Into the Impossible With Brian Keating - Could Aliens Be Using Light to Communicate? A New Era of SETI with Shelley Wright [ep. 483]
Episode Date: March 17, 2025Pique is offering 20% off for life AND a free Starter Kit with your purchase—that's a rechargeable frother and glass beaker to make the perfect cup every time. Just go to http://piquelife.com/imposs...ible Please join my mailing list here 👉 https://briankeating.com/list to win a meteorite 💥 Are We Searching for Aliens the Wrong Way? Historically, SETI has focused primarily on radio waves because they can travel vast distances through interstellar gas and dust with minimal absorption and require less energy to transmit compared to other wavelengths. This approach dates back to the 1960s, when astronomer Frank Drake conducted the first modern SETI experiment, Project Ozma. However, in recent years, optical SETI and infrared SETI have started to gain traction. Here today to tell us everything about this new era of SETI is the remarkable observational and experimental astrophysicist Shelley Wright! Shelley is a Professor of Astronomy, Astrophysics, and Physics at UCSD. She specializes in designing and using astronomical instruments that make use of adaptive optics, with a particular focus on techniques involving integral field spectrographs. As a SETI researcher and instrumentalist, there is no one better to shed light on this topic than her! Join us in our hunt for extraterrestrial life. — Key Takeaways: 00:00 Intro: Shelley Wright 01:26 Shelley’s background 02:19 Drake equation and life in the universe 08:28 Instrument development 14:55 Optical SETI and Fresnel lenses 16:49 SETI vs. radio listening 20:32 Background contamination and protocols 22:35 Ethical considerations and messaging aliens 23:57 Life on Mars and the origins of life 27:57 UAP committee and conspiracy theories 39:08 Galileo Project 40:46 Final thoughts and advice 45:21 Outro — Additional resources: ➡️ Learn more about Shelley Wright: 💻 Website: https://saw.physics.ucsd.edu/ ➡️ Follow me on your fav platforms: ✖️ Twitter: https://twitter.com/DrBrianKeating 🔔 YouTube: https://www.youtube.com/DrBrianKeating?sub_confirmation=1 📝 Join my mailing list: https://briankeating.com/list ✍️ Check out my blog: https://briankeating.com/cosmic-musings/ 🎙️ Follow my podcast: https://briankeating.com/podcast — Into the Impossible with Brian Keating is a podcast dedicated to all those who want to explore the universe within and beyond the known. Make sure to follow so you never miss an episode! Learn more about your ad choices. Visit megaphone.fm/adchoices
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What if everything you thought you knew about UFOs was wrong?
Most scientists are terrified to discuss the truth behind UAPs,
but today we're diving deep into the shocking realities
that have been kept in the dark for far too long.
Alongside my colleague Professor Shelley Wright will take on the most taboo questions.
Is UFO research all pseudoscience?
Is disclosure hopelessly stalled?
Do you have to risk your career to study this forbidden topic?
Well, not anymore.
Astrophysicist Dr. Shelley Wright is now breaking the thing.
taboo, risking her reputation by hunting for real-life alien signals. If you're ready for the unfiltered
truth on UAPs and the surprising science behind it, keep watching. This conversation would force you to
rethink everything you thought you knew about the search for alien intelligence. Even the scientists
were commenting to me, how could you go and talk about UAPs or UFOs? Most people just kind of want to
know what's going on. Most people are just going about their lives and they are genuinely curious. And because
there's this kind of vacuum about real information, that's where you get kind of conspiracy theories,
that people with the loudhorns can come in and fill that space. Welcome everybody to an exciting
out of this universe episode of the Into the Impossible podcast with not only an eminent astrophysicist
and not only a fellow professor, but a very good friend. That's Professor Shelley Wright. Shelley,
welcome to the End of the Impossible podcast. Thank you for having me. I'm excited to be here today.
I want to first start off with a discussion about what makes you interested in the research that you do.
Explain the types of science that you do, both in this world or in this universe and maybe stuff that might be a little more far out removed from what normal astrophysicists, quote unquote, do.
I love tinkering and making new instruments to explore the universe in new ways.
That's basically it.
I love working with engineers, scientists, students to make unique cameras, special.
Electrographs used new telescopes to really do any discoveries across the universe.
And then one of my deep heart interest is the understanding of life in the universe.
Are we alone?
Is there potentially other civilizations out there?
Could they be communicating with us right now in our own galaxy?
And if they were, how could we use technology to detect those signals?
One of the things I always talk about that gets me into trouble when I talk about people.
I'm sort of an alien pessimist, an alien minimalist.
if you will, and that rubbed some of my viewers even the long way.
Some of my friends get really agitated by the fact that I have a,
I would never say the probability is zero,
but looking through how, you know, improbable it is that you and I are having this conversation.
The fact is we don't have any evidence right now that there are other life forms
that rise to the level of many, many sigma confidence levels, right?
So I think, you know, from my perspective,
it would be one of the biggest, if not the biggest discovery of all time,
But we always have to tamper that with our expectations as scientists should be driven by data.
And one of the arguments I want you to react to is people say things like, well, you know,
there's 10 to the 22nd, you know, possible stars in the observable universe.
