Building a Submarine for Titan's Methane Ocean
Washington State University researchers are working with NASA to determine how a submarine might work on Titan, the largest of Saturn’s many moons and the second largest in the solar system. The space agency plans to launch a real submarine into Titan seas in the next 20 years.
The researchers re-created a Titan ocean in a laboratory. They have published a paper on their work in the journal, Fluid Phase Equilibria.
Sunlight glints off of Titan’s northern seas this near-infrared, color mosaic from NASA’s Cassini spacecraft.
Credit: NASA/JPL/Univ. Arizona/Univ. Idaho
Because of the possible lessons it could provide here on Earth, NASA has been studying Saturn and its moons for more than a decade with data collected from the Cassini spacecraft.
The submarine that the agency is designing will have to operate autonomously. It will need to study atmospheric and ocean conditions, move around sea beds, and hover at or below the surface. The engineering is even trickier because, unlike the nearly homogeneous water in earth-based oceans, the concentration of ethane and methane can vary dramatically in the Titan oceans and change the liquid’s density properties.
Ian Richardson, a former graduate student in the School of Mechanical and Materials Engineering, got the chance to tackle how NASA might build a submarine for the extreme conditions. In WSU’s cryogenic lab, which studies materials at very cold temperatures, Richardson re-created the atmosphere of Titan and tested how a small heated machine might work under such conditions.
Richardson, who holds a bachelor’s degree in mechanical engineering from WSU, has had a longtime interest in space and space exploration technologies. He was WSU’s first-ever recipient of a NASA Space Technology Research Fellowship, which included an internship at NASA’s Glenn Research Center in Cleveland, Ohio. It was while working as an intern on a separate problem that a NASA scientist approached him with the problem of designing a submarine for Titan.
This is a WSU Methane-ethane Titan effervescence diagram.
Credit: Washington State University
Simulating Titan seas
The WSU research team built a test chamber that housed the liquid mixture at very cold temperatures to simulate the seas of Titan. They added a two-inch, cylinder-shaped cartridge heater that would approximate the heat that a submarine would create.
One of the biggest challenges for researchers was understanding bubbles in the Titan seas. Add a submarine powered by a heat-producing machine into the very cold Titan liquid, and nitrogen bubbles will form. Too many bubbles would make it hard to maneuver the ship, see, take data and manage ballast systems.
Shooting video at -300 degrees
The next big problem, said Richardson, was getting a video in difficult conditions. Their study was conducted at 60 pounds per square inch of pressure and nearly -300 degrees Fahrenheit. Richardson’s group engineered a solution using an optical device called a borescope and video camera that could withstand the low temperatures and high pressures to visualize what was going on within the test chamber.
“Those aren’t the friendliest conditions,” he said. “You have to come up with creative solutions.”
The researchers succeeded and took video footage of ethane-methane rain and snow. The group also studied the freezing temperatures for methane and ethane lakes and determined that, because of a small amount of nitrogen in the liquid, the lakes freeze at lower temperatures than would be expected: 75 Kelvin, or -324 degrees Fahrenheit, instead of 90.5 Kelvin.
“That’s a big deal,” said Richardson. “That means you don’t have to worry about icebergs.”
The researchers are looking to continue the work with NASA to update the Titan Submarine design.
Contacts and sources:
Washington State University