and ask the central question: is 3I/ATLAS simply an unusual comet, or something fundamentally different? - Run of Show 00:00 – 02:00 Intro and context: Discovery of 3I/ATLAS, orbital properties, and why it has drawn intense attention. 02:00 – 05:00 What is an interstellar object: Comparison with 1I/Oumuamua and 2I/Borisov. 05:00 – 10:00 Anomalies 1 through 5: Brief recap of the earliest reported oddities, including trajectory and activity. 10:00 – 15:00 Anti-tail observations and physics: Explanation of the sunward anti-tail and why it is unusual. 15:00 – 20:00 Rotation period and periodic behavior: Discussion of the roughly 15.5 to 16.2 hour signal and its interpretation. 20:00 – 25:00 Recap of the first 13 anomalies: How they are ranked by likelihood and what they suggest. 25:00 – 30:00 The 14th anomaly: rotation-axis alignment: Geometry, probability estimates, and why this feature stands out. 30:00 – 35:00 Possible mechanisms for axis alignment: Assessment of natural processes versus alternative explanations. 35:00 – 40:00 Jet collimation and structure: Why the sunward jet remains narrow and persistent. 40:00 – 45:00 Implications for outgassing models: Where standard cometary physics succeeds or fails. 45:00 – 50:00 Natural versus non-natural scenarios: Clear comparison of competing hypotheses. 50:00 – 55:00 Future observations and missions: What additional data could resolve the debate. 55:00 – 60:00 Audience Q and A: Live questions with Avi Loeb. 60:00 – 65:00 Wrap-up and final thoughts: Synthesis of the evidence and implications for future research. Learn more about your ad choices. Visit megaphone.fm/adchoices
Transcript
Discussion (0)
It's peak pollination season, and my business is scaling fast.
To keep the nectar flowing, I need a phone plan with top priority data speeds.
That's why I chose Google Fi Wireless.
My connections stay strong even when the hive is buzzing.
Plus, unlimited plans started $35 a month.
Now that's a deal that doesn't stay.
Explore Google Fi Wireless plans today.
Plus taxes and government fees.
Google Fi Wireless is not subject to data traffic deprioritization during times of high network usage.
You said this place was steps from the water.
We just haven't found the steps yet.
How much did we save?
Enough.
Enough to get lost.
Or you could book a stay with Hilton.
Welcome to your oceanfront room.
Just steps from the water.
The Hilton sale is on now.
Book on Hilton.com or the Hilton app
and save up to 20% to get the stay you expected.
When you want savings, not surprises.
It matters where you stay.
Hilton for the stay.
We are live and it is exciting to welcome my good friend Avi Loeb all the way from chilly Boston.
It's chilly here in San Diego. How is it there in Boston, Avi?
Well, it's very cold. It was five degrees below zero.
Water would have frozen, but there wasn't any water so I could jog before sunrise this morning.
Oh, that's right. That's your calling card. You're jogging for me in spirit. I'm with you in spirit, Avi.
You know, it's not, it's not that easy for me to get up so early at that time.
But I'm trying.
You inspired me.
This year I dropped five pounds, Avi, from my chin to my stomach.
So you inspired me, Avi, and you may continue to do so in the new year.
So this has been a wild year.
We started talking about phenomena way back.
We've talked for half a decade already.
I've known each other for more than a decade now.
But we'd start talking about this mysterious object, three eye atlas, which
Some said, could be technology.
It could be something reminiscent of consciousness,
or maybe it's some sort of a spaceship that's going.
I'm using all the Hanukkah gifts.
My kids got me out of here.
Avi, where are we at right now?
You just have an amazing output as normal.
You have a bunch of articles.
We're going to go over some questions from the audience.
From the members of the channel, you
have to be a channel member to ask questions.
Just the way to give back to my channel members.
But tell me, Avi, where are we at right now?
What is your latest assessment?
And I'm going to show some of the great medium articles that you've been writing.
But where are we at?
What have we learned what questions still remain?
So let's start with what is or was 3-Ey Atlas and where is it right now?
Well, thanks for having me.
The best is yet to come because this object, the third interstellar object from outside
the system that was spotted by telescopes passed closest to Earth on December 19th.
And it didn't do any maneuver.
It didn't show any unusual activity.
And it basically ignored Earth.
And it came closest to the sun on October 29th.
And at that point, it was on the opposite side of the sun relative to us.
So it wasn't even observable from Earth with our terrestrial telescopes
because they needed to be at least 30 degrees.
away from the sun for us to observe it.
So what I often say to people who ask me about it is that, you know, we arrived to the cosmic
party, the block party of our local neighborhood.
Just over the past few million years, the human species, any object entering the solar system
probably spent billions of years traveling through the solar system at the current
characteristic speeds of, you know, three-eye atlas, this object,
which is about 60 kilometers per second.
It takes, of order, a billion years to cross the Milky Way disk.
And at that, if you go back a billion years, we were not around.
Jupiter was the most prominent planet still is, the most massive, 318 times the mass of the Earth.
So we shouldn't be surprised that if we arrive late to the party and we are not at the center of the room,
We know that we are moving around the sun and the sun moves around the center of the Milky Way.
And then, you know, we shouldn't be surprised that nobody wants to dance with us so late in the party.
But at any event, a three-eye atlas is an object discovered on July 1st by the Atlas telescope in Chile, half a meter in size.
This object was very bright and we still don't know its size.
I mean, the initial estimate was if the brightness we see from the object is due to a reflection
from a solid body, then its size needs to be 20 kilometers in diameter.
And that is comparable to the size of Manhattan Island or the asteroid that killed a dinosaur
66 million years ago. These objects are extremely rare. And that was surprising. But by now we know
that most of the light is actually from a plume of gas around it. And that plume of gas contains
all kinds of unusual molecules or elements, atoms.
For example, most recently there was methanol detected
with two orders of magnitude more methanol than hydrogen cyanide,
which is a very unusual ratio.
And the thing about hydrogen cyanide and cyanide was also detected in it
in it is that it was used as poison gas in the First World War.
So actually, just this morning, I calculated whether any concern that, you know, as we approach
the holidays, a lot of people are anticipating gifts from their family members, the question
is, will three-I Atlas, any of the material coming from it, will it deliver a gift from
interstellar space to Earth? And the answer is probably not, because if you calculate from the
mass loss rate that was measured by data from the web telescope. If you calculate the distance
where the gas would be swept by the solar wind, that distance is only a few million kilometers.
And the closest, the three Atlas got to the circle of the Earth moving around the sun was
about 50 million kilometers. So there is no way that this gas would cross the path of the
earth because it will be swept away from the sun by the solar wind.
But I do need to point out, Avi, in the spirit of the holiday season, that you, although
Three Eye Atlas won't provide you with any gifts on Earth, you can get a real-life fragment
of a...
Within this intrasteller asteroid that produced a Campo di Cello meteorite shower down in Argentina.
You can get that if you're one of the lucky winners each month at Brian Keating.com slash
or if you're like me and Avi and you're blessed to live in the best country in the world,
the United States, and have a dot edu email address.