Each one of them could have a 10 to 100 planets around them or minor bodies.
There's got to be life out there.
How do you react to that argument?
Do you think it's plausible?
That there's other life out there?
Well, do you think that?
We're already proof of one.
Yeah.
So I think it's a little hubris to think that we could not be the only one.
And the question here is in time, and time is what you know well, the age of the universe.
And the question really is not whether there's other life in the universe or whether there's
other life in the galaxy.
Probably a good standpoint science question is, is there other life that coexist in this moment
with us talking right now?
And if you put it in that frame, like you think about the Drake equation that tries to calculate
the number of civilizations or communicating civilizations, the leading factor of that is time, right?
the lifetime of life existing and co-existing with us. So you could take the premise that we are
one of that 10 of the 22. That's a pretty boring universe in my opinion, but that is an opinion.
And, you know, that's where you need data. But if you take the premise that we should not be the
only ones, right, that we were a byproduct, life was a byproduct, bathroom scum is a byproduct,
dogs or cats, dolphins to humans are a byproduct of this universe, a barbarianic universe for you,
then the question is whether they could exist with us in our own galaxy, are they existing
around other planets that have similar characterizations of habitability like Earth? And then
the rough part here in that calculation is could they potentially be coexisting us in this small
sliver, right? Like we are, our technology in this moment is just the tiniest sliver of time in all
of the age of the universe. So that, I think time is the most important answer to your question.
Now, you not only knew Frank Drake, you also won the Drake Award. What was Frank like? I mean,
he was one of the guests that kind of got away. I'd never got to meet him or have a conversation
on the channel with him. Frank was a brilliant scientist, obviously a pioneer in the field of SETI,
but was a very thoughtful human being, right?
Like he really brought in the importance of science,
hypothesis, the scientific rigor to the field of life in the universe, right?
Obviously philosophers, you know, for hundreds of years
have been speculating about life elsewhere beyond Earth,
but it was really Frank who said,
okay, let's bring science to the table and try to answer this question.
And he did it for decades, right,
and tried to build up a field with individuals.
You know, he like also shepherd Carl Sagan into the mix, into this field.
And he was a wonderful mentor.
Now, when people discuss the Drake equation, I always say it's kind of not a real equation
in the sense that I only consider things equations if you can do error analysis on them.
And I once did a calculator.
Actually, I did it.
You helped me tremendously because you gave a talk at the SETI Institute a couple of months before
I gave one eight years ago now.
It's incredible.
And I decided, oh, I'm going to do this calculation of how many people are in the
the San Diego Zoo right now. And if you do it, you can get any number you want, just depending on,
you know, is it a holiday? Is it raining like it is today? I mean, can you believe that we had to do
this interview in the rain in San Diego? How do you as a professional and an expert in this field?
Do you look at the Drake equation? Is it something you take seriously or you utilize as a tool in
your arsenal? Or how do you apply it if at all? I think we all do apply it in some sense.
Like the Drake equation basically breaks down the constituents of trying to understand the probability
of life, which we were just first talking about.
it and when they first started with the Drake equation I was thinking about that
first variable that he put in there which was actually the rate of star formation
so it was presumptuous to think that okay you got to have a planet to have life
then the planets around stars so the question was how many stars happen within
our galaxy and that was the first variable within it but then there was things that
came later which they had no idea in the late 60s about which was like the fraction
of stars that have planets the fraction of those stars that have planets
have Earth-like planets, and then the fraction of those out of Earth-like planets with the habitability of it.
And what's remarkable in our own careers, Brian, is that we have answered those questions.
So I look at the Drake equation where we march from left to right, where L's the end, that lifetime
of civilization we were just talking about, and we're answering them.
So in the framework of science and astrobiology, the Drake equation is useful, because we need
to answer these questions about how common are planets, how common are Earth-like planets,
how common are Earth like planets,
re-habitability,
how common is other life?
Like, we try to answer these questions,
even trying to go to Mars,
even others' surfaces and planets
within our own solar system.
And I think we'll continue along that path.
On the other spectrum of it,
of course, you have biology interplace,
right, biochemistry in place,
understanding the origins of life,
things like the RNA world,
how probable is it
if you just have organic materials,
you generate life on a surface.
And that's marching the other direction on the Drake equation.
So to answer your question, do scientists sit there and go on the chalkboard with it every day?
No, but I think we use it in a framework to answer the big question of R.B.A.
alone.
So let's talk about what you do in terms of your research activity.
Obviously, you're a professor.
Now you're the chair of the newly formed.
Substitute chair, interim chair.
Okay.
You're an interim chair of the newly formed and incubated astronomy and astrophysics department.
congratulations. Talk about your research and how you divide your portfolio. Let's talk about the
conventional astronomy for lack of a better word, and then we'll go into the optical seti work
that you've been involved with for quite some time. So how do you decide on a daily basis?
I'm going to do work building a spectrograph or a spectrofit on whatever you're focusing on
that day, no pun intended, versus, you know, the work in seti that you're involved with.
