NASA CLPS Moon landing missions

What is NASA’s CLPS program?

NASA is funding a fleet of commercial robotic Moon missions to support the agency's Artemis program.

With its $2.6 billion Commercial Lunar Payloads Services (CLPS) initiative, NASA has been competitively funding commercial companies to build spacecraft that autonomously land on the Moon, and carry with them the agency’s science and technology payloads to geologically diverse places.

Render of Firefly's Blue Ghost lander
Render of Firefly's Blue Ghost lander A render of Firefly’s Blue Ghost lander descending on the Moon.Image: Firefly

In progress CLPS Moon missions

  • Intuitive Machines' Nova-C Odysseus spacecraft landed on the Moon on Feb. 22, 2024 on the IM-1 mission.

    Upcoming CLPS Moon missions

    Because of the dynamic nature of NASA's CLPS program, schedules and timelines change frequently.

      2024

      • Intuitive Machines IM-2 will deliver the PRIME-1 drill to the lunar south pole.
      • Astrobotic will deliver NASA's VIPER mission to the lunar south pole.
      • Firefly will deliver its Blue Ghost lander to Mare Crisium, a dark patch located at the Moon's upper-right as seen from Earth. The mission also includes Lunar PlanetVac, a technology funded in part by Planetary Society members and donors.
      • Intuitive Machines will deliver a mission to Reiner Gamma, a magnetic anomaly located on the lunar near side.

      2025

      • Draper will deliver its SERIES-2 lander to Schrödinger Basin on the Moon's far side.

      2026

      • Firefly will deliver two payloads to the lunar far side, along with a relay satellite built in collaboration with the European Space Agency.

      Past CLPS Moon missions

      • Astrobotic's Peregrine Mission launched on Jan. 8, 2024 for the first flight of United Launch Alliance's Vulcan rocket. The goal was to deliver the Peregrine lander to Sinus Viscositatis, located at the northeast border of the Moon's Ocean of Storms. It was the first CLPS mission. Peregrine suffered a propellant leak and reentered Earth's atmosphere on Jan. 18, 2024.

      Unlike traditional missions, these CLPS missions are fully built, operated and managed by their companies, with minimal oversight from NASA. The agency only dictates preferences for the landing sites, and the instruments it wants onboard.

      These missions also have non-NASA payloads from across the globe — something the agency encourages to spur a commercial lunar ecosystem.

      Intuitive Machines’ first CLPS mission

      For its first CLPS mission, Intuitive Machines will carry six NASA payloads to Oceanus Procellarum, a dark lava plain on the Moon. Most notably, the lander will have stereo cameras to record how its engine plumes impact the surface. This will help us quantify how rocket plumes interact with and kick off Moondust so that we can protect future surface spacecraft and habitats.

      Intuitive Machines’ second CLPS mission

      On its second Moon mission, Intuitive Machines will deliver NASA’s PRIME-1 drill and a mass spectrometer to the Moon’s south pole. The lander will drill up to 1 meter below the surface and analyze the soil for water ice, a first such study. The lander will also deploy a rover on the surface to test Nokia’s 4G/LTE network on the Moon, another first. Further, there’s the company’s own NASA-supported hopper onboard called Micro-Nova, which will jump around the Moon with a camera to take high-resolution images of the surface under its flight path.

      Intuitive Machines’ lander on the Moon
      Intuitive Machines’ lander on the Moon Illustration of Intuitive Machines’ lander on the Moon with NASA’s PRIME-1 drill attached.Image: Intuitive Machines

      Masten’s first CLPS mission

      Masten was aquired by Astrobotic in 2022. The status of their CLPS award is unclear.

      Masten Space’s lander will touchdown on the Moon’s south pole. It will have at least eight instruments onboard, chiefly to detect water ice and other volatiles such as methane and carbon dioxide to help us understand the Moon’s resource potential. The lander will also deploy Astrobotic’s shoebox-sized autonomous rover called MoonRanger. NASA is making use of its capabilities by putting a neutron spectrometer onboard to detect signs of water ice below the surface.

      VIPER rover delivery by Astrobotic

      Astrobotic will deliver NASA’s VIPER rover on the Moon’s south pole. The rover will explore areas in and around permanently shadowed regions for over 100 days, and use its drill and three instruments to unravel the nature of the Moon’s water ice deposits, assess their resource potential, and determine how accessible they are. This will help us plan future human missions to the Moon’s poles and eventually build sustainable habitats.

      Firefly’s first CLPS mission

      Firefly’s first Moon lander will descend in the lava plains of Mare Crisium, carrying several NASA instruments to study the lunar environment. One of the lander’s legs will feature PlanetVac, a low-cost soil sampling technology partially funded by The Planetary Society to enable future sample return missions from the Moon, Mars and other planetary bodies. This mission will also be NASA’s first attempt to get a GPS lock from the Moon.

      VIPER rover and Griffin lander
      VIPER rover and Griffin lander An artist’s impression showing NASA’s VIPER rover moving down a ramp of Astrobotic’s Griffin lander.Image: Astrobotic

      Intuitive Machines’ third CLPS mission

      Intuitive Machines’ third Moon landing will be in the swirl of Reiner Gamma in 2024. Reiner Gamma has a weak local magnetic field, possibly a remnant from the time the Moon had a global magnetic field. The mission’s primary payload suite Lunar Vertex is a collection of spectrometers and magnetometers on the lander and a rover to study the swirl’s composition, and map the strength and direction of magnetic fields on the surface. This will help us better understand the effects of solar wind and bombarding micrometeorites on planetary bodies across the solar system, and shape our understanding of the Moon’s magnetic evolution. The lander will also deploy four small CADRE rovers from NASA, which will autonomously navigate the landed region and collectively better map it than a single rover can.

      Draper’s farside CLPS mission

      For its first CLPS mission in 2025, Draper will land a spacecraft on the Moon’s farside, a feat only achieved by China’s Chang’e 4 mission so far. The landing region chosen by NASA for the mission is no less impressive — the 312 kilometers wide Schrödinger crater, the most pristine impact feature of its kind. The lander will carry 95 kilograms of NASA’s scientific instruments, which includes two highly sensitive seismometers, a drill, a probe, and a magnetic sounder, all to help us better understand the Moon’s internal structure and composition, and how our cosmic neighbor evolved.

      Expanding scope

      With the mission selection to Reiner Gamma and Schrödinger, NASA began an enhanced science phase of its CLPS program. The next mission in this phase will visit the volcanic domes of Gruithuisen in 2026, and another south polar mission around the same time. NASA says future CLPS missions could also deliver more advanced rovers and technology demonstrations, and even infrastructure required by Artemis human landing missions.

      A new commercial model for planetary missions

      Landing on the Moon is hard. Only three countries have accomplished this feat so far — the U.S., the Soviet Union and China. The fact that NASA is entrusting commercial companies with the agency’s crucial lunar scientific and technological objectives, many of which will directly affect their Artemis plans, shows their growing confidence in building a commercial ecosystem around lunar exploration.

      CLPS also inverts the tradition of having only custom-built planetary missions to meet specific scientific goals. If enough of the CLPS missions stick the landing, it would open up frequent and periodic access to the Moon’s surface for diverse scientific investigations in ways never possible before for any planetary body.

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      Acknowledgments: This page was initially authored by Jatan Mehta.