Everything Everywhere Daily: History, Science, Geography & More - Space Elevators
Episode Date: August 1, 2023You’ve probably seen footage of a rocket launch. There is a bunch of smoke and fire as the rocket lifts off to begin its flight to achieve an altitude and velocity which will get it into orbit. It... works, but it requires a lot of energy to get even a small amount of mass into the Earth’s orbit. What if there was a way to travel into space that didn’t require a rocket? What if going into Earth orbit could be just as easy as going up to the top floor of a skyscraper? Learn more about space elevators and how they could revolutionize space travel on this episode of Everything Everywhere Daily. Sponsors Expedition Unknown Find out the truth behind popular, bizarre legends. Expedition Unknown, a podcast from Discovery, chronicles the adventures of Josh Gates as he investigates unsolved iconic stories across the globe. With direct audio from the hit TV show, you’ll hear Gates explore stories like the disappearance of Amelia Earhart in the South Pacific and the location of Captain Morgan's treasure in Panama. These authentic, roughshod journeys help Gates separate fact from fiction and learn the truth behind these compelling stories. InsideTracker provides a personal health analysis and data-driven wellness guide to help you add years to your life—and life to your years. Choose a plan that best fits your needs to get your comprehensive biomarker analysis, customized Action Plan, and customer-exclusive healthspan resources. For a limited time, Everything Everywhere Daily listeners can get 20% off InsideTracker’s new Ultimate Plan. Visit InsideTracker.com/eed. Subscribe to the podcast! https://link.chtbl.com/EverythingEverywhere?sid=ShowNotes -------------------------------- Executive Producer: Charles Daniel Associate Producers: Peter Bennett & Thor Thomsen Become a supporter on Patreon: https://www.patreon.com/everythingeverywhere Update your podcast app at newpodcastapps.com Discord Server: https://discord.gg/UkRUJFh Instagram: https://www.instagram.com/everythingeverywhere/ Facebook Group: https://www.facebook.com/groups/everythingeverywheredaily Twitter: https://twitter.com/everywheretrip Website: https://everything-everywhere.com/ Learn more about your ad choices. Visit megaphone.fm/adchoices
Transcript
Discussion (0)
You've probably seen footage of a rocket launch.
There's a bunch of smoke and fire as the rocket lifts off to begin its flight to achieve an altitude and velocity, which will get it into orbit.
It works, but it requires a lot of energy to even get a small amount of mass into Earth's orbit.
But what if there was a way to travel into space that didn't require a rocket?
What if going into Earth orbit could be just as easy as going up to the top floor of a skyscraper?
Learn more about space elevators and how they could revolutionize space travel on this episode of Everything Everywhere Daily.
What if your perceptions about the past were wrong?
ThruLine is a podcast that takes you back in time to uncover the parts of the story that may have gone unnoticed.
It effectively turned day into night.
And how it shaped the world now.
Time travel with us every week on the ThruLine podcast from NPR.
Getting into orbit is not easy.
If you remember back to my episode on the rocket equation, in order to get a kilogram
of anything into Earth orbit requires a lot more than a kilogram of fuel.
You need a rocket, and then you need some fuel, but then the fuel needs to be sent aloft,
which requires more fuel, and then that fuel needs fuel, and so on and so on.
The end result is that you need a big rocket to send something relatively small into orbit.
Rockets are expensive, dangerous, and they can only be built so large.
They're fine for putting something like a communication satellite into orbit,
but if humanity wanted to do something much larger, like create massive rotating space stations
or send humans to planets around other stars, we'd probably need something else.
But how?
If you remember back to my episode on how satellites work, putting something into orbit isn't
so much a matter of altitude as it is a matter of velocity.
The reason why satellites have to fly so high over Earth is simply because we have an atmosphere.
At the speed you have to travel at to orbit the Earth, the friction,
caused by the atmosphere would make it impossible. So back to the original question. How do you get
something into orbit without a rocket? Well, what if you used a big gun? Could that put something
into orbit? That idea is not as crazy as it sounds. A giant cannon or magnetic rail gun could
put something into orbit. The problem is that unlike a rocket which gains speed over time,
a gun has to start at an extremely high speed and then slows down through the atmosphere. The
payload would have to be at orbital speeds the moment it leaves the barrel of the gun,
and the gun would be in the thickest part of the atmosphere near the surface.
What happens when something traveling at orbital speeds hits the atmosphere?
It usually burns up.
Such a system could work very well if you were launching something from the surface of the moon
where there is no atmosphere, but not from the Earth.
