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Lunar Crater Radio Telescope: Illuminating the Cosmic Dark Ages

This illustration depicts a conceptual Lunar Crater Radio Telescope on the Moon’s far side.
This illustration depicts a conceptual Lunar Crater Radio Telescope on the Moon’s far side. The early-stage concept is being studied under grant funding from the NASA Innovative Advanced Concepts program but is not a NASA mission. Credits: Vladimir Vustyansky

The early-stage NASA concept could see robots hang wire mesh in a crater on the Moon’s far side, creating a radio telescope to help probe the dawn of the universe.

After years of development, the Lunar Crater Radio Telescope (LCRT) project has been awarded $500,000 to support additional work as it enters Phase II of NASA’s Innovative Advanced Concepts (NIAC) program. While not yet a NASA mission, the LCRT describes a mission concept that could transform humanity’s view of the cosmos.

The LCRT’s primary objective would be to measure the long-wavelength radio waves generated by the cosmic Dark Ages – a period that lasted for a few hundred million years after the Big Bang, but before the first stars blinked into existence. Cosmologists know little about this period, but think the answers to some of science’s biggest mysteries may be locked in the long-wavelength radio emissions generated by the gas that would have filled the universe during that time.

“While there were no stars, there was ample hydrogen during the universe’s Dark Ages – hydrogen that would eventually serve as the raw material for the first stars,” said Joseph Lazio, radio astronomer at NASA’s Jet Propulsion Laboratory in Southern California and a member of the LCRT team. “With a sufficiently large radio telescope off Earth, we could track the processes that would lead to the formation of the first stars, maybe even find clues to the nature of dark matter.”

Radio telescopes on Earth can’t probe this mysterious period because the long-wavelength radio waves from that time are reflected by a layer of ions and electrons at the top of our atmosphere, a region called the ionosphere. Random radio emissions from our noisy civilization can interfere with radio astronomy as well, drowning out the faintest signals.

But on the Moon’s far side, there’s no atmosphere to reflect these signals, and the Moon itself would block Earth’s radio chatter. The lunar far side could be prime real estate to carry out unprecedented studies of the early universe.

“Radio telescopes on Earth cannot see cosmic radio waves at about 33 feet [10 meters] or longer because of our ionosphere, so there’s a whole region of the universe that we simply cannot see,” said Saptarshi Bandyopadhyay, a robotics technologist at JPL and the lead researcher on the LCRT project. “But previous ideas of building a radio antenna on the Moon have been very resource intensive and complicated, so we were compelled to come up with something different.”

The conceptual radio telescope could be constructed from a wire mesh dish inside a crater.
The conceptual radio telescope could be constructed from a wire mesh dish inside a crater. In this illustration, the receiver can be seen suspended over the dish via a system of cables anchored at the crater’s rim. Credits: Vladimir Vustyansky

Building Telescopes With Robots

To be sensitive to long radio wavelengths, the LCRT would need to be huge. The idea is to create an antenna over half-a-mile (1 kilometer) wide in a crater over 2 miles (3 kilometers) wide. The biggest single-dish radio telescopes on Earth – like the 1,600-foot (500-meter) Five-hundred-meter Aperture Spherical Telescope (FAST) in China and the now-inoperative 1,000-foot-wide (305-meter-wide) Arecibo Observatory in Puerto Rico – were built inside natural bowl-like depressions in the landscape to provide a support structure.

This class of radio telescope uses thousands of reflecting panels suspended inside the depression to make the entire dish’s surface reflective to radio waves. The receiver then hangs via a system of cables at a focal point over the dish, anchored by towers at the dish’s perimeter, to measure the radio waves bouncing off the curved surface below. But despite its size and complexity, even FAST is not sensitive to radio wavelengths longer than about 14 feet (4.3 meters).

With his team of engineers, roboticists, and scientists at JPL, Bandyopadhyay condensed this class of radio telescope down to its most basic form. Their concept eliminates the need to transport prohibitively heavy material to the Moon and utilizes robots to automate the construction process. Instead of using thousands of reflective panels to focus incoming radio waves, the LCRT would be made of thin wire mesh in the center of the crater. One spacecraft would deliver the mesh, and a separate lander would deposit DuAxel rovers to build the dish over several days or weeks.

DuAxel, a robotic concept being developed at JPL, is composed of two single-axle rovers (called Axel) that can undock from each other but stay connected via a tether. One half would act as an anchor at the rim of the crater as the other rappels down to do the building.

“DuAxel solves many of the problems associated with suspending such a large antenna inside a lunar crater,” said Patrick Mcgarey, also a robotics technologist at JPL and a team member of the LCRT and DuAxel projects. “Individual Axel rovers can drive into the crater while tethered, connect to the wires, apply tension, and lift the wires to suspend the antenna.”

Illustration of DuAxel rovers on Moon
The Moon’s surface is covered in craters, and one of the natural like depressions could provide a support structure for a radio telescope dish. As shown in this illustration, DuAxel rovers could anchor the wire mesh from the crater’s rim. Credits: Vladimir Vustyansky

Identifying Challenges

For the team to take the project to the next level, they’ll use NIAC Phase II funding to refine the capabilities of the telescope and the various mission approaches while identifying the challenges along the way.

One of the team’s biggest challenges during this phase is the design of the wire mesh. To maintain its parabolic shape and precise spacing between the wires, the mesh must be both strong and flexible, yet lightweight enough to be transported. The mesh must also be able to withstand the wild temperature changes on the Moon’s surface – from as low as minus 280 degrees Fahrenheit (minus 173 degrees Celsius) to as high as 260 degrees Fahrenheit (127 degrees Celsius) – without warping or failing.

Another challenge is to identify whether the DuAxel rovers should be fully automated or involve a human operator in the decision-making process. Might the construction DuAxels also be complemented by other construction techniques? Firing harpoons into the lunar surface, for example, may better anchor the LCRT’s mesh, requiring fewer robots.

Also, while the lunar far side is “radio quiet” for now, that may change in the future. China’s space agency currently has a mission exploring the lunar far side, after all, and further development of the lunar surface could impact possible radio astronomy projects.

For the next two years, the LCRT team will work to identify other challenges and questions as well. Should they be successful, they may be selected for further development, an iterative process that inspires Bandyopadhyay.

“The development of this concept could produce some significant breakthroughs along the way, particularly for deployment technologies and the use of robots to build gigantic structures off Earth,” he said. “I’m proud to be working with this diverse team of experts who inspire the world to think of big ideas that can make groundbreaking discoveries about the universe we live in.”

NIAC is funded by NASA’s Space Technology Mission Directorate, which is responsible for developing the new cross-cutting technologies and capabilities needed by the agency.