I spent a lot of my time in the lab and trying to build up, like I said, new technology. I really
think that's kind of the core of our my research and my research group. And that fits into conventional
astronomy where we try to build new cameras, new spectrographs. And I've always interested in being
kind of on the forefront of that. So if I look at my career, I was really interested in adaptive optics.
When that first came online, when I was a student, I said, I had to get involved. And adaptive optics,
of course, it's correcting for the Earth's distortion. It allows stars to twinkle. We want to remove them
from Twinkle and try to get large telescopes to use these. To do that, to take those images that go
behind adapt-objects, you have to use pretty close to kind of even our industry limits in
detectors, in optics, in cryogenic materials. And I think that's really benefited myself and my research
group to take that kind of work and try to synthesize that to make like the latest instruments.
And so my day job, so to speak, is building large cameras and spectrographs for large base
telescopes like Keck Observatory and even designing like first light instruments for the even
larger, extremely large telescopes.
I've spent almost 15 years involved of designing kind of back-end instrumentation that goes
behind 30 meters or larger of telescopes.
And of course, the one that will be coming online is the European extremely large telescope in
Chile. But with all of that and my interest in building new technology for these large telescopes
and in the in kind of the wake of adaptive optics and the detector technology, I was always
interested in the pursuit, the search for extraterrestrial intelligence. And the fact that
nobody was really doing it, that actually, you know, kind of intrigued me because it's such a,
you know, fundamental question, as you have mentioned many times on this show. So I took the abilities of
trying to look at new technology and see what we could do to make new instrumentations for
things like optical study. If you come to my lab, you can go into multiple rooms where we're
building things for the largest telescopes on Earth to building completely unique instruments and
telescopes that are kind of unique to anything or on Earth and trying to get them deployed.
One of the things that's so remarkable about the way that you approach your research is that
it's not the pie in the sky, you know, let's build a particle collider, the size of the moon or the
solar system, you know, diameter, like some of my past guests have talked about and actually
honestly proposed. We'll see about that. But you actually do things that are practical, as well as,
you know, kind of the stretch goals and then more kind of probable or lower risk, but, you know,
also very high reward in the optical setting. So let's talk about that. You use something called
a Fresnel lens. So let's talk about what was the thought process that led you to design that
particular type of instrument. So we have here Galileo Galilei and this finger popping guy.
And he's holding a telescope.
Obviously, he did not invent the telescope.
That's a myth.
But he did kind of perfect it in a way.
And then he made its magnification much, much better than before he invented the tripod.
People don't really think about that.
But he really did that.
And of course, he made images that revolutionized the way that humans look at the stars.
But one of his favorite quotes that I love to kind of bring out with my students.
And it's kind of the impetus for what I do is he said, our job of scientists is to measure what's
measurable and make measurable what's not already so. So when you design a for now, let talk, walk us
through that. What was the design choices, the tradeoffs cost and don't be afraid to be super
technical. This is a great question because it's how experimental physicists to operate, right?
Because we have to take a science question or a science measurable, as you say, and you say,
how do I use the current technology to actually build to that, right? So you know this. Our science
question or our science objective was to try to image, look,
literally how do you image the entire observable sky and take a picture at every nanosecond.
So every one, one billionth of a second, how do you take a picture of the entire sky?
And then, of course, the practicality of that is how do you do that where you could actually
afford it?
That led us into, you know, it's as usual, long winding road and design and a lot of dead ends.
And we kind of went to traditional telescopes, like Galileo, even looking at traditional.
lenses and refractors than going to more like Isaac Newton telescopes with mirrors.
And we kept going down this path and it was never really cost effective.
You couldn't get these large angles across the sky.
And so we needed a way of thinking about how to make cost effective telescopes with
large what we call field of regard.
Like we're going to look at large angles.
And that's what led us to for now lenses.
In fact, project scientists here at UC San Diego Jerome Mayer, who does optics was like one of the
first to say, let's try for NEL lenses.
We had thought of it, other groups had thought about it before.
And we said, I don't know if that works.
Like maybe we thought they had too poor of image quality.
But those were years past.
And we said, well, let's go check out the technology.
And so we bought a bunch of them, brought them into the lab,
did experimentalists what we do best.
Don't just talk about it.
We measure it.
And we measured the lenses and they were great.
In fact, they were better than we thought.
And other people within astronomy had thought,
we just had not looked at them for a while.
We published a few papers and realized that this was the answer to how to make cost effective,
wide field angle telescopes for the science objective we want.
Right.
It's not always going to work for other projects.
But as you know, we're always trying to get to our science requirement.
In this case, our science requirement was taking a picture across the entire observable sky.
And then the even crazier part of the technology is how to do that every nanosecond.
And tell me about the serendipitous kind of.
alignment with high energy physics and high energy astrophysics. You didn't initially plan on that,
right? Yeah. So we're talking about a project that's called panoramic setty, which was trying to do
this all-sky observatory. And so each telescope looks at 10 by 10 square degrees. It takes a picture
of every nanosecond. We have many telescopes. We are looking for, you know, in this case, optical
setting kind of what we call pulse pile up, all the light arriving in that nanosecond, which would be
very unusual. Stars don't do it. Maybe like submerging black holes, things, you know, high energy
events could happen, but we haven't detected those actually yet. And so we wanted to look for point
sources in the sky. We know in this field that if you take a picture every nanosecond at optical
light, we get kind of flashes of light that happens from high energy particles that hit Earth's atmosphere.
