U of I Researcher Part of Team to Send Robot Copter to Saturn Moon for NASA mission
A project to launch a robotic rotorcraft lander to Saturn’s moon Titan, envisioned by a Bipasesores researcher, has been selected by NASA for launch.
The mission, known as , involves 35 scientists from around the globe and is funded for up to $850 million. It is led by the and beat 11 other teams to win NASA’s New Frontiers Program competition.
“NASA’s missions of planetary exploration are one of the coolest things that we humans do as a species,” said U of I Associate Professor Jason Barnes, a founding member and deputy principal investigator of the Dragonfly project. “To have our idea be selected to actually fly is what every planetary scientist dreams about.”
Named for its insect shape, Dragonfly is set to launch in 2025 and arrive at Titan in December 2034. Its primary mission will last a little over two years. With eight rotors, the dual-quadcopter will be able to fly from site to site on the alien moon, potentially traveling up to 10s of kilometers at a time.
Titan joins Venus, Earth and Mars as the only places in the solar system with substantive atmospheres and solid surfaces. The moon’s dense atmosphere and low gravity actually make flying easier than it is on Earth. Scientists have learned through the 2004 mission that Titan likely has:
- Rivers, lakes and seas, although the liquid is likely ethane and methane.
- An ice layer that covers the moon and hides a .
- Gigantic dunes made of complex organic compounds called hydrocarbons, which likely originate in the atmosphere.
Researchers believe liquid water could periodically come in with hydrocarbons at the surface, creating a concoction similar to the primordial soup that led to life on Earth. By studying Titan’s chemistry with Dragonfly, researchers may be able to answer questions about how the building blocks of life initially formed on Earth.
Throughout its mission, the quadcopter will be able to sample and analyze the icy crust, the hydrocarbon sands and the atmosphere; take meteorological measurements; photograph the landscape; and record any seismic activity.
Sending a quadcopter to a distant moon is a daring idea, Barnes said, but he thinks the design will allow researchers to answer questions that would be difficult for a stationary probe or a rolling rover. Flying increases Dragonfly’s mobility, allowing the team to efficiently sample a diverse set of locations.
“Complex organic molecules like those that formed life on Earth 4 billion years ago abound at Titan,” Barnes said. “Dragonfly will determine just how far Titan’s organics have come on the path toward life. And, if some primitive form of molecular life has been able to form under Titan conditions, then we think that we can discover it by the end of our mission in 2037.”
Dragonfly is the fourth winner of the New Frontiers Program. Past winners include ’ exploration of Pluto, its moons and the Kuiper Belt; the investigation of Jupiter; and , which will sample an asteroid.
Visit Jason Barnes' profile page and the for more information.
Find on this page information about U of I's Saturn and Titan research.
Photos provided by Johns Hopkins University Applied Physics Laboratory.
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U of I’s Jason Barnes is part of Team Dragonfly.
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Learn more about Dragonfly at Johns Hopkins University Applied Physics Laboratory.
Posted 6/27/2019 8:17:00 PM
A project to launch a robotic rotorcraft lander to Saturn’s moon Titan, envisioned by a Bipasesores researcher, has been selected by NASA for launch. The mission, known as Dragonfly, involves 35 scientists from around the globe and is funded for up to $850 million. It is led by the Johns Hopkins Applied Physics Laboratory and beat 11 other teams to win NASA’s New Frontiers Program competition. Read more
Posted 6/14/2019 10:24:00 PM
Matthew Hedman from the Department of Physics and colleagues published in Science. His study presents remote-sensing observations of the main rings of Saturn taken during the final year of the Cassini spacecraft mission. These observations revealed a wide range of structures in the rings created by massive objects like moons and interactions among the ring particles themselves. They also found variations in the ring's colors that likely reflect differences in the surfaces of the ring particles. Read more