Sean Carroll's Mindscape: Science, Society, Philosophy, Culture, Arts, and Ideas - 42 | Natalya Bailey on Navigating Earth Orbit and Beyond
Episode Date: April 15, 2019The space age officially began in 1957 with the launch of the Sputnik 1 satellite. But recent years have seen the beginning of a boom in the number of objects orbiting Earth, as satellite tracking and... communications have assumed enormous importance in the modern world. This raises obvious concerns for the control and eventual fate of these orbiting artifacts. Natalya Bailey is pioneering a novel approach to satellite propulsion, building tiny ion engines at her company Accion Systems. We talk about how satellite technology is rapidly changing, and what that means for the future of space travel inside and outside the Solar System. Support Mindscape on Patreon or Paypal. Natalya Bailey received her Ph.D. in aeronautics and astronautics from MIT, where she helped invent a new kind of ion engine. She is currently co-founder and chief executive officer of Accion Systems Inc. She has been included in 30 Under 30 lists from Forbes, Inc, and MIT Technology Review. Accion Systems Wikipedia page Twitter Talk on the Human Side of Rocket Science Real-time map of satellites currently in orbit
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Hello, everybody, and welcome to the Minescape podcast. I'm your host, Sean Carroll. And today we're going to talk about space travel. One of the things that you don't necessarily appreciate when you start talking about space travel is the very different scales that we might be talking about. So we're not talking about traveling to other stars today, anyway. We're not even talking about the very down-to-earth mission of taking a gigantic rocket and launching it into space to put up human beings or satellites. What we'll be talking about is,
Once you get there, once you're out in space, let's say you're in orbit around the Earth,
how do you move around?
The big problem with space travel is carrying weight, carrying mass up into space.
And if you rely on conventional methods of propulsion once you're up there,
that means you need an awful lot of fuel just to adjust your position in orbit.
So today's guest, Natalia Bailey, is an aerospace engineer who has started a new company called Axion Systems.
That's ACC-C-I-O-N.
named after a spell in Harry Potter, not after the hypothetical small particle that could be the
dark matter. What Axion Systems is doing are building ion drive engines. If you're of a certain
age like I am, you remember ion drives as being this way that you might investigate interstellar
travel, because an ion drive can provide a small amount of propulsion, but for a very long time
with very little fuel being wasted. So Axion Systems is building these incredibly tiny, you know,
centimeter-sized rocket engines that can be put onto little tiny satellites like
CubeSats that you and your educational institution could build and launch into space yourselves,
and then they will help you move them around from place to place.
This is going to be an important part of a burgeoning ecosystem where we have a lot of new
satellites in space that hopefully will not be crashing into each other and hopefully
we'll be organizing themselves in the most efficient way.
It's also a stepping stone, of course, once you're in space at all,
once you're in orbit, you're halfway to anywhere, you're halfway to Mars, you're halfway to Pluto or
whatever. So this is going to be an important way that we advance the cause of traveling through the
solar system in much more efficient ways. So this is a great conversation, and we did, you know,
Natalia and I are both science fiction fans ourselves. So near the end of the talk, we forget about
the solar system and think more broadly about traveling through space. I do want to apologize
because the audio quality on this one fades near the end. It's fine at the beginning, but the last
15 minutes are a little rougher. I tried to clean them up as much as I could. You know, these
podcasts, some of them I do at my house or in my office. Others I do remotely. I will travel to
somebody else's place or at some conference or something. Some of them you got to do over the
computer, right? And that's the biggest challenge. I've been investigating different software,
different websites, different services to do this. Sometimes they work really well. Sometimes
not as well. I apologize to the listeners and to Natalia that this time didn't work as well. But I'm
trying to get better at it, still new at this, and I think that I am getting better at it.
So hopefully this is a temporary glitch.
The content of the discussion is really, really great.
So I think you're going to enjoy this.
Let's go.
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Natali Bailey, welcome to the Mindscape podcast. Thanks for having me, Sean. So there's obviously
we all know that the orbits above us, the sky above us are, is filled with satellites. I think maybe
people don't really have a very good idea of how densely packed.
the space is with satellites or how not densely packed.
We're hearing about the fact that there's a lot of space debris up there.
But on the other hand, space is really big, right?
And, you know, you can have a lot of things up there without any of them running into each other.
Could you just, like, set the stage for us a bit?
And what is the current environment up there in near-earth orbit and beyond?
Sure.
So as far as the Earth-orbiting satellites that are focused down to,
here at people living on our planet. Every year there are, you know, around 1,000 spacecraft launched.
That number has increased from the previous kind of space industry, how we've done things for
the past 50 years. It's been increasing every year for the past decade. I think we'll probably
start to see numbers more like 3,000, 5,000 spacecraft launched annually. So now, now,
all of those things last anywhere from, you know, a few months on orbit all the way to 15 or 20 years on orbit.
And so you can, you know, do that math and figure out how many of those are up there.
But the other thing that has people in this community a bit worried is that sometimes satellites collide with one another or hit another object in space and they themselves turn into.
you know, 10,000 new pieces of debris.
And that can actually have a kind of waterfall sort of effect called the Kessler syndrome,
where potentially we could reach a point where there are just so many pieces of this debris
in orbit that the problem kind of runs away and we keep creating more and more debris.
And low Earth orbit becomes a bit unusable for these earth-facing applications.