Go to briankeen.com slash edu, and you will get a fragment of these guaranteed.
So Avi, back to your description of the gifts or lack thereof.
Yeah, yeah.
So no gift made of gas, but then you ask, okay, what about particles?
And dust particles that are smaller than a micron would be swept by the solar radiation away from
the sun.
so again not intercept the orbit of the earth.
And then bigger particles, bigger, let's say, than a millimeter,
will not be affected much by the solar radiation,
the solar winds.
So they could potentially rain on Earth.
But such particles would burn up.
Any particle much smaller than a meter burns up in the Earth's atmosphere.
So it will never reach the ground.
We shouldn't worry about it.
And then bigger than meter, there aren't enough such objects.
that could be shed by three-a-atlas based on the mass roast rate that was measured for us to worry
that any of them would collide with the earth. So I did this calculation. It doesn't look like we'll
get the gifts. It ignores us in terms of the trajectory. And the interesting point is that it's
heading now towards Mars. It will get, sorry, towards Jupiter. It will get to Jupiter on March 16th,
26 and actually it will arrive exactly at the distance which is called the hill radius where
jupiter's gravity dominates over the sun's gravitational tide and the question is whether that
has any significance but it's it's arriving at 53.5 million kilometers from jupiter and that's very
close to where the hill radius is and by the way the hill radius is. By the way the hill radius is,
is also the separation of the Lagrange points
from any massive object.
And it's a good, the Lagrange points
are a good place to deposit devices
because they don't need much fuel to stay there.
We put the web telescope at the second Lagrange point
from Earth.
And so it would be interesting to watch it all the way to Jupiter.
And after that, if nothing unusual is observed,
then of course I will downgrade the rank of this object
to potentially,
or most likely a natural object.
And in fact, I always thought that it's most naturally a natural object.
But I think that we must consider the possibility of it being technological
because of 15 anomalies that I noticed.
And those 15 anomalies that I listed in one of my recent essays
require that we take the technological option seriously.
Why is that?
for the same reason that intelligence agencies revised their practices after September 11th, 2001 and October 7th, 2023.
They did that because they realized that Black Swan events should not be ignored.
These are events where we assign a small probability for them materializing, but nevertheless, we should spend resources in collecting as much data as possible to prevent
them from materializing. And that was the mistake made on both dates by intelligence agencies saying,
oh, it's very unlikely that something that would happen. And scientists, you know, very often do the same,
take the same approaches as was taken before these events and say, well, at the 99% confidence
level, you know, we believe this is the correct interpretation. Now, in most cases, there are no
implications to society. Like, for example, a week ago, there were two papers published in Nature
magazine about the experimental searches for a ghost particle called sterile neutrino. And they both
failed to find it. And it was originally believed to exist because of anomalies in previous
experiments. Now, the fact that it could have existed or that it doesn't exist makes no
difference to our daily routines.
That doesn't affect society at all.
And most of the time, you know, even with significant discoveries, academic discoveries,
there is no impact on society.
So scientists are used to that situation.
Thank God.
Thank God there's no impact of our faculty committee meetings, obviously.
I mean, that would be a fate worse than cyanide coming down there.
I mean, think about being run by, as William F. Buckley Jr., I think so, you know, the first
a hundred people in the Boston phone book versus your fellow colleagues at Harvard.
I know what I would take, Avi, but thank God we don't have to worry.
We only have to worry about cyanide from comments.
But go on, go on.
Actually, Henry Kissinger said that he, when he decided to go to Washington, D.C.
and leave Harvard.
He had an appointment there as a professor, but he had to give up because there is a rule
that Harvard faculty cannot take a leave for more than two years.
And he said that at universities, professors spend a lot of time on inconsequential decisions, like where to put the bicycles, you know.
And whereas...
What time to have the faculty meetings.
In politics, you know, he was attracted by the impact of the decisions to, you know, society.
And so anyway, coming back to what I said before, I think this is a
a situation where we have a visitor to our backyard. There is a chance that this visitor will
enter through our front door. So if you see an animal in your backyard, you can say, well,
it's most likely a street cat. But then if you find that the tail is coming from the forehead of
that animal, then you should start asking questions about whether it's indeed a street cat. And the
reason I bring this up is because three-eye Atlas is showing a gym.
jet that is going in the direction of the sun.
Instead of going away from the sun, the way that cometary tails look like,
where they are pushed, I mean, the gas and dust making up the plume of gas and dust around the object,
they get pushed away from the sun by solar radiation and solar wind.
And so in the case of three Atlas, from the beginning on July 21st,
when the Hubble Space Telescope took an image,
it was clear that there is elongation of the glow around it
in the direction of the sun by a factor of two.
And then when you correct for the projection angle,
you find that the elongation is actually a factor of 10.
So there is actually a jet that is 10 times longer
than it was wide in the direction of the sun.
And actually right now, we are also seeing a similar jet
from three-eye atlas towards the sun, again, very tightly collimated,
10 times longer than it is wide,
and stretched over a million kilometers.
We've never seen an anti-tail, a jet from a comet that stretches across a million kilometers
in the direction of the sun being the most prominent feature that one can see in the image.
And is that, is that when you compare, I'm sorry,
When you compare Three-I Atlas to Omuamu and Borisov, is that the main anomaly that clearly breaks the pattern of, you know, purely non-anomalous or, you know, kind of homogenous compared to previous examples?
Is that the most likely?
In terms of the properties of the object, because another thing that was pointed out in a paper just a week ago is that we see a wobble of this jet, the antitail.
We see that it wobbles by eight degrees around the rotation axis.
of the object. So think of it as a procession of a pulsar, a pulsar beam of light or a lighthouse,
where the beam of light is not aligned with the rotation axis so that you get wobbling. And the
point is that this rotation axis is in the direction of the sun to within eight degrees. And
why would an object coming from interstellar space have its rotation axis?
aligned with the direction of the sun at large distances.
This is really surprising.
And it means that the object has a permanent dayside and a permanent night side.
And the jet is emitted from a base.
It's launched from a base very close to the pole,
one of the poles of the object.
And that was when it was arriving to the sun.
Now when it's receding away from the sun,
there is, again, an antithel.
But it must originate from the opposite.
pole. So somehow, if you think about, let's say, the conventional interpretation, you would say
there is a pocket of ice near the North Pole and near the South Pole. And that pocket of these two
pockets of ice dominate the evaporation. And so when one of them gets illuminated by sunlight,
you end up getting a jet in the direction of the sun from one pole. And when the other pole gets
illuminated by sunlight, you get it from the opposite direction. The problem is that
If you just have a pocket of ice on the surface of a rock,
it will not generate a very tightly collimated jet.
It will evaporate to a hemisphere.
And then, you know, this very broad fan of gas coming out will get pushed back by the solar radiation and wind.
And so that's what we see in comets.
We end up getting a cometary tail.
Here we see a very tightly collimated jet.
So how can you collimate the outflow?
of gas from a pocket of ice.