They're called Trinkoff showers. And about every second we get an event. This was noise to us. We knew this.
We were making our detectors to take our noise of this, what's called Trinkoff Shower and throw it away.
And, you know, another person's garbage is another person's treasure.
And we said, okay, we should go talk to the high energy folks to see if they want this information.
And they were interested.
And we decided to do a campaign where we went to Veritas Observatory in Arizona.
Huge dishes are amazing.
And we set up our Panasati telescopes with them back in 2019, 2021.
And we set them up and to observe at the exact same time, the exact same sources.
And the idea was to try to understand the sensitivity we were to high energy events.
And the answer is panoramic study was very sensitive.
And opened up a whole kind of new phase space for high energy astrophysics.
So we made a really nice detector that can detect these trancoff showers.
And this led into a collaboration for our study group with higher energy astrophysics
to now campaign and do both projects.
So now talk about why.
Talk about why SETI is different from radio listening like Drake and others.
We're initially interested in the Big Ear Project.
And then I do want to get back to the Galileo project and how that's different from what you're doing.
But first, let's talk about the actual science motivation.
Why would a civilization?
Why would you tune it to look in the optical when radio is a lot easier, you know, speaking as a dumb radio astronomer?
It's a lot easier to do radio astronomy in many ways.
Why did you just choose or why do people feel that's optical is a promising wavelength or
to explore.
Well, so just to comment that, you know, radio study we've been doing that 60 plus years,
right?
And it's interesting, that was our first technology for, you know, long range communication, right?
It's interesting to think of other civilizations would have developed other communication
outside of radio.
Radio is a great communication because it's low energy, as you know.
You can build large dishes and transmit.
It's easy to receive.
But you can use any, right, light, whether you're at optical light, radio light, gamma ray light,
microwaves, they all travel the speed limit.
So in terms of getting to distances from stars, you get there the same amount of time.
But why optical setting?
So Charles Towns invented the laser, right?
In 1959, wins the Nobel Prize for this.
In 1961, he wrote a really interesting nature paper about how lasers would be a phenomenal
way to do interstellar or interplanetary communication.
And if you think about this, like, that's kind of remarkable that this experimentalist
invented the laser and then immediately understood implications at a universe like scale.
And the paper basically argued that with a laser, you can pack a lot of information in it.
You can beam it if you know where the person is going to receive it.
It is a better carrier of information.
It's incredibly bright.
So if I sent a signal to you in another planet and you're receiving it, you don't have to
build a large dish, right?
You can just build a small dish.
And thinking back to panoramic study, we use, you know, these very small 20-inch lenses,
half-meter-sized lenses.
And even if you do the calculations, you can take Earth's technology today, go a thousand light years away,
take a laser, shine it back to Earth, and our little dish will detect it.
That's how bright lasers are.
So lasers became this kind of realm and optical study as an interesting realm to look at that wavelength.
By optical, I mean visible light.
Now, if you're going to send signals, you know in between stars there's gas and dust,
right?
And that's why you might, you like probably will say, well, you should probably be communicating
thousands of light years away communicated radio wavelengths.
So, you know, we knew this as study scientists, right?
So one of the arguments in fact is if you were to use a laser or use a beacon that's not
at radio, maybe you would do infrared, right?
And this led into our team also building another kind of like the first near infrared study instrument,
which I was interested in early on to get to those wavelengths.
lengths of light as well. But, you know, it's funny over the years, you know, we always use this
kind of anthropomorphic, I might say the right, anthropomorphic view of our technology and how we
would do detection. Right. And if you got in the public and you get public talks, they'll say,
well, how do you know they would use a laser? Wouldn't they use something else? And they would
give a word to something probably in science fiction. Yeah. And you're like, I don't. But light is
everywhere in the universe, right? And in truth, we're not necessarily detecting lasers. We can detect
anything at visible light that would make a bright flash or look unusual to nature.
And everything in study is about detecting something that looks unusual that, you know,
natural phenomenon aren't producing. And that's true at radio wavelengths as well.
What are the most significant background or systematic sources of astrophysical contamination?
At optical study, we really don't know yet. Most of the things I think for our program like
panoramic study, the things that we may detect the most now are like satellites. So kind of
earth technology, we checked a lot of planes, satellites, even people talk about sprites in the upper
atmosphere. So kind of local to us, that's true in radio study too, right? We talk about radio
interference. And most of radio study is removing our own Earth signal from that. Yeah.
Astrophysically, the exciting part is we don't know. Would pulsars be something? Potentially, yes.
One of the astrophysics things is we have LIGO, of course, with gravitational wave discoveries.
If we have these large angles of field of view, perhaps we could correlate an event that may produce what we call an optical counterpart to it.
But nobody's detected it.
Yeah.
And then do you have a protocol?