So we're keeping an eye on that.
But like I said, the number per year is about 1,000 and growing.
And it's an exciting time in the industry.
Yeah, I bet that most people, because me, didn't realize that the lifespan was only 10 or 15 years.
So that means that a thousand satellites are falling to Earth every year, right?
Yeah, that's about right.
And is that just, is that lifespan specific to near?
Earth orbit, lower Earth orbit? I mean, how should we in our brains visualize the different
places that we put these satellites? That's a great question. So a satellite launch to about,
I think it's, you know, 300 or so kilometers will stay there for about a year. A satellite
launched to 500 kilometers could stay there for about 20 years and it's actually an exponential
relationship with altitude between altitude and lifetime. So if you go much above 500 kilometers
and that's the distance above the earth, you end up basically putting things there that for the
all reasonable purposes end up becoming kind of permanent fixtures, which is not a great
position to be in. So really the UN and then NASA and various space agencies,
agencies prefer that things only have about a 20 to 25 year lifetime in orbit. So that either means
500 kilometers and below or that these objects have a way to de-orbit themselves at the end of
their useful lifetime. And presumably they burn up in the atmosphere. There's not a threat that
they're going to land in San Francisco and hurt people, right? Yeah, I think, I believe I read somewhere
that you're more likely to be attacked by a shark and struck by lightning in the same day.
then you are to be hit by a piece of debris from a spacecraft.
If I take that statistic seriously,
I presume that means that no one has ever been hit by a piece of debris from spacecraft.
Okay, good.
I didn't realize that NASA and the space agencies actually encouraged people
to launch their satellites into lower Earth orbits specifically so that they don't last,
so that part of the solution to the problem of overcluttering orbit is make it temporary.
Yes, exactly. Things only become really problematic if they're up there for, you know, five, 10, 15 years. Otherwise, they de-orbit on their own.
And, of course, there's a special geosynchronous orbits where you orbit once every 24 hours, you can hang out above some particular place on Earth or at least some particular latitude, sorry, longitude on Earth. But that's much further out, right?
Yeah, exactly.
much further out, much more expensive to reach.
So that's more for the handful of Fortune 500 companies and then the space agencies.
And that's roughly 40,000 kilometers versus the kind of 400 we've been talking about.
Okay.
And the environment there in terms of what satellites are up there is changing.
Obviously, we have communication satellites.
We have defense department stuff and NASA stuff.
But these days it's becoming a lot cheaper, right, to just send something into space.
Yes, exactly.
So the past, I guess now maybe 15 years, you've had this fantastic combination of private money and coming into the space industry.
And then Moore's law making smaller electronics still quite capable.
And now we're able to package those into smaller spacecraft.
You had this ever-increasing demand for the Internet.
And so these various factors have come together,
and space has as a result become more accessible
and also more desirable for various applications
and, you know, more affordable.
So smaller satellites mean that more countries can access space,
more organizations, even, you know,
we're working with a high school team and they're also, you know, hobbyists in their garage
building satellites.
Which I will never stop being abused by it.
But is this the CubeSat idea?
Explain to us what a CubeSat is and why it's so fun.
Sure.
A CubeSat is kind of the one industry attempted a more standard form factor for a satellite.
So as you know or can't imagine, a standard.
a standardized anything basically can lead to reduce costs
and therefore more users around the world
being able to leverage spacecraft.
So a cube set, one cube, one unit is 10 centimeters by 10 centimeters by 10 centimeters.
So a thousand centimeters cubed and to give you a more physical sense,
you could fit a softball inside of one U.
What's a little bit more popular is a 3U,
so that looks a little bit more like a shoebox or a champagne bottle.
And there are actually commercial companies now launching 3U CubeSats
that are able to generate revenue,
which is an extremely new thing in the past decade.
And yeah, so you mentioned high schools.
How much does it cost?
Let's say I have built the CubeSat.
let's say I'm not very good at it. I just built it at home, but I trust it's going to go up there.
How much would it cost me to get it on a rocket and launch into orbit?
If you are a high school, you know, all in, you're probably spending 20 to 40,000.
If you're an individual or a commercial business, you're spending maybe $150,000, $200,000.
You mean they charge me more because of an individual, not a high school?
Yes, there are a lot of discounted launch opportunities for academic projects.
I see. Well, $100,000 is probably outside my price range for building my personal vanity satellite.
Yeah, well, it keeps coming down.
Yeah, exactly. That's right. And when you say there are companies doing the launches, so they're building rockets.
Obviously, we hear about NASA launches, we hear about SpaceX and Blue Origin and so forth.
But how many companies are there launching things into space?
So you'll have to fact check me on these numbers, but in something like 2008, I believe there were around 80 active space companies.
And then 2018, there were something like 800.
And now some of those are not the ones actually sending things into space, but they're part of the value chain somewhere.
So that gives you a sense of the growth in recent years.
Okay.
Yeah, no, I really had no idea.
And are they launching from their home base?
Or do they rent, you know, space at Cape Canaveral or something?
Yeah, there are a few launch sites around the world.
The, you know, the ones I hear most about are people launching from India on their launch vehicle.
You know, in the U.S., there's the Cape, like you mentioned.
And then on the West Coast, there's Vandenberg.
There's also Wallops, that's off the coast of Virginia, but that tends to be more of the government launches.
And then our first launch was from New Zealand, so that's a new thing for the industry.