Well, one way is you drill a hole.
So you have a pit.
And at the base of the pit, there is some ice.
But that would mean that in order for the sunlight to reach it,
it really needs to be, the sun needs to be overhead.
And that will happen only for a short period of time.
So it's really not easy to collimate the gas that comes out of a pocket of ice
sublimated by sunlight.
And all I'm saying is we can't argue that we understand this object until we explain how
the jet gets collimated and why is it in the direction of the sun and how come that it's
always in the direction of the sun even when the object, you know, moved.
Your summer starts now with Memorial Day deals at the Home Depot.
It's time to fire up summer cookouts with the next grill, four-burner gas grill, on special
buy for only $199 and entertain all season with the Hampton Bay West Grove seven-piece outdoor
dining set for only $499. This Memorial Day get low prices guaranteed at the Home Depot.
While supplies, price invalid May 14th or May 27, U.S. only exclusions apply, see Home Depot.com
slash price match for details. Now to recede away from the sun, so you do see the anti-tail
is more prominent than the tail in those latest images. And because the way,
was a second Hubble image taken on November 30th. And again, it shows an allegation primarily in
the direction of the sun. So this, you know, this is that just as a non-expert? How rare is that for
comets in our own solar system to have an anti-tail? We don't see. We don't see an anti-tail. I mean,
we do see situations where it looks as if. Not parallax antitail, but actual. Yeah, exactly.
That's it. So that happens to be a perspective, an effect of perspective. When the earth is at the right
angle, it looks as if there is a tail pointing at the sun, but it's not really because we're
just seeing it from a strange angle that gives us that optical illusion. Other than that,
there are cases where there is a little bit of extension of the glow around the comet in the
direction of the sun, and that's the gas being sublimated from ice on the sun-facing side.
But then soon afterwards, everything gets deflected backwards.
you do see a much more prominent tail.
And so that is not really an antitale of the kind we see now,
because right now we see a jet stretched over a million kilometers.
That's two and a half times the distance to the moon.
Just think about it as if the earth were to generate a jet that stretches a few times farther than the moon.
That's a huge jet.
And it's persistent, right?
I mean, Avi, how long has the antitail been observed for?
months now. From the beginning until now. So we see it. Now, and it's also, you know, at the beginning, at least, we saw it wobbling around the rotation axis. So there are all these geometric coincidences of the rotation axis being aligned with the direction of the sun, which need not be the case. I mean, it's a half a percent chance of that happening. And then half a percent chance that you get your jet within eight degrees of the
rotation axis. So there are all these geometric. I just want to pause for one second to just set the
stakes for everybody else out there. From the beginning, Avi has maintained that the most likely
explanation for this object was that it was a normal natural forming object. It had some
probability, though, of being unnatural. I think that's any scientist should say that. Even if they
think that probability is less than, you know, a part in a billion or something like that,
You set the probability maybe higher than others, but from the very beginning, as a good scientist should,
Avi has been very steadfast that this could be a natural object. And so from the beginning,
I've asked you, Avi, even, well, I shouldn't say even if, I said when, if indeed it does turn out to be
beyond the lobe scale, you know, the lowest level of the lobe scale, i.e. it is natural. Then what would
we learn about commentary and solar system and extra solar objects? That would be interesting.
And there you also made the point that this object is revolutionary.
So I think it's important for the audience of lay people that may be in the audience,
although we have the smartest audience in the known multiverse,
that the object has taught us a tremendous amount of information.
And I don't think, Avi, you can't say this because you're too, you're too smooth,
you're too humble.
But I can say it.
I don't think a lot of the attention would have been paid.
I mean, a lot of great scientists have studied this object.
But I think you gave a special spotlight to this object.
and I think you do deserve credit for that.
Thank you. Yeah, I mean, I had an interview with the former speaker of the house,
Noot Gingrich, who has a podcast.
And just before it started, he thanked me for bringing so much attention to space exploration.
He said that, you know, that's a subject that deserves much more attention.
And there wasn't much given to it before I started speaking about three Atlas.
So he was very grateful.
And of course, there are these parents that are grateful because their kids now want to pursue.
to science after they heard me speak on television or podcast.
So, you know, irrespective of what the nature of three-A Atlas is,
it clearly served a very important purpose where people were curious about its nature.
And the way I approach it is that science is work in progress.
You know, it's a learning experience.
And why would we pretend to be the adults in the room that know the answer in advance
when we can actually collect data and ask questions?
In fact, the more questions we ask, the more we can learn.
And there is no reason to assume that it's the same type of comets that we have in the solar system.
It may be coming from a completely different environment.
Just to give an example, it may have originated from a molecular cloud.
And that's why it has mostly carbon dioxide.
I mean, who knows?
It may not be from a protoplanetary disk.
And so people make assumptions.
They initially said, well, it must be water rich.
But it's not water rich.
Why pretend to know the answer?
Let's just figure it out and let's be curious about the anomalies.
I think that's a fundamental aspect of science.
And we know that because both of us work in cosmology
and there are lots of questions in cosmology that are not resolved.
And nobody punishes a theorist that puts on the table additional possible explanations.
You know, right now there is the possibility that dark energy may be evolving.
So I wrote a paper saying, no, it's not the dark energy evolving.
It may be the dark matter is evolving.
And nobody went after me, you know, no zealot started saying bad things about my character
just because I said that.
Why?
Or that you're a cult leader.
Remember, you're a cult leader according to some of the professionals.
I don't have any social media and I don't lead any cult.
I just say what sounds to me like reasonable.
But the point is that science is done very often in exactly this fashion.
for those zealots, for people who are not even practicing science to resist
a hypothesis making just because they don't like those hypotheses is anti-science.
This is not the way.
Now, the other thing that happened was that I was interviewed just a few days ago by News Nation.
And the digital media group at News Nation decided to make a big deal of the fact that they said
that it's most likely a natural object because they said, oh, he changed his mind.
I didn't change my mind.
I said it from the beginning.
If you look at my first paper on technological possibility of three-eye Atlas,
I just said there that it's most likely.
You said it on this podcast.
Yeah.
And I said it many times.
And so they decided to make a splash just out of this statement as if it's new.
And then, of course, a lot of those critics said, oh, he's changing his mind.
I didn't change my mind.
So I wrote, I tried to explain that yesterday.
there, I wrote an essay, basically it's showing, now it's all in writings, so I can point to links of
where I said what, and you can just read those things, and you will find it there. Now, what really
happened is reporters are trying to make statements that attract clickbait. So they say, he is
predicting that this is technological. I didn't say that. And so then other people respond to what the
reporter said as if this is what I said. So distortions by the media trigger a negativity from some
people, but they are, they should understand that they are just responding to the reporter who made
an incorrect statement based on what I said. So this is an unfortunate reality, but there is an
even more unfortunate aspect of the reality that we live in. And that is that a few weeks ago,
there was a YouTube channel after with my name on it, where they used AI to generate
the creators generated content videos with me saying deep fake.
And of course, some fans wrote to me and said,
this must be fake because the clock behind you is not changing.