You know, the signal comes in and they're talking with, you know, Proxima Centurie or you see something of interest.
Do you guys have a protocol for what you would do as the PI as that, you know, what would you do if this comes in?
Or is that not for public consumption?
No, it's a great question because we get this question
a lot about what we would do and people have their,
you know, sneaky suspicions of whether we get taken away
from the men in black.
You know, we have candidate signals, as you know,
in experimental, you know, experiments,
you have kind of false positives, as we say,
that can occur from your instrument as a noise,
or it's a signal like a satellite.
So we have protocols that do verification.
So we have like whether, you know,
we flag it like this as an exciting candidate or not.
And then we go down and do the checklist to see if it's something internal or if it was correlated with something else.
It usually is very unexciting.
So we try not to call New York Times in most cases.
But the question is if there is something exciting, you know, we do have a proclamation that we would declare it on astronomers telegram, you know,
just like we would for any other transient source to get other facilities to follow up.
Yeah, obviously the question of, you know, the rationale for another civilization to communicate with us.
I mean, there's a famous quote from Stephen Hawking where he says, you know,
basically trying to message other civilizations is like ringing galactic dinner bell to serve men
we'd be cautious and not send out you know beacons that say that we're here i mean not that that's
something you're directly involved but what's your what's your position on that type of messaging to
extracurion yeah this is the concept of meti it's a really interesting ethical conversation right
there's a twofold question here one is like if you think there's a galactic civilization out there
You don't like go out in the forest and scream that I'm right here, right? That's another phrase that's used. That's interesting. Of course, we're constantly leaking. I think more of it comes into kind of an ethical question about representing humanity. And so, as you know, there have been, you know, people with means that go out and have taken radio dishes, taken their favorite rock album and broadcast it into space. You know, is that the best representation of humanity? Should there be kind of united,
protocols about messaging over time. You know, there was a lot of work into the Voyager
message on how to represent this and how to represent planet Earth as in general. I think we're
a little young in our infancy to send out messages, but. And the risk might outweigh the rewards.
You mentioned earlier, you know, about looking for, you know, not maybe, maybe techno signatures,
but maybe just biosignatures from aliens in our own solar system. So I have an argument I'd love to
run by you. This is a meteorite. Now, this is from,
This is Chelly a Benz meteorite.
I have a meteorite and I actually have a Martian meteorite that came from Mars.
This is not that.
This is actually yours to keep unlike the Martian meteorite.
So I'll let you take one of these.
So this is a chunk of Argentinian gold.
It's actually iron nickel cobalt.
And you two can get it out there.
As you know, go to my website, bryanketting.com slash list or slash YouTube or whatever.
Go to slash list.
I'll actually cut out the YouTuber.
So go to briancaidon.
dot com slash list. And if you're like Shelley and me and you have a dot edu email address,
you get one guaranteed if you live in the US. So go to briankeen.com slash edu and you'll get one
and you'll get some information about that one. Now that one came here via gravity. I also have one
that came from Mars. I said. And you know, I scanned it for life, never found any life on it.
But the point I guess I'm trying to make is the fact that we don't see life on Mars.
Okay. It's it would be a long shot. But can we use the non-observation of maybe techno
signatures in our in our own solar system. Does that set any limits on the
the sun-a-te-tee of life in the universe or is that too limited a scope to project into the
rest of the galaxy? Well, as you know, the cosmos in our Milky Way is vast and something that's
always humbling as an astronomer is the distance between stars. I think the only thing you
could say is something about interstellar travel and the number of people taking vacations here
in our solar system. Now for Mars, I think more of it's, you know, people we take rovers there,
as you know, to look not just at like whether life exists.
now, I would say more of the argument is, did life exist?
Yes.
Right?
So if you look back 3.1 billion years ago, we know Mars had an ocean.
We've done a lot of discoveries about our own surfaces of other planets within our solar system.
The question is if this gets back into the origins of life, now, if we go to Mars and a rover says,
wow, look, there was evidence of life three billion years ago that it could start either
on another surface besides Earth, that's a very statistic.
big deal, right? Because it means not only it can just happen on one surface, it can happen
on another. And not only that, it could happen on another surface in the same solar system,
that marvels me, actually, the most, Brian, because the fact that we can take, you know,
our resources today do things like launch the Europa Clipper and go try to study the oceans of
exo-moon discovery. I know you had David Kipping on recently. Just thinking about life underneath
Europa's ocean or Enceladus ocean, the moon around Saturn. And thinking about organic materials and
what organic materials could be there, that's fascinating to me that one solar system out of billions
were contemplating not necessarily, you know, can life coexist us now in our own solar system,
but could have coexisted in the past. Yes. Right. We started this whole podcast thinking about, you know,
the probability of life, that should be a measurement, actually.
That even in our scientific nature here in one solar system, we're exploring potential
signs of previous life and other surfaces.
And when they may have overlap with life on Earth, because life on Earth kicked off.
Well, yeah, we can get the panspermia and other things.
Here we go.
But take that to all the other planets we're discovering now, James Webb Space Telescope's
discovering it's an incredibly exciting time.
And when I started my career, you know, I was.