Okay, yeah, that's cool.
I mean, it makes sense to have it near the ocean, right, in case something goes terribly wrong?
Yes, exactly.
Range safety, they call it, so try not to fly over children and homes and things like that.
And what are most of these satellites doing?
These thousands of satellites that are going into orbit every year?
A couple main missions.
Probably the most prevalent one is communication.
So whether that is direct TV or serious radio to broadband internet to IOT-type type of
services, those all fall under communications.
The other main segment is Earth observation or imaging.
So using, you know, various spectral imagers to infer things about the planet for, you know,
national security or climate, agriculture, asset tracking, things like that.
And then, of course, you have some of the pure science missions looking at
the atmosphere, looking at, you know, icebergs melting, doing other types of earth and atmospheric
science. And then some will separate out maybe military applications, but really they can be a
combination or one of those three types that I already mentioned. Right. And I presume that most
of the high school ones are trying to do some science, or are they trying to do communications?
Yeah, most are doing science, one of the ones, we, we,
worked with was taking pictures of Venus.
Oh, okay. That's cool. So it's not just looking at the Earth. They can make their own
little space telescope and send it into orbit. Yeah, exactly. Folks knew the Colonel approved of his
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let's go places. All right. I did not know that. Okay. You've mentioned your own satellites,
but you're not so much in the satellite business as you are in the little rocket engine business,
right? So once these satellites are up there, you may be happy with where they're located or how they're
orbiting, but you might also want to push them around. And that's where you come in. Is that right?
Yes, that's right. So a very typical use case for one of our systems is you launch your satellite, but maybe you had to purchase a cheaper or sooner launch, so it's not quite where you wanted to go or you weren't put precisely where you needed to be. So you need a propulsion system to raise or lower your orbit. Initially, if you launch a group of satellites, you also don't want them to stay clustered together in a
very tight group, so you need to phase those out along an orbit. Then, you know, presumably your
mission lasts for five, seven, 15 years. There are all sorts of forces acting on a spacecraft when
it's in orbit, especially over that long of a period of time. There's gravity and atmospheric drag
and other perturbations. You may need to avoid collisions with debris like we talked about.
All sorts of reasons over the lifetime, you may need to maneuver. And then at the end of your
satellite's lifetime, you're responsible for making sure it de-orbites responsibly and burns up in the
atmosphere. So you also need propulsion for that. Okay. So what do people usually do these days? What is the,
what is the most typical kind of propulsion you would hook up to your little satellite?
Well, the status quo of the industry, frankly, has still been really large satellites. And there are
existing ion engines. We build a type of ion engine. There are really large ion engines that work on a, on a
geosatellite. But those don't scale down. And so the new industry forming around smaller satellites
doesn't really have a solution today. There are several people trying to scale down the traditional
large technologies to fit on small satellites. Those have some kind of fundamental plasma physics
limitations that we could get into. And then as a kind of backup plan, it's possible to use a type of
chemical propulsion, so like a smaller, same technology as a rocket for launch, but a much smaller
version, those are not very fuel efficient, which is why they're not very popular. Or you could even
do something like a can of compressed air and open that and use that thrust, but that's kind of the
least efficient method. So those have been backup plans, but you really need something that's much
more fuel efficient to close basically all of these business models and make these missions
viable. Right. Yeah, let's get into this a little bit. I mean, I think the can of compressed air
is a hilarious way to push your satellite around. But I think probably most people have in mind
the traditional chemical propulsion where you burn some fuel and push yourself around. What is an ion
engine compared to that? What's the very idea of an ion engine? Sure. So chemical rockets that most people
think of when they think of rocket science or propulsion.
The, you know, fundamentally you are releasing chemical energy by breaking bonds through
combustion and transferring that chemical energy into kinetic energy to push the spacecraft.
So you have, let's say, hydrogen and oxygen and you combust those two fuels, fuel and oxidizer
together. You end up with a very hot gas as a result, and that is forced through a nozzle and out
the back of the spacecraft, and the spacecraft moves in the opposite direction. So that's chemical
propulsion. And fundamentally, that's based on the conservation of momentum. Stuff out the back
pushes the spacecraft forward. So electric propulsion, which is what we do, based also on conservation
of momentum, stuff out the back, pushes it forward, but we use electrical energy to accelerate
a charged particle out the back of the spacecraft, so electrical into kinetic rather than chemical
into kinetic. And it's actually more efficient to do electrical into kinetic in terms of the unit
mass. However, you need your own power source when you're doing the electrical,
conversion, chemical carries the power required within the reaction. And so there's, there's a
tradeoff there and it's also a bit slower. So you send fewer, fewer particles with mass out
the back. So you need more time on orbit to accumulate to get up to the speeds that you would
like to reach. But we found that most people in the industry actually have that time available and
would trade it to benefit from the fuel efficiency savings. So the very, very basic idea is you just
charge up an atom, you ionize it, and then you put it in a strong electric field and push it. So
instead of burning some fuel, you just take some atoms that are lying around or molecules. I don't
know, hopefully you'll tell me. And then you can just accelerate them as long as you have
electricity and a battery or electrical power source lying around. Yes, that's right. And so
the idea of an ion engine, I remember reading, at least in the 70s, this was going to get us
to interstellar space. But the technology already exists. It pre-dates your company, but you're
just doing a different spin on it? Yeah, that's right. Ion engines have been used on
commercial spacecraft and on interplanetary spacecraft.