You know, the time is not changed.
And also it contradicts what you said in your medium message, they said.
And I wrote to YouTube and they took them some time,
but eventually they responded and said,
Why do you think that it invades your privacy?
And I said, look, this is, someone is stealing my identities like an imposter that is trying to make money possibly out of making content after my name.
And this is inappropriate.
And in fact, I was in consultation with legal advisors at Harvard about it.
And also a reporter from Futurism wrote an article about it.
and NBC News invited me for an interview that evening.
So I said the story will get bigger unless you correct it.
So then they removed the YouTube channel and they made a statement to NBC News that appeared when I was interviewed there.
And then, you know, obviously this worked, but only for one week.
And by now there are many other channels that are under different names creating fake videos.
So I mean, they say imitation is the sincerest form of flottery, but I don't think that's going to be.
the case. I think it's bad for YouTube. I think it's bad for YouTube. Let's go on. And by the way,
it's bad also for science because the biggest enemy of science is misinformation. So if you have
content that people believe to, and in fact some reporters even put video excerpts from this fake
account on their reports, as if I said those things, you know, that generates an intellectual
climate of misinformation, content that is taken out of context that has nothing to do with what I really want to say.
And that is pretty bad.
And I'm sure I'm not the only one.
And I'm sure it will be a very important challenge in the future.
And my advice to young people is always go to primary sources.
And in my case, interviews like the ones, the one we have right now or on television or my essays on.
medium.com, but these are the primary sources where you can see me speaking with someone.
They cannot easily fake that. Right. Exactly. It would take a lot more to do that. I mean,
I've always said if you can fake being sincere, then you're really fantastically well off.
Okay, Avi, the other thing that you've talked about recently that we haven't talked about
is this kind of 16-hour heartbeat that you mentioned is one of the anomalies. Can you talk about
this? What is this period of city? I wasn't familiar with it until this most recent medium piece.
Is this a rotation period?
And then most critically, could it be an instrumental artifact?
No, so that was reported back at the end of July observationally.
So first of all, they detected the brightness of three-eye Atlas repeating every 16 hours
and with some pattern.
So there was some modulation of the brightness.
And the authors of that paper assigned it to the object being a spheroed, like a food,
ball so that as it rotates and it reflects different amounts of sunlight.
But that must be wrong because only about a percent or less of the light that we receive
from Theratlas comes from the nucleus itself.
We know that from the Hubble image that the brightest pixel that contains the nucleus
accounts for less than a percent of the total light.
So then you cannot get variations at the level of 20 percent just by the object rotating
and showing us a different surface area
that makes no sense whatsoever.
I don't know, I mean, again,
this is a paper that was peer reviewed, published, and celebrated.
People make mistakes, okay?
So that cannot be the explanation
because we know that there isn't enough light
coming from the nucleus to explain 20% variations,
modulations every 16 out.
So I suggested that instead what happens is
we know about the jet, the antitail,
and so imagine a jet coming from
the object and that jet is being, you know, is moved around. It wobbles because of the rotation.
Okay. So it wobbles around the rotation axis and because of that, the amount of light that you see
reflected sunlight from the particles in the jet, that gets modulated. So the variations are because
the jet itself is wobbling and you are seeing variations in the brightness as a result of that,
because the jet is creating also the comma, the plume of gas around the object.
So when you need to build up your team to handle the growing chaos at work,
use Indeed-sponsored jobs.
It gives your job post the boost it needs to be seen
and helps reach people with the right skills, certifications, and more.
Spend less time searching and more time actually interviewing candidates who check all your boxes.
Listeners of this shell will get a $75-sponsored job credit at Indeed.com
slash podcast. That's Indeed.com slash podcast. Terms and conditions apply. Need a hiring hero? This is a job for
Indeed sponsored jobs. Now, you can think of it like a heartbeat, because in the case of a heartbeat,
you have, you know, the pulsations of the bloodstream into the veins and that origin is from the
heart. And in this case, you know, the object itself is basically pulsating in the
material that it sends into the surrounding plume of gas through the jet.
And so it's sort of like a heartbeat that every 16 hours it repeats as far as the observer is
concerned. And so that is my interpretation. I, you know, it's relatively straightforward. And I didn't
publish it, but this seems to me like the most natural way of explaining the variability of the object.
And then we don't have a similar measurement after the object passed closest to the sun. I'm waiting
for that data.
And the other kind of anomalies that we have to always be mindful of at least is what sorts
of, you know, kind of multiple in a Bayesian sense, probabilistically, are there correlations
between some of these anomalies, you know, the rotation axis alignment, the jets, the alignment
with the solar system? I mean, there are many, are the plan of solar system?
Yeah.
Are there any hidden, you know, off-diagonal elements in the covariance matrix?
and ASEAN LIBRAD.
I mean, let's just explain what could go into it.
What assumptions could go into?
Yeah, so one of the anomalies is the very high polarization,
and unprecedented polarization of the light coming from 3-I Atlas.
And that could be indeed the result of the jet,
you know, because of the tightly collimated jet 10 times longer than it is wide,
going out to a million kilometers right now.
So that could result in polarization that is a new,
is unusual because of the asymmetry of the jet. So indeed you are right that some anomalies may be
related to others, but for example, the alignment of the trajectory with the plane of the planets
around the sun, you know, the ecliptic plane, you know, there is no simple way to explain that
because the disk of the Milky Way galaxy is misaligned by 60 degrees relative to the ecliptic
plane. So if the objects come from the disk of the Milky Way galaxy, why would the, you know,
the third one select the ecliptic plane,
when the chance for that happening to within five degrees
is one in 500.
So you would need hundreds of objects before one of them
will likely be in that plane.
And we had only three, this is the third,
we had two before that.
I should also say that when people claim
that they are comet experts,
and they should be believed as authority on this subject,
there are no experts of,
of interstellar objects because we had only two detected by telescopes before three eye atlas.
And therefore, you know, we should be open-minded.
My basic point is there is a lot for us to learn.
And I would love to actually scoop one of the future interstellar objects
and bring some materials to Earth so that we can check if that material has the building
blocks of life, as we know it.
even if it's a rock, you know, it's the first time we would have access to actual material
from a big object that came from another star.
And finally, I would say that if I had an opportunity to hitchhike 3A Atlas, I would love
to take it for a ride out of the solar system.
I mean, I wouldn't survive that long.
It will take it 8,000 years to get out of the solar system by the year 10,000 C.E.
You know, so by the year 10,000, it will actually exit from 100,000 times the Earth's sun separation.
That's the edge of the ore cloud where out to which we have objects still bound by gravity to the sun.
Well, you keep jogging, Avi at 3 in the morning and you'll undoubtedly get there or not.
By the way, I should say, I just wanted to compare that to Voyager.
You know, Voyager, you can ask, how long will it take Voyager to get to the same distance?
it will take it 28,000 years.
So Voyager will get out to the outskirts of the solar system by the year 30,000 C.E, whereas
Three Atlas will do it much earlier.
