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NASA’s Lunar Flashlight Ready to Search for the Moon’s Water Ice

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Earlier this year, NASA’s Lunar Flashlight mission underwent tests to prepare it for launch in November 2022. The solar-powered small satellite is shown here with its for solar arrays extended in a Georgia Tech clean room.
Earlier this year, NASA’s Lunar Flashlight mission underwent tests to prepare it for launch in November 2022. The solar-powered small satellite is shown here with its solar arrays extended in a Georgia Tech clean room.
Credits: NASA/JPL-Caltech

Editor’s note: The text has been updated to reflect the mission’s new launch date.

Set for a November launch, the small satellite mission will use lasers to search for water ice inside the darkest craters at the Moon’s South Pole.

The Moon’s poles offer a tantalizing opportunity for human explorers: There may be reservoirs of water ice there that could be purified as drinking water, converted into breathable oxygen, and used as fuel by astronauts. These reservoirs are inside permanently shadowed craters – regions where the Sun never rises above crater rims.

It’s known that water ice exists below the lunar regolith (broken rock and dust), but scientists don’t yet understand whether surface ice frost covers the floors inside these cold craters. To find out, NASA is sending Lunar Flashlight, a small satellite (or SmallSat) no larger than a briefcase. Swooping low over the lunar South Pole, it will use lasers to shed light on these dark craters – much like a prospector looking for hidden treasure by shining a flashlight into a cave. The mission will launch aboard a SpaceX Falcon 9 rocket in November.

“This launch will put the satellite on a trajectory that will take about three months to reach its science orbit,” said John Baker, the mission’s project manager at NASA’s Jet Propulsion Laboratory in Southern California. “Then Lunar Flashlight will try to find water ice on the surface of the Moon in places that nobody else has been able to look.”

Before being integrated into its dispenser, which will eject the small satellite from the SpaceX Falcon 9 rocket after launch, Lunar Flashlight was fueled with “green” propellant at NASA’s Marshall Space Flight Center in Huntsville, Alabama.
Before being integrated into its dispenser, which will eject the small satellite from the SpaceX Falcon 9 rocket after launch, Lunar Flashlight was fueled with “green” propellant at NASA’s Marshall Space Flight Center in Huntsville, Alabama, earlier this month.
Credits: NASA

Fuel-Efficient Orbits

After launch, mission navigators will guide the spacecraft way past the Moon. It will then be slowly pulled back by gravity from Earth and the Sun before it settles into a wide, looping, science-gathering orbit. This near-rectilinear halo orbit will take it 42,000 miles (70,000 kilometers) from the Moon at its most distant point and, at its closest approach, the satellite will graze the surface of the Moon, coming within 9 miles (15 kilometers) above the lunar South Pole.

SmallSats carry a limited amount of propellent, so fuel-intensive orbits aren’t possible. A near-rectilinear halo orbit requires far less fuel than traditional orbits, and Lunar Flashlight will be only the second NASA mission to use this type of trajectory. The first is NASA’s Cislunar Autonomous Positioning System Technology Operations and Navigation Experiment (CAPSTONE) mission, which will arrive at its orbit on Nov. 13, making its closest pass over the Moon’s North Pole.

“The reason for this orbit is to be able to come in close enough that Lunar Flashlight can shine its lasers and get a good return from the surface, but to also have a stable orbit that consumes little fuel,” said Barbara Cohen, Lunar Flashlight principal investigator at NASA’s Goddard Space Flight Center in Greenbelt, Maryland.

Shown here in early October, Lunar Flashlight underwent fueling activities and final testing in a Marshall Space Flight Center clean room before being packed up in preparation for shipment to Cape Canaveral Space Force Station, Florida, in early November.
Shown here in early October, Lunar Flashlight underwent fueling activities and final testing in a Marshall Space Flight Center clean room before being packed up in preparation for shipment to Cape Canaveral Space Force Station, Florida, in early November.
Credits: NASA

As a technology demonstration, Lunar Flashlight will be the first interplanetary spacecraft to use a new kind of “green” propellant that is safer to transport and store than the commonly used in-space propellants such as hydrazine. This new propellant, developed by the Air Force Research Laboratory and tested on a previous NASA technology demonstration mission, burns via a catalyst, rather than requiring a separate oxidizer. That is why it’s called a monopropellant. The satellite’s propulsion system was developed and built by NASA’s Marshall Space Flight Center in Huntsville, Alabama, with integration support from Georgia Tech Research Institute in Atlanta.

Lunar Flashlight will also be the first mission to use a four-laser reflectometer to look for water ice on the Moon. The reflectometer works by using near-infrared wavelengths that are readily absorbed by water to identify ice on the surface. Should the lasers hit bare rock, their light will reflect back to the spacecraft, signaling a lack of ice. But if the light is absorbed, it would mean these dark pockets do indeed contain ice. The greater the absorption, the more ice may be at the surface. 

This illustration shows NASA’s Lunar Flashlight over the Moon. The SmallSat mission will have a very elongated orbit, taking it within 9 miles (15 kilometers) above the lunar South Pole to search for water ice in the Moon’s darkest craters.
This illustration shows NASA’s Lunar Flashlight over the Moon. The SmallSat mission will have a very elongated orbit, taking it within 9 miles (15 kilometers) above the lunar South Pole to search for water ice in the Moon’s darkest craters.
Credits: NASA

Lunar Water Cycle

It’s thought that molecules of water come from comet and asteroid material impacting the lunar surface, and from solar wind interactions with the lunar regolith. Over time, the molecules may have accumulated as a layer of ice inside “cold traps”.

“We are going to make definitive surface water ice measurements in permanently shadowed regions for the first time,” said Cohen. “We will be able to correlate Lunar Flashlight’s observations with other lunar missions to understand how extensive that water is and whether it could be used as a resource by future explorers.”

Cohen and her science team hope that the data Lunar Flashlight gathers can be used to understand how volatile molecules, like water, cycle from location to location and where they may accumulate, forming a layer of ice in these cold traps.

“This is an exciting time for lunar exploration. The launch of Lunar Flashlight, along with the many small satellite missions aboard Artemis I, may form the foundations for science discoveries as well as support future missions to the Moon’s surface,” said Roger Hunter, Small Spacecraft Technology program manager at NASA’s Ames Research Center in California’s Silicon Valley.

More About the Mission

In October, Lunar Flashlight was fueled at NASA’s Marshall Space Flight Center in Huntsville, Alabama, and is scheduled to launch aboard a SpaceX Falcon 9 rocket from Cape Canaveral Space Force Station in Florida no earlier than Nov. 22 with the Japanese Hakuto-R lander and United Arab Emirate’s Rashid 1 rover. The mission worked with Maverick Space Systems to provide launch integration services.

NASA’s Small Business Innovation Research program funded component development from small businesses including Plasma Processes Inc. (Rubicon) for thruster development, Flight Works for pump development, and Beehive Industries (formerly Volunteer Aerospace) for specific 3D printed components. The Air Force Research Laboratory also contributed financially to the development of the Lunar Flashlight propulsion system.

Lunar Flashlight will be operated by Georgia Tech, including graduate and undergraduate students. The mission is funded by the Small Spacecraft Technology program within NASA’s Space Technology Mission Directorate.

Ian J. O’Neill
Jet Propulsion Laboratory, Pasadena, Calif.
818-354-2649
ian.j.oneill@jpl.nasa.gov

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