But they, it's near impossible to scale down this, that particular technology to fit on a
smaller satellite.
So what kind of technology is it?
Do they use on the big ones?
So a conventional ion engine works by injecting a neutral gas into an ionization chamber.
So they'll inject xenon or argon into a chamber.
into a chamber and they'll also inject a stream of high energy electrons and the job of those
electrons is to find and collide with one of those neutral atoms and to kick off an electron
thereby ionizing the xenon atom so now you have a xenon ion and then some fraction of those
xenon ions hopefully makes it to the downstream grid where there's actually two grids and there's an
electric field between them. So if an ion gets, you know, finds its way into this electric field,
it's accelerated out the back of the spacecraft producing thrust. Okay, I see. So I can already,
even though I'm a theoretical physicist, not an engineer, I can detect the possibility for
some inefficiencies in this initial process where you're just squirting gas into a chamber and ionizing.
Yes. So even, even at the larger scales, there are several inefficiencies. You're losing ions into the
walls all the time. And then as you, you could also imagine as you tried to scale this technology
down, the first thing you do is you make that ionization chamber smaller because it has to fit on
a smaller spacecraft. And what you've essentially done is reduce the amount of time, the residence
time that the neutral xenon atoms and those electrons spend in that chamber. So you've reduced
the likelihood that they'll collide with one another. And so you basically don't form any ion
if you make the chamber small enough.
So to combat that, you have to increase that likelihood again.
And so you inject more high-energy electrons into the chamber to improve your odds.
But now you have so many high-energy electrons,
and many of them end up going right into the walls of the chamber.
And to get back to that same ionization fraction,
you actually put so many into the walls that you melt most materials known to man
that could be used in this application.
So it actually doesn't really close on many of these, the scales of these smaller satellites.
Okay.
So your company is devoted Axion, right?
Is that how we pronounce your company's name?
Yes, axon.
It sounds exactly like a particle physics, hypothetical dark matter candidate.
But it's spelled differently.
Right.
So you are devoted to having a better technology that can be made smaller and more portable for the ion engine idea.
Yes.
So we can't get away from conservation and momentum.
And we know that we want...
That would be bigger news.
I would have had you on the podcast earlier.
It would have been a different podcast.
Yeah.
And we know that we want to use electrical energy to accelerate charged particles out the back of the spacecraft.
So those things hold.
But how can we maybe get away from this ionization probability and needing to inject this gas and these electrons?
So we looked at using instead a liquid propellant.
It's called an ionic liquid.
actually, and they're quite popular in the battery and electrochemical cell applications.
And they're really just positive and negative ions that happen to be liquid over a wide range
of temperatures.
They're not in solution.
There's no water or anything.
It's just positive and negative ions.
So we took these liquids and we said, well, can we apply this same electric field that
those ion engine guys apply between their grids to accelerate their ions?
but can we not only accelerate ions,
can we also extract ions of one polarity out of this liquid
and then accelerate them with that same potential,
with that same electric field?
And it turns out that if you are clever with the ways
you kind of orient the geometries and designing systems, you can.
And so we don't need to ionize anything on orbit.
We already have positive and negative ions,
so we don't need this large chamber for these collisions
to occur in, we just really need that grid and this source of ion.
And the reason this, you know, we, my co-founder and I were, we actually met as grad
students in a lab and weren't necessarily, we didn't have entrepreneurial aspirations at
the time.
But the reason this, that there was this need for this and there was great timing was
this is actually inherently happening on a very small scale.
This ion emission from these liquids occurs within a region of about.
20 nanometers. And so instead of taking something really large and trying to scale it down and
basically tanking the efficiency, we started with this mechanism, which happens on a small scale,
and now we can just parallelize it and scale it up to be able to work on satellites of all sizes.
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Prices in participation vary. I see. Okay. And so the the main difference here is that in the chemical
propulsion, the actual propellant is the same thing as the fuel, right? I mean you burn it and then you
expel it, whereas here you will carry around this little liquid of ions. It's sort of pre-ionized
in some sense. I guess, I guess, are the different kinds of ions gently hugging each other and
you can easily take them apart. Yeah. And then, but separately, you have a source of power,
which is electricity. So do you carry a battery up there? Or do you, is it solar powered typically?
So we, yeah, we draw power from the spacecraft. So a combination of solar energy and batteries.
Okay, and so the limit is basically how much fuel you can bring up.
The limit for how much thrust do you have over the lifetime of the satellite?
Yes, that's right.
And how long do you have?
I mean, you're packing these into, you know, centimeters sized or, you know, tens of
centimeters sized boxes.
How much lifetime can you have for pushing yourself around?
Yes, well, that, you just nailed the big, the most important metric at Axion.
And right now, we've demonstrated that the technique works now to make it actually useful to various types of missions and customers with satellites' lifetime is the key here.
So when we spun out of our lab, we were operating for 10 hours, 20 hours.
Recently, we just broke 1,000 hours, and that's actually what we're now ready to go to market.
with that. So it's on the order of thousands of hours.
Okay, that's cool. And these are just so our audience is visualizing this,
these rocket engines are really tiny things, right?
Yes. So we have, we build a complete system with the thruster head where the ions are
extracted and accelerated, but also the propellant supply system, including the tank,
and then the power electronics for interfacing with the spacecraft. But the, the, the, the
Thrusterhead itself where all of the magic occurs is we build it in thruster chips.