So I would much rather, you know, if travel agencies will at some point sell tickets, I would buy one.
And I would love to ride such an object, a fast object like Three Atlas, out of the solar system.
I think, yeah, I think we can start selling shares in that to,
to supplement their academic incomes.
Okay, so speaking of fun things,
I've been asked by people in my offline mailing list
that you can get to atryancaiton.com slash yT,
and again, you'll enter to win a real fragment of an asteroid
that's 4 billion plus years old.
Older than our Earth, right, Avi?
I mean, these meteorites form from some object before that exists.
Is there a name for the solar object that exploded a type 2 supernova,
I presume, that created our solar system?
Yeah, in fact, now.
we have more data about our immediate environment, you know, some tens of light years around us,
there is a bubble where a group of about 10 massive stars, you know, finished their life and
exploded, presumably in multiple supernovae about 10 million years ago. And so the sun may have formed
as a result of the blast wave created by this explosion. We can see the location where, you know,
if you look at the bubble, the hot bubble of material of gas,
you know, the sun is offset from that center.
And in fact, the original stars, the remnants of whatever resulted from those
stellar collapses and explosions, the remnants must have been kicked out of that location.
We haven't found, for example, a pulsar yet or a black hole remnant.
But definitely there was some violence in our neighborhood that led potentially to the
formation of the sun 4.6 billion years ago.
And so there was a, the clump of gas that made the sun, you know, could have resulted from the blast wave
because the blast wave from these stellar explosions condensed the gas.
And then these blast waves often are unstable to fragmentation. So they make clumps.
And one of these clumps was the proto sun cloud. And as the material reigned in to make the sun,
It had some rotation, some angular momentum that created a disk of gas through which the sun was fed early on.
And a small fraction of the mass was left in that disk about a percent or so, which then started making the planets.
And they all move in nearly circular orbits.
And that's why we have the ecliptic plane as the characteristic plane of the planets orbiting the sun.
And they were probably worried about something like their Instagram followers.
you know, right before 10 supernovas went off, Avi, right?
Knowing the nature of consciousness.
Okay, so I have a playful question that came from offline.
You'll be taking questions from the audience, members of the channel,
which means you pay a huge fee of 99 cents or more a month to support the channel.
It costs thousands of dollars to run the channel, team of people.
And it's been a phenomenal year, Avi, I don't know if you knew,
but I won this huge, massive award.
I have it in the back there.
I can't even pick it up.
Maybe you could pick it up.
You're so buff, but it weighs about 16 pounds of pure copper from the Signal Awards,
listeners choice award that I won this year.
It's been great.
We reached top eight podcasts for a day on Spotify.
It's been an incredible year.
Next year is going to promise to be even better.
Great guests are coming on as usual.
But my audience has asked questions, including this one.
If an engineer were asked to design a propulsion system that produce a very tightly collimated,
persistent sunward jet like Atlas observed, like Atlas is observed to have,
what constraints would immediately jump out to him, it, clock,
whatever you call this object, their pronouns in this other galaxy.
What sorts of engineering constraints would they face?
Yeah, so that's a very interesting question.
So the question is, why would we have a sun-facing jet?
What would be the purpose of that?
You know, in the first half of the orbit of Tri-I Atlas, you might have thought it may be related to some attempt for maneuvering, but not really because it was in the direction of motion and now it's opposite of the direction of motion.
The only sensible thing is, so it wasn't also to clear out the objects in front of it or to illuminate the path because now it's opposite of the direction of motion.
The only sensible thing is that the solar wind may cause damage on a technological device when it impacts the surface because it releases of order 100,000 times the energy per net mass of T&T.
The solar wind is moving at 500 kilometers per second.
So when it impacts the surface of some technological device, it may cause damage.
So when you approach a star, you might want to deflect the solar wind.
And one way to do that is by creating a jet ahead, always towards the sun that deflects the solar wind.
So that is the only thing I could come up with.
But I would argue that it's really difficult to guess the mind of technological designers.
And that's what makes it difficult because, you know, I had some exchange with Professor Josh Wynn from Princeton
where he said, could you forecast the technological signatures of an interstellar object
And the problem is that, you know, we don't know who sent a technological object to our backyard,
and therefore we don't know the intent.
It's really difficult to guess ahead of time what would be the technologies that are employed
and what would be their signatures.
One thing we can look for is, of course, outliers, objects that have unusual behavior
that we've never seen before.
And that's the purpose of me putting out this list of anomalies that I mentioned,
because that's the only way for us to make progress.
Basically, ask, is there anything that distinguishes this object from the normal comets that we're
familiar with? There was nothing really substantial about Borisov, the second interstellar object.
It looked just like a comet from the solar system.
There was a lot different in the case of Omuamua, but in a different way, it was definitely not a comet
of the type that we are familiar with. There was no gas or dust around it,
and then it exhibited the non-gravitational acceleration.
So at first people said it's a comet, but then there was no gas or dust.
They said it's an asteroid, but then it showed non-gravitational acceleration.
So they said, well, maybe it's a dark comet.
And so the point is, if something doesn't fit neatly into categories that we are familiar with,
we should be curious about it and figure it out.
And that's why I'm listing the anomalies.
It's really a way for us to learn.
If something is not familiar, let's use it to learn something new because, you know, finding
material objects from another star is a completely new frontier in astronomy.
We are used to looking at things remotely with a telescope and also with gravitation wave detectors.
But finding a material object, a large material object that arrives to our backyard is an opportunity
to learn about its source and it would take us millions to billions of years, to
visit those stars. So it's just an amazing, amazing opportunity. Not to mention the fact that the last,
you know, major one that came to visit the earth and did leave some material with it was a, you know,
giant dinosaur killing, you know, hunk of rock that hit off the coast of the Yucatan, right? So
not only has informational and scientific interest, it has survival, civilizational, existential
benefits to us and for protection, even if it's not technological. I made a post on X on Twitter
today about, you know, we're coming up on the 50th anniversary of the Voyager, you know, launches,
as you mentioned earlier today, they're barely one light day beyond the Earth's, you know,
distance from the Earth and the sun. So they're relatively, you know, kind of on the doorstep,
really, they haven't left the home yet. They're like teenagers that won't move out, right? But,
but I said, what would you put on a golden disc? And it made me think, A, well, I'd like to know,
what would you put on a golden disc, A, Avi? And if a civilization found a golden disc, what would
they say about it. It's just like, you know, the critics, the, the, the haters, would they say
things like, you know, oh, it's just, it's just a flat, you know, piece of a golden, golden metal
from a supernova. I mean, they'd be making all these natural explanations for it, the haters,
the jealous ones that the, oh, yeah, the troves. I mean, they would be, they would behave just
like a cave dweller that is finding a cell phone, because the cave dweller would argue it's a
rock of a type that I've never seen before. And that's also what was argued about the,
Tesla roads the car when it was confused for an asteroid just this year on January 2nd by the
Mine of Planet Center.
So what would you put on a golden disk and then, yeah.