So, once again, how can we get into space without a rocket?
About that speed thing.
Getting into orbit, as I mentioned before, is about speed.
In the low Earth orbit, a satellite will go around the Earth about once every 90 minutes.
The higher the orbit, the longer it takes to complete an orbit.
Keep going high enough, and eventually the time it takes to orbit the Earth would be one day,
the exact same time that it takes for the Earth to rotate about its axis.
That point is known as geostationary orbit.
Anything at that point will just hang over the same.
spot on Earth. So if you can get enough altitude, you can sort of solve the issue of speed.
You can use the rotation of the Earth to provide the velocity. But you need a lot of altitude.
To put it into perspective, the International Space Station sits at an average altitude of 400
kilometers or 250 miles above the surface of the Earth. Geostationary orbit, however,
sits at an altitude of 35,768 kilometers, or 22,236 miles, almost a hundred times higher than that of
low Earth orbit. Or to put it in another way, it's almost three times higher up than the diameter
of the Earth itself. So we can reframe the problem. Instead of having to go really fast, we could
get around it by just getting to a really, really, really high altitude. However, that just creates a whole
new problem. How do you go 35,786 kilometers straight up? Maybe we could build a gigantic tower.
In theory, and this is just in theory, such a tower could work. However, it would have to be 44,700
times taller than the tallest structure ever built by humans, the Birch Khalifa. The problem is that
there's a practical limit to how tall we can build something. The larger the structure, the more weight.
The more weight, the wider the base of the structure would have to be.
In theory, again, in theory, it could be possible to build something as tall as Mount Everest,
but it would require a massive base to handle the compressive forces of gravity of all of that mass.
Even if we could build a structure so tall that it required a base of the area of an entire hemisphere of the Earth,
it wouldn't be nearly tall enough to reach geostationary orbit.
So we're back to our original question.
How can we get to geostationary orbit,
without a rocket. It turns out there might be a solution to the problem. In fact, the solution
of the problem was first considered as early as the 19th century by Konstantin Sealkovsky,
the same theorist that gave us the rocket equation. Seelkovsky originally came up with the
ideas that I've just gone through up till this point. He originally proposed the idea of a giant
tower, but it was more of a thought experiment, and as I just explained, it isn't actually possible.
No one took the idea seriously until it was revived in 1960 by another Russian, an engineer
by the name of Yuri Artzutanov. Artzatanov's insight was that rather than building a tower
using the ground as its base, you could use a platform in geostationary orbit as the base.
From the platform in geostationary orbit, you could drop a cable down to the surface of the
earth. By putting a counterweight at a higher orbit, the center of mass would remain at geostationary
orbit. Unlike Sealkovsky's tower, which would require materials with compressive strength,
Arzotanov's cable would require a material with tensile strength. Artzatanov's idea was unknown
outside of Soviet circles because he wrote about it in Pravda, a Soviet newspaper that academics
and engineers really didn't pay attention to. In 1966, a similar proposal called Skyhook was
discussed in the magazine science. While mostly a theoretical discussion, the authors did try to determine what
material the cable could be made out of. Assuming that the cable was of uniform width throughout,
they believe that the material used would have to be twice as strong as any material currently
known. In 1975, a retired NASA engineer named Jerome Pearson, unaware of what Art Zutonoff
had wrote 15 years earlier, published a paper titled, The Orbital Tower, a spacecraft
launcher using the Earth's rotational energy. Unlike the previous articles on the subject,
which were really just informal articles suggesting the idea as a thought experiment,
Pearson's paper was filled with calculations showing that such a structure could theoretically be possible,
and moreover, his paper was written for a scientific audience.
The idea, while interesting, remained firmly in the realm of science fiction for another 20 years.
Arthur C. Clark had a space elevator in his 1979 book The Fountains of Paradise.
Other science fiction authors used the concept of a space elevator as well.
Throughout most of the 80s and 90s, the idea of space elevators was mostly ignored.
However, in the 1990s, discoveries of new materials were made that changed attitudes towards
the idea of a space elevator, that being carbon nanotubes.
Carbon nanotubes had properties unlike any materials that humans had access to.
It had a tensile strength, orders of magnitude greater than steel or Kevlar.
It was so strong and lightweight that it could actually meet the requirements for
a space elevator. NASA held the first symposium on space elevators in Huntsville, Alabama in June of
1999, and from that, NASA published its first document on the idea titled Advanced Space Infrastructure
Work Group on Geostationary Orbiting Tether Space Elevator Concepts. After this, more and more time
and attention was given to the idea of space elevators. The Elevator 2010 contest launched, which had
cash prizes for teams that could develop technologies that could be used in a future space elevator.