And each chip is a square centimeter.
And you can arrange any number of these chips together in different places on a spacecraft to accomplish your mission.
So it's a square centimeter and it's thinner in the third dimension, right?
It's less than a cubic centimeter.
Yeah.
Okay.
So you basically like glue these to the walls of your engine and that's your rocket.
Yes.
To the walls of your satellite.
Right.
All right.
That is a very cool idea.
And has it happened yet?
Have you, are you in orbit?
Yes.
Well, when we were still at MIT, we launched a couple back in 2015.
And just recently, Axion launched our first two at the end of last year.
And now we're working on another three launches this year.
So yes.
But you're hoping to do a thousand launches in here, I presume.
Yes, exactly.
It's a growing, it's a booming thing, right?
Yep.
And how much thrust are we getting out of this?
Is this like a G or, you know, it's probably a tiny little amount, I'm guessing?
Tiny little amount.
Each chip produces about 12 and a half to 50 micronutons.
So on the lower end of that, that's about the, as much as a mosquito landing on your hand.
But you keep it up for hundreds or thousands of hours.
and you can actually move the satellite around is the idea, right?
Yes, and when you're in space and not, you know,
trying to get out of a gravity well or trying to compete against atmospheric drag,
the force really adds up.
And we're producing enough thrust to complete most commercial emissions today.
Yeah, just to be super clear, because I know it's clear to me and you,
but for everyone, nothing you're doing is solving,
the issue of getting into orbit, right? You are not launching the spacecraft. You're
gluing your little centimeter sized tiles onto the size of something that's already in orbit
and nudging it from one orbit to another. Right. We're doing in-space propulsion. So the
satellite has already been launched and then we take over from there. And that's always going to be
true, right? There's no version of this that's going to help us get into space. That's not the idea.
There are universes where that's possible where nuclear or some other anti-matter type of energy source is available to power a system like this.
Right now politically, I don't think that will be possible, but as far as the physics go, it's not impossible.
I see. So basically because is the limitation just how strong of an electric field you can have, or is it how much fuel you can carry around?
No. Actually, for launch, the current limitation is in the power supply system. So the specific power, power per kilogram.
Most power sources that people feel comfortable launching from a country with people living in it are to, that.
number is too low. The power per kilogram is too low. But there are, you know, there, there are
possibilities where you could launch small things with, with known power sources or with some more
theoretical ones in the future. And have I heard that people are imagining like 3D printing
launch systems that will get us into space? How, how close are we to a truly revolutionarily
new relationship with getting things into orbit and manipulating them there?
Yeah, I think, I mean, even today, some of the new launched companies are 3D printing,
a lot of the main components, or they're innovating around having purely electric pumps,
things like that.
So we're getting there in terms of the components.
Then there are things like operational considerations.
How do you build a factory around this when your demand is quite lumpy or uncertain?
And then it's a bit of a chicken and egg problem.
If they could be guaranteed, you know, 5,000 launches per year,
we could start seeing a lot of innovation on the launch side.
If we could be guaranteed, you know, $500 a kilogram to orbit,
we could see more innovation on the satellite side.
So fortunately, we have some really,
rich people that like launching stuff into space working on these problems. So I think we're heading in the
right direction. And that's not you. You're not one of those. You're the, you know, plucky little upstart.
Yeah, exactly. And I presume that because it's in space, like everything in space, there's a lot of
defense commercial or customers, I guess. I mean, there's a lot of applications for existing people.
I know that just this morning I read an article where India was able to shoot down a satellite.
And so they're now the fourth country that has officially been able to shoot down a satellite.
And it makes you think about the future of the militarization of space.
Yes. So right now, about half of the market is government or military.
And space in the 60s to 90s,
was a big asset for space-faring countries.
Now it's kind of flipped into a liability and we're so dependent on it,
but now it's not a rare place that only a few people can access.
So how do we protect the things we're so dependent on now up there?
And, yeah, I think, you know, the government and military side of that will change a lot in the coming years.
and there's a lot of things happening.
You know, if you're following the, you know, space force and the things happening in the Pentagon
versus what's happening in the Air Force and a lot of changes right now.
Yeah, well, I'm not really following it.
I mean, are there, so for the audience, is there specific changes that we should be looking out for,
even if they're not, you know, set in stone, but just what kinds of things are people contemplating?
Yeah, so the Air Force has traditionally been where most of the U.S.'s space activity
as far as defense has been housed under.
And the point I made earlier about it,
becoming a place we're trying to figure out
how to protect our assets in means that now
the Pentagon is considering creating a separate branch
of the military force space specifically in recognition of that.
And so there are moves happening like that
in some reorganizations.
as the U.S. tries to navigate our next couple decades in space.
And I can't help but think, you know, as someone who's trained as an astronomer,
one of the great things to do in space is to explore other planets.
Are your engines going to be useful for that kind of thing,
either getting, you know, once you're in orbit getting to other planets
or once they're there manipulating the orbits of satellites and probes that NASA,
somebody want to launch? Yeah, absolutely. So on our, on our roadmap is increasing the amount of
thrust or power we can produce per unit area. And fortunately, the particular technology we're
working on has the potential to be scaled along those lines in ways that are unlike any other
electric system that's known today, whether it's flight proven or theoretical. So we have,
this technology has legs and we can certainly see it being used on.
on crude spaceflight missions or interplanetary science missions in the future,
especially as we continue to improve that metric, the thrust per unit area.