So I would actually right now put an AI chip because that's our most advanced technology
and it brings in the technology of artificial intelligence.
and in fact even have an AI brain on that record that we put
just in order to demonstrate that we can create intelligent systems,
which is a milestone for us, because that's the first time our own technological child
may have a higher level of cognition than our brain, you know,
and this hopefully will bring us a sense of modesty that we desperately need.
And if not, then of course, alien intelligence superior to ours will do the same.
So for it to meet an alien civilization, you know, we'll demonstrate that we are able to create things that are better than us.
Okay.
And we could, we would do it without embedding a deep fake of, you know, Donald Trump pushing some meme coin, some Trump coin.
Okay. So let's get into some more.
By the way, I should mention an anecdote that just a few weeks ago, I had an interview by a high school.
student from Taiwan. And she was very young and her teacher was with her on the call. And she asked me,
what's your advice for young students? And I said, my most important advice is to have human friends
and not AI companions. And then the second most important is to go to primary sources and not rely on
AI systems because that's just like consuming junk food that is bad for your body. In this case,
It's intellectual junk food provided processed by AI that is bad for your brain.
That's really my concern about young people.
They will get dumber if they were to rely just on AI because they don't have critical thinking.
And so she said, could I share the video with my father?
And I said, of course.
And then the teacher informed me that her father is one of these billion, multi-billionaires.
that is in the tech business associated with AI.
And my hope is that he sees the light,
that even though he develops AI,
he would agree with me that his daughter should refrain
from being addicted to AI.
Yamava Resort and Casino at San Manuel
is California's number one entertainment destination
for today's superstars.
Catch the Jonas Brothers return to the Yamava Theater stage
on April 30th, the powerful vocals of Demi Lovato on May 17th,
and the signature Southern Country Rock of Eric Church on July 19th.
Tickets on sale now at Yamava Theater.com, only at Yamava Resort and Casino,
celebrating its 40th anniversary.
UN must be 21 to enter.
Yeah, it is incredibly addictive.
I use it all the time.
I use it every day.
I enjoy it.
My kids use it.
I think it is possible that the people who use it, you know, for,
its intended purposes, we'll find great success with it. I don't think that it was capable of doing
what I care most about, which is new physics, at least in terms of GPUs plus LLMs. There may be some
other thing that this girl's father's work. Well, I'm really worried that already now, that I
wouldn't be surprised if 10% of the papers in journals are being written by AI. Oh, yeah. And I worry,
I worry that some of the data, which is reported, is fake, because how would you verify unless you do the
experiment yourself. So the AI system can create fake data that looks as real as real data.
And then it's not easy to tell the difference. And so I'll give you an example. I saw a paper
on the other day on the archive where the postdocs and senior people post new papers. And
I looked at the content. It didn't make any sense. There were lots of mistakes. The physics is
wrong. And I then looked at the author. The author has papers.
both on quantum gravity in the early universe and on asteroids.
And I thought no postdoc can have so much, such a rich repertoire.
And it looked to me like all these papers were written by AI.
And this postdoc is basically trying to beef up their resume.
And the other clue was that all these, none of these papers was submitted for a peer-reviewed journal.
They all appeared on the archive.
So to me it says there are people.
out there, you know, that produce papers that have no meaningful content and they appear on the archive.
There are moderators on the archive, but the moderators are paying attention to the length of the
paper, all kinds of superficial aspects. They cannot really judge whether the content makes sense.
So there are lots of papers written by AI that are completely wrong. So then the question is,
you should check it out. And before you blame the speech,
stupidity of the co-authors, it may be the stupidity of the AI system that created the paper.
And they have this problem that afflicted beef in Great Britain in the late 1990s.
Remember, mad cow disease.
Now I call it mad bot disease where these AIs are training on data that they themselves are making and regurgitating things.
So I don't believe that this is the way to get to a theory of everything, quantum gravity,
new predictions in cosmology or serendipitous observations.
but there may be another technology that does it.
And I kind of want to springboard that.
I should say that I get about three papers a day submitted to me from people that have,
you know, come up with the theory of everything.
And they always say the same day, you know, Press Keating, you know, we vetted it.
It's past ChatGBTGPT or Gemini.
And they all say, I'm brilliant and I'm the greatest.
I said, well, be careful because I asked that, you know, chat GPT,
what books is Brian Keating written?
And it came back with, you know, losing the Nobel Prize, featuring Avi Loeb.
it came back with Into the Impossible.
Then I came back with a brief history of time.
And I said, well, you know, I need to get a couple percent of Stephen's book sales.
But I said at least their theories of everything, you know, are at least as maybe untestable or unverifiable as string theory.
You know, so it's not like, which was created long before we had a theory.
Yeah.
We had AI.
And it's still not being tested and it will not be tested in the.
So the question is why is it physics?
But the thing I wanted to say.
about the best contribution that AI can make to science would be to, for AI medicine to increase
the longevity of scientists so that, you know, you can use the experience and the wisdom that you
gained over the decades to make new discoveries. I think that would be, I mean, if Einstein
were to live a few hundred years, I'm sure he would have benefited humanity far more.
Right. I see people like yesterday I was looking up at Witten, you know, he was on Brian Green's YouTube channel talking about string theory in the year 2037. I don't know how they came up with that. But I got the notion, you know, and I was talking to friends about this, you know, that like you could make it, you know, string theory in the year 25,000, that it would probably still be the same, you know.
Well, yeah, I mean, it will be, if you think about it, it's similar to the story about the Lubavichers rabbi, that, you know, they had a theory that the rabbi when he dies will become the Messiah.
Yeah, and then he died. And there was a data point. He died and he didn't come back.
Right. So you might say, okay, well, does that demonstrate the theory is wrong? Not at all, because they say we only have to wait more.
And the same is true about supersymmetry.
For example, we didn't find it with a large Hadron Collider.
And the answer is, okay, we need a higher energy collider and we might find it there.
And this is actually a good situation where you can actually test the theory.
But in the context of string theory, there is no definite prediction that can be, you know,
we had a talk at the Institute for Theory and Computation that I'm serving as the director of.
And the string theory said that, you know, we could explain the evolving dark energy.
in the universe based on inspired by ideas from string theory.
And I said, great, you're making a prediction.
Suppose we now find that it's all false and indeed the dark energy doesn't evolve.
Would that rule out string theory?
And he said, no, string theory will always be right.
It's just that my conjecture may be wrong about it.
And how can you operate in this way where you don't stick your head and, you know,
to an empirical test?
You basically say, irrespective of what the experiment
will say, you know, I want to gain the benefits of a successful prediction, but then if it's not
successful, then it doesn't say anything about my theory. I mean, that's what, that's, it's impossible
to eat the cake and leave it, you know. That's what your former colleague Natty Cyberg said,
you know, no matter what we find, if it's not consistent with string theory, we'll say it's
part of string theory, you know, string theory is those things that they're not consistent. I would say,
you know, quantum computers are really good at predicting the properties of quantum computers,
and they may be useful for other things, I'm not sure yet,
but string theory is very good at describing the mathematics of string theory.