Today, we are nowhere near being able to build a space elevator.
However, the idea is no longer dismissed as being crazy.
It's gone from being a thought experiment to today being more of a massive engineering challenge.
The biggest thing holding back a space elevator, other than an enormous amount of money, is material science.
While we can create carbon nanotubes, we can't create them at scale, especially the scale required for something as massive as a space elevator.
but assuming that the challenge could be overcome at some point in the future, what would a space
elevator look like? Here is a rough idea of how it would work based on several current proposals.
First, let's start with the tether. It actually probably wouldn't be a cable with a circular
cross-section. It would probably be a flat and wide tape made out of a single massive sheet of carbon,
probably in the form of something like graphene. The length of the tether would have to be massive,
not just extending up to geostationary orbit, but far beyond that, as the center of mass of the
tether has to be in geostationary orbit, or more likely a little bit higher. This would require
either making the tether longer or putting a counterweight on the other end. The tether would
have to deal with a host of forces, including atomic oxygen in the atmosphere which could react
with the tether, micrometeoroids that could hit it, wind in the atmosphere, the gravity of the
moon, and the Coriolis force. More on that in a bit. The tether would,
would not be of uniform width. It would have to be constructed to be slightly wider in geostationary
orbit than it is at its ends. The need for tapering is to have more strength in the middle
where it will experience the most stress, and to have less weight at the ends where there's
less stress. The tether would have to be attached to something in geostationary orbit, which would
require the construction of a massive space station. In addition to anchoring the tether,
it would need to be able to make small changes in its position to compensate for forces on the tether.
The tether also needs to then have some base station on Earth on the equator.
There have been several proposed sites for such a base.
It could be outside of a major city near the equator like Kito Ecuador or Nairobi, Kenya.
Another proposal would be to build a large platform in the Pacific Ocean that would be far away from populated areas.
The next thing that would be necessary would be the creation of a climber.
This would be the physical object that goes up and down the tether.
The climber needs to be as light as possible, but it also needs to have the energy.
to climb all the way to the top.
How to power such a vehicle is a challenge.
One idea is to power it with lasers from the ground for at least the first 40 kilometers.
The lasers would hit solar panels that would function off regular sunlight once it's
beyond the atmosphere.
Another proposal would be to have some sort of power in the tether itself, or to have
a compact nuclear reactor inside the climber.
The speed of a climber would have to be limited.
It couldn't climb at the speed of a rocket.
Assuming that a climber could travel at the speed of a high speed,
locomotive, about 300 kilometers or 180 miles per hour. It would take five days to reach geostationary
orbit from the ground. The reason for the limitation on speed is the Coriolis force. The top of the
tether is going faster than the bottom of the tether. With every increment that the climber goes up the
tether, it is going slower than the part of the tether it's at. That difference in speed will
cause the climber and the tether to lean to the west pulling stress on the tether. If the climber
were to move too fast, it could cause it to break. The opposite would occur with a climber going down
the tether as it would be faster than every incremental part of the tether that it reaches. There are a lot
of problems to overcome before we could even attempt to create a space elevator, and I'm pretty
sure that one will never be built in any of our lifetimes. If and when one were to be created,
it probably wouldn't even be built on Earth. The easiest place to build one would be on the
moon, which has less gravity and no atmosphere.
Nonetheless, the idea of a space elevator is a captivating one.
If one were to be built, it would be the greatest engineering achievement in human history.
We are a long way from having the technology to build such a thing.
But if significant advances in material science are made,
maybe our great-grandchildren, or their great-grandchildren,
could one day live in a world where going to space is nothing more than getting on an elevator.
The executive producer of Everything Everywhere Daily is Charles Daniel.
The associate producers are Thor Thompson and Peter Bennett.
Today's review comes from listener Jay Glucks from Apple Podcasts in the United States.
They write,
I'm addicted.
Every single morning I anxiously await the addition of a new or even repeat episode.
I've listened to Everything Everywhere Daily for several years and feel that I haven't even scratched the surface of episodes.
Thank you, and please don't ever stop.
Thanks, Jay Glucks.
I'd like to remind you that addiction to Everything Everywhere Daily is one of the
of the only addictions which is actually good for you. Four out of five doctors agree that a daily
dose of this podcast will benefit people of all ages. And that fifth doctor still accesses the
internet with the dial-up modem. Remember, if you leave a review or send me a boostagram,
you two can have it run on the show.