I was always interested in this question of R.B. alone, but I remember sitting in classes
in undergrad and people were talking about this rare earth hypothesis, right? Yeah. Yeah. That's,
so, you know, even in my little, our little short little sliver of time here, we know that's not
true, right? And again, this is marching down the Drake equation. Yep. So now I want to pivot to a recent,
you know, I told my wife that, you know, I saw a star being born when you were on the recent Nova,
PBS Nova, which is, you know, one of the, not only one of my favorite, it's one of the oldest, you know, science and nature communications, you know, and it's one of the best and well done. And so your episode was no exceptions. Talk about the genesis of that, if you will. How did you come to get involved with, you know, PBS Nova and talk a little bit about the role that you played in the other, you know, contributors to that, to that wonderful. No, I've always been interested in studying techno signatures in this field of Arby alone. And there's actually not that many people in this field, which is one of my things to.
advocate for that we need, you know, more brilliant people entering this field of SETI and astrobiology.
So when, you know, Congress basically committed, you know, told NASA to commission a committee, a
civilian committee on trying to understand, you know, I'll say the word here, UFOs, but at that time,
it was UAPs. I was asked to serve on the NASA UAP committee, unidentified, and then now anomalous
phenomenon. And I said yes because it was very intriguing that, you know, our government as well as
NASA was interested in kind of going into this realm that our science community is taboo. We can talk about,
you know, microbial life on Mars, but we can't talk about life and interstellar travel.
You know, there's this kind of divide that occurs and a stigma that occurs in the science community
as well as public, right? There's like this taboo thing to talk about UFOs and UAP.
And so I said yes, and it was a really fascinating committee to come into it and take a kind of a science data approach to it.
I also am interested in using new technology, as I said, to image the night sky.
So I was looking at NASA's capabilities with what are called geos, their satellites or geosynchronous satellites.
We looked at satellites, Earth observing satellites and their capabilities of imaging and their angular resolution, the timing and their detectors.
And so it was an interesting approach to see what we could detect from the kind of civilian NASA sense and couple that with both what was being seen, you know, by military personnel at the time that was going to Congress, as well as what people see daily, you know, and say what they see in the night sky.
So that was kind of where I entered this world of the UAPs.
And then I was invited to kind of talk about that experience on that recent PBS Nova.
Where does the committee stand now?
Like, is there a second follow-up report?
I mean, maybe you can summarize for those that may not be familiar with the actual report
out.
What was the conclusion or what were, you know, the preponderance of evidence?
Where does it come down?
Obviously, it's not, you know, that we're definitely being visited.
But there were some caveats.
And there were a lot of still remaining mysteries that we don't understand.
Yeah, I think there was some misconceptions by the public because I got a lot of emails about
this that at first they thought, okay, we have a committee of scientists that are going
go in and review every single case that on this date I saw something in the night sky.
Our, you know, committee charge was to go in and basically state what is NASA's role and what is
kind of interagency U.S. role in how to identify and address UAPs at large.
And so we were kind of looking at what data existed.
We looked at the occurrence rate, like number of people reporting things.
We had the FAA people there talking about things that were occurring within the FAA.
What are reporting schemes from pilots?
We had brought in people that had publicly disclosed and declassified some things that were done in military and then looking at that and trying to
Ask what other data we could apply to these scenarios and in particular it was much more forward looking
So we were looking at how NASA could help with this topic in the future, right? How can it work with the other interagencies?
And I think our committee you know, I'm actually proud of the work the committee did
I think we've seen change that came from it the first one was even thinking about
FAAs, like how do pilots report cases? It turns out, you know, it used to be like in a little,
you may know, because I know you're a pilot, but there was a manual and there was a 1-800 number
you would call, right, to somebody that you would report to. And so there was a stigma within that
and now there's better reporting for UAPs. And then there was also this ways that
communication between the interagencies of the government communicate when a UAP event
occurred and whether you can look at, again, these satellite information that came from it.
And there was a division that started in NASA to look at this case and how it connects to other government agencies like Arrow.
The other one that I think maybe is probably the most long lasting is probably trying to break down the stigma.
The public stigma on this topic is really important and the giggle factor that's around it because there really is a national security risk here.
There's an air traffic control risk as well.
you know, we looked at the number of drones being flown, looked at the number, I was always
surprised by the number of balloon launches per day. There's 10,000 balloon launches per day across
the world. A lot of these are industry based. And so it was, you know, just looking at this
aerial phenomenon and it's a great way to tell the public how amazing the night sky is. To look up.