And I want to just point out the, you know, kind of something we hinted at,
but we're talking about the deep future.
You know, it has been said that it's impossible to really think that in a thousand years
from now people will still care about the Civil War in America,
but they'll care about Maxwell's equations, which came about in the exact same decade, right?
So when we look back a thousand years, hence, people studying the data, compare Three-Eye Atlas to Omuamua and Borosov, which is the one that will still be remembered? Or will they all be remembered? But which one clearly breaks the paradigm? I think, well, my guess is the one that will be proven to be part of a population that is extremely unusual. And once we have enough statistics, more than three, you know, it's like a blind date. You go on a blind date three times. I mean, some people convert.
with a partner.
Yeah, thank God, my wife did that.
Yeah, she settled for the first day.
I would argue that's actually not a good practice
because your data set is very limited.
You know, if your sample includes only one person,
obviously you think that person must be exceptional.
You don't have a comparison.
However, if you go on many blind dates,
eventually you get a good enough sample
to actually assess that the partner has some rare qualities.
And so we just need a bigger sample.
just need a bigger sample to appreciate whether three-eye Atlas or or Muamua were a member of a
very unusual class of objects that originate from a source very different than the solar system.
And, you know, if you ask me what will happen in a thousand years, let's say, I would argue that,
you know, if you look at the funding of science, we are funding projects like the one that you're
working on, like some of that I work on, where we study the known unknowns. For example, in the
context of cosmology, we know that we don't know the nature of dark matter. We know that we don't
know the nature of dark energy. We know that we don't have verification that is beyond any doubt
of cosmic inflation in the form of gravitation waves. So there are known unknowns. Okay, so things that we
know that we don't know. These are the kind of projects.
that we fund that we put resources towards.
That's right.
And on the other hand, what are the most consequential discoveries in science?
These are the unknown unknowns.
Right.
For example, yeah.
Yeah.
These are situations where we don't even know right now that we don't know something.
And just to give you an example, back around 1895 or so, Michelson,
gave a talk at the University of Chicago, where he said,
physics is pretty much over, and the only thing that remains is to fix the fundamental
constants to the fifth decimal point. That was his mainstream point of view. He gave a lecture
for a new laboratory, opened at the University of Chicago, with huge confidence that we
are done with physics. And then 10 years later, special relativity. Another 10 years,
general relativity. Another 10 years, quantum mechanics. Everything he was talking about is completely
sidelined by a new perspective about the physical reality. Now what does it show? He couldn't have
imagined quantum mechanics because nobody could have imagined and Einstein had a problem with it.
So when I visited the Copenhagen just a few months ago, I was struck by this auditorium where the
conference was held when I entered into it because,
because that's the birthplace of quantum mechanics.
And, you know, Nils Bohr was willing,
as a young scientist, was willing to say,
reality is different, Albert, he would tell Albert Einstein,
reality is different.
Quantum mechanics is not classical physics.
And Einstein would say, no, no, no,
we are just missing another variable or, you know,
it makes no sense that there is this spooky action
at this.
So Einstein wasn't the wrong side.
because he had traditional thinking.
Nils Bohr was much more daring, and he was right.
Now, Einstein, of course, is a celebrated figure.
But what does this story tell you?
It tells you that even the most distinguished mainstream scientists,
you know, Einstein was not mainstream when he started,
but became mainstream at that point.
Even those are sometimes too traditional.
And therefore, you know, being open-minded is really a virtue
when you explore the unknown.
He could have had a good career.
He could have been famous if he didn't make those mistakes, right?
Einstein could have been a well-known individual.
So let's talk about, I have a question for one of my beloved audience members.
This is Stephen Dittalus 74, and he's asking,
do you think Jupiter might hide some alien life, as in the movie 2001 of Space Odyssey?
And that's the reason why Thry Atlas is coming towards Jupiter,
or seems to head towards Super.
What do you make of that?
It's really difficult to maintain life in the atmosphere of Jupiter because there is no solid surface there.
Or it's moons, right?
Ah, moons, definitely. That's definitely possible. Yeah.
Yeah, so we haven't obviously found much.
Actually, on Europe, there are two spacecraft now on their way to Jupiter, and one of them is the Europa
clipper the other one is juice and the both of them of the european space agency and and the
clipper the europea clipper is planning to arrive close to this moon of jupiter europe where the surface
is frozen because jupiter is far from the sun but under the icy surface we believe that there is
liquid water an ocean a subsurface ocean
And we know that there are cracks in the ice and out of these cracks come plumes of water vapor, just like a geyser.
And the question is whether there are any living organisms in those oceans.
And in particular, you could imagine fish swimming there.
And some dead fish on the surface of Europe.
we just don't know if these dead fish are, you know, spewed out from the cracks in the ice.
And so it would be nice, of course, to learn more about Europa and figure out if there is, there are any organic molecules in the plumes of water coming out, water vapor.
So this is an example of a place where, you know, it's pretty much part of the mainstream scientific thinking that there is potential.
potentially life under, you know, subsurface life.
And I should say that I wrote a paper about six years ago talking about subsurface life.
And the idea is that you could imagine, you know, the solar system maintain planets that we see today.
But there were many more planets to start with that were kicked out of the solar system because of interactions among the planets that kicked them out gravitationally.
And what would happen to an Earth-sized planet, just like the Earth, a twin of Earth that, let's say, was kicked in between Earth and Mars, for example, was kicked out?
It would freeze, obviously, and the surface will be covered with ice, maybe down to a depth of 50 kilometers or so.
But there could be liquid water under the ice because of the radioactive warming of the inner core.
core, you know, there are radioactive isotopes that decay and warm up, the core of the earth.
We know that there is significant amount of heat coming from the core in addition to the heat
coming from the sun.
Yeah, that's why the Earth has the main temperature that it does. That's why...
Exactly. So you could have definitely liquid water oceans under the icy surface of the
Earth that was ejected, not at all close to a star like the sun. And this may be actually the most
abundant form of life in the universe because there were many more frozen planets that were kicked
out of planetary systems than those that remained. And therefore there must be a lot of free-floating
planets frozen on the surface that may have life inside of them.
Trapped or signs of past. It would be really difficult to find that form of life because you have to
either look through the cracks in the eyes or drill a hole in order to reach.
the life underneath, but it may be the most abundant form of life.
Yeah, but so I've never been afraid of a little hard work.
Ambition comes in all shapes and sizes.
At First Citizens Bank, we roll with your goals because we're built for what you're building.
Fit for your ambition for Citizens Bank.
Okay, I have a couple of questions.
We come to the end of the year, the end of the episode, three kind of rapid fire questions as we close out.
I want to thank you for being my most popular guest this whole year.
an incredible journey. We've had over a million and a half views and downloads of our episodes
together. May we have many more? Okay, this one has to do with the name of the month, January.
So Janus, the god, Janus is a god that looks forwards and backwards to the past and the future.
I want to say to you, when you look backwards at these objects, you know, that are interstellar
and then forward to a decade of vastly better surveys and instruments, what are you thinking is going
to be, you know, sort of a misstep or a misunderstanding, and what do you suspect the future data
that's coming very soon will force us to unlearn.
