homehome Home chatchat Notifications


This nuclear-powered probe will help NASA look for life on frozen worlds

NASA has bold ideas to look for ice on the frozen moons in our solar system.

Mihai Andrei
December 6, 2023 @ 12:14 pm

share Share

cryobot
Artistic depiction of the cryobot breaching into the ocean of Europa and looking for signs of life. Credit: NASA/JPL-Caltech

NASA has embarked on an ambitious quest to explore the possibility of life beyond Earth. We’re not talking about alien life in a galaxy far, far away — but right here, in our cosmic neighborhood. This bold endeavor, which could redefine our understanding of life in the universe, centers around the development of a cryobot. The cryobot aims to penetrate the icy crusts of Jupiter’s moon Europa and Saturn’s moon Enceladus, delving into the depths of these alien oceans in search of life.

Breaking the ice on alien life

If you’re looking for life in our solar system, you’re probably looking at ice. Sure, places like Mars or Venus look a lot like Earth at first glance, but life needs water to exist — at least life as we know it. “Follow the water” has been the mantra of astrobiologists for years, NASA says. Now, this mantra has taken the space agency to the frozen moons of Saturn.

These moons are super cold. Their surface is completely frozen. But there’s a twist: beneath the frozen surface, there lies an ocean of liquid water. Gravitational stress generates friction and this friction creates enough heat to melt the water.

This type of mission holds immense potential. There are dozens of frozen moons in the outer parts of our solar system, and some of them are promising when it comes to holding liquid water. In fact, some of these moons have more water than the Earth’s oceans. Add in the fact that ice shields them from radiation, and you end up with some promising conditions for life to exist.

Exploring these frozen moons and their potential for life is indeed a significant opportunity. Here’s why:

  • They have a lot of liquid water. The presence of liquid water on these moons indicates the possibility of habitable environments. This is most likely microbial life, but potentially even more complex organisms.
  • They seem to have the right chemistry. It’s not just water: these moons seem to have salts and organic molecules that are necessary for the building blocks of life.
  • They’re shielded from radiation. Without an atmosphere, radiation can be devastating for life forms. A thick blanket of ice can help with that.


Ultimately, we have a realistic chance of finding alien life in our very own solar system. But you need a way to break through the icy surface. This is where the cryobot comes in.

cryobot
Conceptual image of the Cryobot mission profile. A lander deploys a nuclear-powered probe, which melts through the ice shell to access the ocean below. A tether and wireless transceivers are deployed behind the probe during its descent for communication. Credit: NASA/JPL-Caltech

The cryobot is essentially a cylindrical probe. Its main goal is to melt through ice using heat. The heat melts the ice in front of the probe, and the ice then flows to the sides of the probe before refreezing. This method has already worked on Earth and has become a key way to study glaciers. However, the colder, thicker ice of alien moons poses a bigger challenge​​.

NASA tried several different designs in its Scientific Exploration Subsurface Access Mechanism for Europa (SESAME) and Concepts for Ocean worlds Life Detection Technology (COLDTech) programs. Ultimately, they zoomed in on this type of heat drilling approach.

To get this to work, NASA says four systems are crucial:

  1. The power system. Melting ice requires power, and with current technology, only a nuclear power system can work for this goal. Several nuclear power systems were tried. This technology is already within our reach, as demonstrated in previous missions.
  2. The heat management system. You generate a lot of heat, but you need to make sure it doesn’t affect the probe itself. So you need a system that can pump the heat efficiently. Here, NASA zoomed in on two independently pumped fluid circuits — one that circulates internally and one that circulates melted ice. Some of this has already been demonstrated, but an entire system that can function reliably is still a work in progress.
  3. A system to bypass blocks of material. Research suggests that it’s not just water ice that the probe will have to penetrate. These icy shells contain blocks of dust or salt, which may be more difficult to penetrate with heat, so you need a different system. This requires the cryobot to incorporate a mapping sensor that can detect such obstacles, and a combination of “water jetting” and mechanical cutting to break through them.
  4. A communication system. Being able to communicate with Earth while under a thick sheet of ice will not be easy. In order to do this, the cryobot must be tethered to the surface lander

This is all doable

exploring frozen moon
Europa Clipper could be an excellent opportunity to get a better look at a promising frozen world in our solar system. But this is a complex world with plenty of different features. Image credits: Howell and Pappalardo, Nature.

Of course, none of this would be easy. But NASA announced that it’s sticking with this concept. At a workshop where nearly 40 top researchers from diverse fields and institutions discussed this technology, the consensus was that it was feasible. Not easy, but feasible.

In addition to engineering developments, closer observations of these moons can also help NASA better prepare for this type of mission. For instance, the Europa Clipper is planned for launch in October 2024. The spacecraft is being developed to study the Galilean moon Europa through a series of flybys while in orbit around Jupiter.

The stakes are high. The potential for finding extraterrestrial life seems higher than ever. Humans have often speculated about this potential, but this is scientifically promising.

As NASA gears up for the groundbreaking cryobot mission to Europa and Enceladus, this mission is a continuation of our astronomical pursuit to understand the universe.

The potential discovery of life, even in its simplest form, on Europa or Enceladus would force us to rethink our way in the universe. Now, this goal may be within our sights.

share Share

How Hot is the Moon? A New NASA Mission is About to Find Out

Understanding how heat moves through the lunar regolith can help scientists understand how the Moon's interior formed.

This 5,500-year-old Kish tablet is the oldest written document

Beer, goats, and grains: here's what the oldest document reveals.

A Huge, Lazy Black Hole Is Redefining the Early Universe

Astronomers using the James Webb Space Telescope have discovered a massive, dormant black hole from just 800 million years after the Big Bang.

Did Columbus Bring Syphilis to Europe? Ancient DNA Suggests So

A new study pinpoints the origin of the STD to South America.

The Magnetic North Pole Has Shifted Again. Here’s Why It Matters

The magnetic North pole is now closer to Siberia than it is to Canada, and scientists aren't sure why.

For better or worse, machine learning is shaping biology research

Machine learning tools can increase the pace of biology research and open the door to new research questions, but the benefits don’t come without risks.

This Babylonian Student's 4,000-Year-Old Math Blunder Is Still Relatable Today

More than memorializing a math mistake, stone tablets show just how advanced the Babylonians were in their time.

Sixty Years Ago, We Nearly Wiped Out Bed Bugs. Then, They Started Changing

Driven to the brink of extinction, bed bugs adapted—and now pesticides are almost useless against them.

LG’s $60,000 Transparent TV Is So Luxe It’s Practically Invisible

This TV screen vanishes at the push of a button.

Couple Finds Giant Teeth in Backyard Belonging to 13,000-year-old Mastodon

A New York couple stumble upon an ancient mastodon fossil beneath their lawn.