Does it make sense to sort of use conventional fuel rockets to get into space
and then use ion engines to guide yourself to Mars or something like that?
Yeah, until we solve that power per kilogram issue, we were talking about earlier.
We'll continue to use chemical rockets for launch from a gravity well, which is a planet or a massive planet.
So we'll continue to do that and then use more efficient means once we're in space.
I mean, how do you personally see the future in the sense?
You know, there was this space race in the 60s and 70s.
We went to the moon and that was very exciting.
But now the United States, correct me if I'm wrong here, we can't even get
a person into space right now, right? As a country, we don't have that capability.
Yeah. So, well, right. I mean, we do send up U.S. astronauts, but not on our own rockets.
So looking looking a little bit farther ahead, I think, you know, there's a big question.
Is Mars the answer? Is the moon the answer?
are stations in between planets, the answer.
And I have my own opinion, which is that it's a bit risky to plant yourself in another gravity well once you make it off of one.
So I mean that if you get off of the planet Earth, it's probably worthwhile considering building an orbiting station, maybe at a around the Earth or something at a Lagrange point.
And I think I would change my mind a little bit more on that if there were planets that we didn't need to go terraform or that had really wonderful atmospheres and were more homey feeling for us.
We're quite frail.
So I think being able to design and curate our environment a little bit more will be a more feasible next step.
I like that what you call the gravity well, the rest of us call a planet.
Yeah, it doesn't have to be a planet, right?
Could be a moon, I suppose. Yes, that's right. But I get your point. Especially people who seem sanguine about the idea of terraforming Mars, it seems always very unrealistic to me when we're not even very good at controlling the climate of our own planet right here on Earth.
Yeah, I always come back to that too. And I don't necessarily view it as a like, oops, we messed up this one. Let's go.
find a different one. But I do think that if humans are around in 300, 400 years, it's probably
because we found a way to live off of just this one planet and to diversify a little bit in terms
of where we're able to support life. But I, yeah, I think we could probably make it easier on
ourselves by not picking somewhere that's already pretty harsh right off the bat.
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But you do think, it did sound like before you were optimistic about just building artificial space stations and living there.
Do you think that is a large scale possibility?
Yeah, and I think I see a more incremental path to doing that.
You don't have to get a lot of humans to a more distant planet.
You can build it in stages.
Yes, I can see that line a little bit more clearly.
It does, of course, the hard part of that is that it requires taking a lot of construction materials up into space, right?
If you would make something really big, if you want to put a million people on a habitat that you built artificially in space, that would be quite the undertaking.
But I guess you're saying, but at least you can do it bit by bit.
Yeah.
And aside from, you know, just having something to stand on Mars already, you don't really have much else.
We don't know if we could use the actual materials we find.
there to build anything. So I don't think the situations in those terms would look that much
different in the end. Yeah. And so between you and me, I know that the government and NASA,
it's not really between you and me because we're on the podcast, but it's always looking for a
bigger goal, you know, should we go back to the moon, should we go back to Mars? So it sounds like
you think that neither one of those obvious goals are the right ones. Well, the objectives are a little bit
different. I think there's still a lot of science to be done. You know, you don't, you don't end up in
my field working at an ion engine company without wondering about the origins of the universe and why
we're here and how planets form. So I think, yes, of course, there's, we, we don't understand
anything yet. And so there's always reasons to, to visit and keep supporting those types of
missions, but if we're thinking about it in the survival and longevity terms, I think there are
maybe other places or other ways to consider that.
And what about, you know, from watching science fiction TV shows, I imagine that in the future
we're going to be mining the asteroids for all of our valuable raw materials.
Do you think that's feasible?
And do you think ion engines are going to help us, you know, take an asteroid and push it
closer to Earth so we can mine it more easily?
Yes, I do think eventually we'll be able to kind of harness the resources that are beyond just our own planet. Absolutely.
I mean, this is a crazy unfair question, but what kind of time scale do you think that would involve?
Well, I don't even necessarily think it's impossible to do today. It's more of a question of those resources.
and priorities.
So given how things are looking today,
you could say it will never happen.
But I think technologically,
there aren't,
I don't think there are many parts of a mission like that,
at least for a very near-Earth object
that are actually infeasible.
Do you think, I mean,
how much should we know about what is in the asteroids?
Is it really,
I've never really understood the extent to which
it would potentially be worth it in the sense that is it actually easier, more efficient,
more economical to get certain materials from asteroids than it is just from here on Earth,
where we already are and we can breathe while we're doing it?
Yeah, so it's kind of a funny, you know, economical argument where, you know,
I know someone that was looking into mining asteroids for things like platinum,
but as soon as you start bringing back that amount of platinum to the earth and inserting it into the market,
all of a sudden the value of platinum has completely diminished.
And so how do you justify the cost of doing that?
But I think if it's a matter of the energy cost of, well, it's much more expensive to go back down to Earth to grab this water
or to grab these other materials that we can harvest that are passing nearby,
then I think there are a lot of instances where that equation works out.
Okay, that's good to know.
What about, so as we're spinning science fiction scenarios here,
for science purposes, could we imagine using engines, ion engines,
maybe like your own or maybe some other design, to capture objects in space,
capture a comet that is passing by?