Right. So first of all, with respect to three-eye Atlas, if we use the web telescope, and I'm sure
it was used very recently over the past week, but we haven't heard anything about it yet,
if we can take a spectrum of the jets in particular, because the web telescope has an
amazing spectro graph, and measure the speed of the jet and the composition of the jet relative to
the comma, the cloud of gas around three a atlas, then if the speed is below a few hundred
meters per second, then it could be due to the sublimation of ice, pockets of ice on the
surface of her rock. However, technological thrusters can produce chemical propulsion and exhaust
speed of a few kilometers per second, or in the case of ion thrusters, they could reach tens
of kilometers per second. So the speed of the of the jets would tell us a lot about their origin and
their and the nature of the object. So that's what I'm looking for in the next few weeks. I mean into
January. But more generally we're entering a new era starting in January and that is with the
Rubin Observatory in Chile that was funded by the National Science Foundation and the Department
of Energy. And the Rubin Observatory employs
a 3.2 gigapixel camera about a thousand times more than a number of pixels in your cell phone
camera and then and it also surveys the southern sky every four days so we expected to find
a new interstellar object every few months and of course some of that discovery space may be
mitigate maybe suppressed by by all this communication satellites of SpaceX and
others and because they create the tricks that sort of compromise our ability to
look at the sky without interruption but it's sort of like city lights in the sky
and I'm a bit worried about that but other than that the discovery rate should
be a hundred times higher than we had in the past decades
from Pan stars or from Atlas.
So we are entering a new era where we will have many more,
maybe several dozens of or maybe five dozens.
It's hard to tell in the next decade of interstellar objects.
And that would allow us to gain some insight into the statistics,
how unusual are the outliers,
and what are their nature, where do they come from?
So this is something I very much look forward to.
And then of course, if we are ambitious, we will design an interceptor that will cross the path of one of these.
And we can actually take a close-up photograph of an incoming interstellar object and perhaps even land on it and bring some materials back to Earth, which would be amazing.
Just like we did with Osiris Rex that landed on Benu and brought a sample of 120 grams, where we found.
most of the amino acids actually from the surface of an asteroid in the main asteroid belt.
So we want to know if the same thing, if those amino acids exist near other stars,
and that would be an amazing opportunity for astrobiology that was not mentioned anywhere,
by the way. So I really hope for that. Now, this kind of a mission, an interceptor mission,
I mean, an ISA already has this mission of a comet interceptor in my
mine. And by the way, it's not so difficult because even our Juno spacecraft around Jupiter
could have intercepted 3A Atlas if it just had the original fuel that it started with. I did the
calculation. I wrote the paper, published the paper about it. But it just consumed all of its fuel
by now. So there is no way. It was a missed opportunity. So these these kinds of missions, interceptor
missions, will cost at the level of a billion dollars, a few billion dollars. The point is,
this is pocket change money.
If we realize that alien technology is coming our way,
then it would make sense to allocate a significant fraction
of the military budgets that we spend every year for planetary defense.
Yeah, that would be half a percent of the daily, you know,
there would be sort of half a day worth of military spending to pay for a single mission.
So can you imagine what we do?
Yeah, exactly.
So imagine a trillion.
dollars a year for constructing a warning system for planetary defense, it would of course help in
terms of people feeling more secure that Earth that we know now when objects come in, whether
they are technological or rocks just from getting a close-up photograph of them. But it will also
boost the astronomy in a major way. Just think about all these probes out there. So a trillion
dollars a year is a very substantial budget for science.
Absolutely.
And I very much, so that's, people say, why are you so excited about them searching for
technological artifacts?
And the answer is because it will bring us to a much better place where science gets a higher
priority, where space exploration serves humanity, you know, and deserves to be funded at that
level because it's not just about conflicts among people on the surface of this tiny rock,
you know, that makes three millions of the mass of the sun. We have some residue, some debris
that left over from the sun. We are obsessed with small territorial disputes on it. And by way,
Putin, who is one of the main people who are, you know, causing a lot of deaths just over a piece
of territorial dispute. You know, he actually,
was asked on Friday by a journalist in Russia. He had the summary of the year, 2025. He was asked
about Free Air Atlas and he tried to explain what this object is. But, you know, if he were to
get the full picture from the cosmic neighborhood we have, it would immediately suggest to him
that his life ambition makes no sense whatsoever. That's right. That's as Carl Sagan says,
you know, looking at the pale blue dot, you see humans fighting over the fraction of a dot.
Well, Avi, I want to wish you a great success in your coming new year as you go forth and prosper.
May you be successful.
And you've really done so much this year to really highlight the most exciting, most interesting things,
other than cosmology in the Big Bang that I study.
Right.
Okay, I can't dispute that.
But, Avi, you've done an incredible amount to inspire people, millions of people around the world.
and there's much more coming in the new year,
and I hope we'll be able to get together
because you have this ability to change the way
that ordinary people and scientists
think about our place in the cosmos.
I want to thank you so much.
I want to wish you a happy holiday season,
a happy new year,
and remind you, if you want a piece of an actual asteroid
that is probably from our solar system,
not interstellar, but it definitely has some DNA on it,
Avi, because I lick each one and put it.
No, I don't do that, but we have a...
We can't avoid shedding some amino acids
when we put these things in the mail to you.
You can get one at Brian Keating.com slash edu if you are a university dweller in the United States.
But if you're not, Briancating.com slash yt.
I just wanted to say one thing, Brian.
When I was a kid, I was told about people that are willing to sign a document
dedicating their body to science after they die.
Okay.
I'm willing to dedicate my body to science while I'm alive.
Well, you've dedicated.
so much of your mind and your body.
And yeah, I just, I just wanted to be said of me in 150 years, Avi, that I look good for a 200-year-old
person.
So that's the way that I am.
Avi, thank you so much.
Have a great holiday season.
We'll see you next year and we'll have many more exciting adventures together.
Thank you guys so much in the super chats and the members.
And tune into my interview with a second most popular guest this year, Mario Eurich, of the
Rear Rubin Observatory.
We talked about tens of thousands of asteroids and comments that.
they are discovering and will discover in the coming years with Vera Rubin.
So tune in to that.
I'll put a link to that right here.
And for everybody else, thank you for being so supportive.
Many great interviews to come, including a long interview with our friend Terence Tao,
part two, a very, very wonderful interview with Terry Tao, one of that.
Mozart's of Mathematics.
He's kind of the Avi lobe of mathematics.
Avi, thank you so much.
Be well, my friend.
Thank you.
You can't reason with the sun.
Trust us.
We've tried.
This summer, it's time to put that angry ball of fire on mute.
Columbia's Omnyshade technology is engineered to protect you from the sun's harsh rays that can burn and damage your skin.
The sun is relentless, but so is our gear.
Level up your summer at Columbia.com to spend more time outside and less time slathering on allotion.
You're welcome.
Columbia, engineered for whatever.