Right. To look up. I was surprised, you know, because I talk with several people, I've talked with,
you know, pretty much everyone that was in the Nova episode. Now I've talked to you, I've talked to you many
times here, my upstairs neighbor, but on the podcast, Hakeem O'Leishie, Avi Lowe, Ryan Graves,
Mick West. I've talked to everyone. And what really troubles me is the vitriol that I see,
and that's primarily in one direction. You don't see many astronomers, you know, kind of really against
the public about their, you know, being ignorant or that they don't accept the fact that we've
discovered, you know, some advanced technology. And for example, I had Sarah Skolls on,
author, many years ago, she heard a book, they are already here, which talked to
about the fact that, you know, 99% of what we saw and even the reports that something like 95%
or something could be explained and there's all sorts of plausible ways to explain it. But that 5%
leaves this ambiguity in the human mind, which we're not comfortable with. And she talks
about how the human mind fills in those gaps with sometimes fanciful stuff. But the one thing
that stuck out in my interview with her is that she said, there's a feeling that the government
is maintaining sort of a secret cabal, you know, just as we covered up 9-11 or just as we covered up,
you know, the alleged Kennedy assassin, whatever you want to say. I mean, I'm joking about the
alleged. But the point being, there's a deep mistrust of government. And then that somehow
bleeds through to a concomitant mistrust of you and me as representing big astronomy or big
cosmology. I get it, you know, from a different cohort of people when I'm not opining and railing
against, you know, those that believe that were definitely being visited. But I get it for people
that say the Big Bang never happened. And that will strike a chord in the public and people go on Joe
Rogan and opine about, or the moonland.
didn't happen. How did you react to that? The vitriol, the complaints. I mean, not maybe don't,
you don't have to speak about to you directly, but to other members of the committee. I mean,
can you talk about what kind of negative impacts that maybe are discouraging to scientists? Because
you have a million things you can spend your time on. What was kind of the most, you know,
surprising thing about serving on this panel as doing a patriotic duty that, you know,
I find so commendable? Yeah, it was surprising. I would have to say that how much
you know, my inbox, I would say, filled up from all corners of this kind of realm.
Pro, not con, or, you know, even the scientists were commenting to me about accepting this role in the UAP.
It actually encouraged me.
It sounds funny to say this, but I think, you know, most people just kind of want to know what's going on.
They're not the ones who are, you know, spouting out vitrole, right?
Most people are just going about their lives and they are genuinely curious, right?
And because there's this kind of vacuum about real information, that's where you get kind of conspiracy theories, people, the people with the loudhorns can come in and fill that space.
And I saw it as an opportunity where people that do study the night sky every day, people that do fly airplanes every day that deal with airspace and think about this topic could go into this space that's otherwise taboo and fill it.
with real information, with real facts, with real data.
Do we have all the answers?
No, but that's science for you.
Right.
And so I took it as kind of an invitation and actually a call to say,
wow, there's something going on here.
Like, we should be tempering this and using, you know,
Occam's razors and rational minds and look at data and, like, investigate this stuff.
And that's to the scientists, too, because, you know, I think there is, you know,
scientist says, oh, good, how could you go and talk about UAPs or UFOs? They would say the word too.
And I'm like, well, you know, most of the time people are seeing something, right? And it's a good
opportunity to educate them about how fast does a plane fly, right? How many degrees per second is
that traversing across the sky? You know, that's going really fast. It's going like a degree or
10 degrees per second. And if you take a video camera with that, like you can get weird looking
images. So it's an educational moment. How do you really?
act just as not an expert in or being involved with the testimony, you know, of the so-called,
I don't say harvesting, but just the, that they're collections of not only artifacts, but even
biologics according to one gentleman, David Grush. Talk about that as a scientist, as a non-expert
in that particular congressional panel. What do you make of that? Like the claims of famous, you know,
book came out, Lou Elizondo wrote a book about imminent, disclosure is imminent. What does that
sound like to a professional scientist, an astronomer who's got, as you and I are talking before
we start recording, we would love to have, you know, be visited by aliens as long as they're not
going to eat us and they'd probably, you know, eat me before they'd eat you. But the point is,
how do we, how do we like handle these kind of seemingly outrageous claims of spacecraft that
are bigger inside than they are outside and biologics and things like that, that now we're
having panels like a congresswoman in Florida's investigating this in all seriousness? So how do you as a
scientists react to such things? Well, I think that will always be there and persisted before,
you know, this became kind of a lightning rod topic in the last few years. There's always
been stories of this and they always will be, right? And there's always your, you know,
extraordinary claims requires extraordinary evidence and that will always exist for myself as a
scientist. People could come forward and say what they see and there's ways to investigate it,
right? And we don't have to get overly excited about every time someone
walking forward and claiming things like this. So I'm not bothered by it. And again, I think it's an
opportunity that shows that we need to educate the public more about what's happening. Now,
regarding like the conspiracies theory aspects of it, I think that will again always be there
because there's reasons why things are secured, right, that things move forward. This is nothing new.
It's been around since Roswell. Yeah. I appreciate the discussion on the Nova special about
Roswell and putting it in context. I mentioned the Galileo project, past guest, many-time past guest,
Avi Loeb. And his Galileo project is doing something different. It's also looking in the optical,
but it's doing other things like listening for audio signals and explain, compare and contrast,
you know, Panosetti with what they're looking for and what kinds of complementarity or
multi-messingerness you might enjoy with them. Well, I don't know all the details, of course,
about the Galileo project, but of course I think they're trying to look for aerial phenomenon
that's in Earth's atmosphere. So one of the striking differences, since we talked about
kind of science requirements and experimental, we're looking for things that are astrophysical and far away.