I presume very informally that things that are moving by are just doing so quite quickly,
and it would be an impossibly difficult task to slow them down and bring them closer,
but maybe I'm wrong about that.
Yeah, so in poor space person form, I haven't really done the full trade through,
like if you needed to launch all of the propellant from Earth and to stage it nearby
until there was something you wanted to go to and attach to and then push it closer to Earth or do a few experiments.
I haven't walked through those scenarios in much detail.
But if we go back to the science fiction side of things a little bit,
you know, the asteroid that passed through our solar system not too long ago,
Oh, Muamua, that was shaped, you know, suspiciously like a solar sail,
that came from, you know, way outside our solar system.
And this is the first object to pass through that has ever done that.
And I absolutely think we should have done more with that one.
Very suspicious and worth studying, I think.
So, yes, I hope our technology can be a part of those types of missions in the future.
But I haven't walked through the full trade study.
Yeah, okay.
I think just to be fair to the audience,
You should probably fill in a little bit of the details because this is amazing.
I'm glad you pronounced the name of it because I can't pronounce the name of it.
Amuamua, is that it?
Yeah.
Yeah, this was this object, which is certainly from interstellar space, right?
It's not something that was already in the solar system, but it, for whatever reason, flew through the solar system.
And it was not in the shape of a little tiny ball.
It was apparently more or less big and flat.
And I know that Avi Loeb, a friend of mine, Harvard Astronomy professor,
suggested in the paper that, you know, maybe one of the things it could be is a solar sail, you know,
designed by some alien civilization. Many other people poo-poohed that idea, but, I mean,
maybe what you're saying is, look, if there's even a 1% chance, it would certainly be worth
checking that out. Yeah, exactly. And, well, I think you just did a good overview of what it was,
but it shaped, as far as we could tell, looked very peculiar. It was shaped in such a way that, you know,
could have captured photons from the sun or other stars to give it the force it needed to
actually make it to our solar system.
And then I think there was something odd about its trajectory that suggested that it had
had a burst of thrust or force for some reason.
And our best guess, as humans, that it passed by something that heated it up and caused,
you know, gases to expand and give it a push.
But I am still hopeful that there's more there that we should have looked into.
So I hope we get to the next one, and I hope to be a part of that.
I mean, don't you think, giving the aliens credit,
don't you think they could have designed a craft that would have slowed down and stopped
than just zooming by, like spending all that effort to send an object to another star system
and then only have a visit for a few weeks?
Well, you know, I think, so we're getting into my crazy theories of various things about the universe.
So I think there's got to be other life in the sense of other, you know,
self-replicating molecules.
So we're not alone in that there's other bacteria probably out there.
But I also, I'm not sure I'm convinced that anybody, any of one else that falls into that
life category has solved the faster than speed of light travel problem before they were
perhaps hit by a mass extinction sort of asteroid or something.
But that, let's say there was other life out there.
they generated a lot of knowledge, learned how to do some of these things, then were hit by
some sort of impact. Part of their planet Brogha often is traveling through our solar system as
Oumuua. We could probably learn a lot by studying it. So if I had to posit something, that's where
I've landed. No, I mean, I do think I'm very much an agreement with this, the philosophy that if
it's such a high reward kind of gamble, then, you know, yeah, let's take it. Let's at least explore that
possibility. But I don't think that there is, you know, a solution to the faster than light problem.
As a physicist, I think that's that problem is not going away. But do you think that nevertheless,
if that's true, if we don't ever go faster than light, what do you think is the prospect
for we human beings sending spacecraft to other stars? Well, I mean, Alpha Centauri isn't that
far away. I love the breakthrough star shot ideas about, you know, using lasers to send
tiny little chip-sized spacecraft past that star system and maybe take pictures and send them back.
And I mean, you know, honestly, the thing I love about that project is that every single
part of it is impossible today and it's so exciting.
Actually, yeah, let's, I think not everyone is going to know exactly what that is. So this was a
proposal. I remember Stephen Hawking was part of the PR push for it, but it came from Yuri Milner and the
other Breakthrough Prize people. Yeah, that's right. So there are several initiatives under the
breakthrough prize name, and there's Breakthrough Listen, Breakthrough Star Shot, and there was one
other that maybe we can record my voices knowing later. But this particular one, Breakthrough
Star Shot, the goal was to use a, I don't know, Goeillion.
and what laser to, so, you know, to accelerate a tiny spacecraft with little solar sails
to speed such that they could reach Alpha Centauri. And I think it was 20 years. And so that they're,
to get them close to traveling at, you know, a respectable fraction of the speed of light and that
their signal could come back in time so that people in our lifetime could actually start to
see this data coming back. But, you know, the laser doesn't exist. If those tiny spacecraft were to
and that signal back from that far away, you would need a receiver that's the size of the distance
between the sun and the earth to capture the data. I just love, you know, like we know what needs
to be done and none of it's possible today, but I think you have some of the smartest people
in the world thinking about it, which is really exciting. Yeah, no, that that's really great.