And so the way we designs, our instruments are different. The aperture sizes for the Galileo project
are really small at visible light. They're kind of like think about fish eye, all sky cameras.
So you can think about sensitivity of that. I think they also use radar. And the way that they
image the sky is very different than the projects I was talking about, where we're trying to do
something very extreme, which is this nanosecond, microsecond time regime. That's actually interesting
because we do detect aerial phenomenon, but that's not our goal. In fact, I have a student here
just, I have a student here undergrad because I love part of the joy of also running a lab here
at University of California, San Diego is working with the students and educating and getting people
excited about the topic of life in the universe. But this student is working on trying to detect
and correlate airplanes and satellites in real time to what's registered. And so we do track some of those
aerial phenomena. Flight aware. But it's a completely different project, different technology,
different science goal. That's exciting. And a couple things to close with. One is, you know,
there's a famous quote from Winston Churchill that I really like. He said that he succeeded because
he proceeded from failure to failure without loss of enthusiasm. When you come against evidence that
maybe disputes or refutes your hypothesis, how do you know what to stop?
Like, how do you know when to turn off an experiment?
And I want to segue that into something that the general public can maybe glean for their benefit,
which is, you know, how do you know when you're wrong as a scientist?
Because a lot of, you know, I read some study and my audience hates when I mention it.
But, you know, if you exclude the times when Venus is above the horizon, UFO settings in America go down like 70%.
Yeah.
Now, you would think that that would diminish their enthusiasm a little bit for then claiming that, you know,
there are actually UFOs and we're just coming.
covering it up or when you see these recent drone sightings in New Jersey and they've got a flashing
red light on the right wing and a flashing left green line. That's exactly what all airplanes have
in America and around the world actually. So how do you know when to, you know, kind of close the
books or can you say, you know, well, we just don't know enough and we'll always keep searching?
How do you as a scientist and how should the general public know when they've been falsified?
The thing is for SETI, like everyone I think I meet thinks scientists do this.
But we don't. As you know, there's only like, I think I once testified, there's only two dozen
dedicated science. There's more in the NBA in Los Angeles. So that's always shocking me. So the answer is
that there's so much face space to study. We talk about wavelength coverage and radio and visible
light and infrared. There is new technology to do exploration for it. When you start an experiment
like this, the reason why this is so interesting to me is that we haven't designed an instrument like
this, we don't know what we're going to detect. Do I think we're going to detect interstellar
communication? I always temper that with my students. No, we're not going to detect that. But nobody's
ever looked. And as we've learned, usually in history, what we've learned is that if you look at
the universe in new ways, you usually discover something interesting by the natural world. And so
I don't know if we'll detect anything. I think for this, you have to run it for the amount of
time we say we're going to run it. So as you know, we provide limits. Okay, you do this in cosmology.
You say, I'm going to observe this amount of time to get to this limit. You know this very well.
We do similar things. We try to apply to some sensitivity limit to that experiment. For myself,
in this space space of experimental study or experimental technosignatures, I mean, this is an exciting time.
You can go in any other area either archival research or build a new instrument. So there's no
shortage of phase space there. And you know, Jill Tarter always equates it with like us walking
down to La Jolla Shores here with your pint glass and scooping out water of the ocean and looking in the
pine glass and saying there's no fish in the pint glass, therefore there's no fish in the ocean,
right? Although I told her if you don't find some microbes in it, there's something really wrong.
Well, that's true. But, you know, it's the same thing. Like that analogy of like the pint glass
to the volume of the ocean. I mean, comparatively to everything else we've done in astrophysic
is. Now, astrophysics, it's nothing. Yeah, it's minuscule. Well, Shelley, I always like to conclude
the podcast by asking a kind of existential or deep question. I want to ask you one that ties into the
name of the podcast into the impossible. It comes from Sir Arthur C. Clark's famous saying that the
only way to discover the limits of the possible is to go beyond them into the impossible. And I want
to ask you, as someone who's done just incredible things, I always say that one of my highlights
of my careers that I was on the committee to hire you 10, 15 years ago. I can't believe it. And
and you brought so much renown to this institution. What advice would you give? You've got 20 seconds,
30 seconds with a 25-year-old Shelley Wright. What do you say to her? What do you tell her to give her
the courage, to give her the inspiration to go into the impossible as you've done? Authenticity.
It's a short life and try to like follow what drives you as a scientist. And we're talking about
science here as well. But, you know, passion is what pursuits you want to pour your energy into.
For the impossible portion of it in science, I would say, you know, take some risk.
You know, you commented on, you know, your Winston Churchill quote, which is totally true.
Most of science is failure.
Every day we're running into dead ends.
And I think to really do cutting edge science and get to the forefront of discovery, you have to take some risk.
And I would say, don't be afraid of that.
Shaddy, right.
Thank you so much for being here on the end of the possible.
I hope we have you on many times.
appearance now, you got your SAG after card probably for this wonderful appearance,
PBS. Now we'll have links to that. We'll have links to your website and your talks at SETI Institute
that are so amazing and inspirational. Thank you so much for everything you do and for coming on the show.
Yeah, thank you for having me. Great. Thank you.
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