And I think that, you know, personally, since I don't think that we're going to go faster than
the speed of light, but I also don't necessarily think that that should be an obstacle to go
other stars. People say, well, if we travel at point one speed of light and then we'll all be dead
if there's a human being or a set of people in the spacecraft. But number one, you know, we could
just sleep, right? We could, you know, cryogenically suspend people. Or number two, we could come up
with therapies that extend human lifespans to thousands of years. And I think that that's, those are much,
even though those are nowhere near, technologically feasible now, they're much more technologically
feasible than going faster than the speed of light. So we should just learn to be patient about
these things. Yeah, I'm right there with you. I think humans in our, you know, frail biological
forms are the, are the main problem there. And so instead, you know, maybe we send some stem cells
and a robot or something and then see what happens. I see. So that, no, that's a new idea. So you
basically want to have the ingredients for a human being and send them into space rather than sending the whole
human being. Yeah, or the other way you could take it is, and kind of getting at what you said,
you know, various therapies to extend our lives. But really, I've started to buy into the idea that
really our memories are really the only things that make us kind of unique. And so if we can
just figure out how to read and write those, just package those into the spacecraft and then
you don't really need these animal forms anymore. All right. I think that makes, certainly I would be
surprised if the first probe that we intentionally sent to other stars had human beings on it.
That does seem to be an inefficient way to do it.
So what about the other way around?
You hinted just before that you think it's very likely that there is other life out there
in the galaxy, but maybe not other intelligent life because it destroys itself.
Do you have thoughts behind these probability estimates?
Yeah.
So I look at this recently.
I think the odds of getting to a self-replicating molecule are very high,
especially given the number of Earth-like planets in the universe.
So certainly I think that cropped up all the time.
Don't ask me what all the time means.
But then you have some other probabilities that need to occur,
depending on kind of the conditions on the planet.
Does that life need to make it out of the oceans onto land?
Do giant reptiles need to become extinct before mammals?
can really take over.
So I haven't really factored those in,
but the main problem I see is that to make it to that point,
that probability is probably about the same probability
as that whole planet getting wiped out by some sort of catastrophe.
I don't know if it's self-made or from the universe.
External, yeah.
But I definitely, while I don't think that we'll necessarily see another craft
from an alien planet, because, you know, Fermi paradox,
Like why haven't we already?
I do think there are probably signals or other signs of this life
and whether we need to travel to that planet to dig it out of the earth
or whether it got to the point where it's able to put off some sort of electromagnetic signature
or something.
I'm not sure, but I believe it's out there.
So yeah, so the Fermi paradox, you know, the idea that if any time in the past history
of the galaxy, intelligent life became spacefaring,
we should have noticed it a long time ago and we haven't yet.
You know, I'll be honest, my personal favorite solutions to that are that either life is really, really hard, that it's much harder than we think, because the biochemistry is not something it's fully understood yet, or intelligent life, technological life is much harder than we think.
I think these are two phase transitions we don't quite understand yet.
It seems that you are more inclined to think that intelligent life happens with a respectable
frequency, but then somehow it gets destroyed.
Is that fair?
I'm out on whether life makes it all the way to intelligent life.
I guess I would say that it probably does with some lesser frequency.
But yes, then the likelihood that it gets destroyed is even greater.
And then the tragedy is that knowledge is lost.
So each time every form is.
is starting over. So if we could just pass on, you know, the atomic theory or something,
maybe maybe then one of these civilizations could make it to light speed travel or at least,
you know, fire a little bit faster. What is your feeling about the search for extraterrestrial
intelligence as we do it these days? Well, like I said, I think, you know, it's possible
there are some sort of electromagnetic signals we should be able to pick up. So I know,
We do that type of listening, well, I think, fairly well.
And then really, I think there's probably a lot of evidence of, you know, life in the more
bacterial sense, but we have to kind of make it to those other planets or find bits of
them that have been blasted off by impacts or something passing your Earth to be able to
determine that.
So I kind of think it's just a matter of time.
Okay.
I mean, that's a, I like the optimism there.
Personally, I think that the chances that smart technologically advanced alien civilizations
are wasting their power by beaming radio waves out into space seems unlikely to me.
But, you know, again, if it's a tiny chance, it would change history if it were true.
So I have definitely in favor of looking just in case.
Yeah, I will forever remain really suspicious of pulsars too.
Like, what are those?
Those have got to be something that we don't understand yet.
It's always possible.
I wanted to end because every thing that interview with you always you mentioned that you kind of got into this game because what you really wanted to be an astronaut.
Yes.
Is that still an ongoing ambition?
Yeah, I'll keep applying.
I've never made it past the very preliminary rejection postcard phase.
And to be honest, I don't think I want to be the first person to go visit anywhere.
but I still have the dream very much to go do science in space.
I mean, is it still, even with private rocket launchers sending people into space,
is it still the prospect that people going into space are going to be officially astronauts,
or is space tourism an option for you also?
I'm more of, I'm not so much of a risk-paker,
so I would be really into going to a space station because I needed to do an experiment
that could only be done in microgravity like that.
Or maybe one of these orbiting stations will be built in my lifetime
and they'll need people to go figure out how to best design some part of it
or where to put the ion engines.
And so I'll go to help with that.
And I do think space tourism will become a bigger part of our lives
and our discussions going forward.
But I probably won't sign up.
All right.
Well, I hope that they finally come to their senses and pick you for it,
but not until you've finished.
perfecting these engines because I think that these ion engines are definitely going to be a big part of
how we look at the solar system and the earth in the near future. So Natali Bailey, thanks so much
for being on the podcast. That was a fun conversation. Yeah, thank you, Sean.
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