Jenn Gustetic, NASA's Small Business Innovation Research Program executive, talks with Rob Mueller, senior technologist and co-founder of Kennedy Space Center's Swamp Works. Gustetic met team members and viewed many of the pioneering technologies and innovations in development at Kennedy. Swamp Works is a hands-on, lean development environment for innovation following the philosophies pioneered in Kelly Johnson's Skunk Works and Werner von Braun's development shops. The Swamp Works establishes rapid, innovative and cost-effective exploration mission solutions through a highly collaborative, "no walls" approach, leveraging partnerships across NASA, industry and academia.

In the Swamp Works laboratory at NASA's Kennedy Space Center in Florida, student interns such as Maddy Olson are joining agency scientists, contributing in the area of Exploration Research and Technology. Olson is majoring in mechanical engineering at the University of North Dakota. The agency attracts its future workforce through the NASA Internship, Fellowships and Scholarships, or NIFS, Program.

In the Swamp Works laboratory at NASA's Kennedy Space Center in Florida, student interns such as Kevin Murphy are joining agency scientists, contributing in the area of Exploration Research and Technology. Murphy is majoring in mechanical engineering at the University of Illinois at Urbana-Champaign. The agency attracts its future workforce through the NASA Internship, Fellowships and Scholarships, or NIFS, Program.

Thomas Zurbuchen, in plaid shirt, NASA's associate administrator for the Science Mission Directorate, listens to a presentation at the Swamp Works facility at NASA's Kennedy Space Center in Florida.

Thomas Zurbuchen, in plaid shirt, NASA's associate administrator for the Science Mission Directorate, listens to a presentation at the Swamp Works facility at NASA's Kennedy Space Center in Florida.

Thomas Zurbuchen, in plaid shirt, NASA's associate administrator for the Science Mission Directorate, listens to a presentation at the Swamp Works facility at NASA's Kennedy Space Center in Florida. In the foreground is a prototype robotic exploration vehicle.

Thomas Zurbuchen, in plaid shirt, NASA's associate administrator for the Science Mission Directorate, listens to a presentation at the Swamp Works facility at NASA's Kennedy Space Center in Florida. In the foreground is a prototype robotic exploration vehicle.

In the Swamp Works laboratory at NASA's Kennedy Space Center in Florida, student interns such as Andrew Thoesen are joining agency scientists, contributing in the area of Exploration Research and Technology. Thoesen is studying mechanical engineering at Arizona State University in Tempe, Arizona. The agency attracts its future workforce through the NASA Internship, Fellowships and Scholarships, or NIFS, Program

In the Swamp Works laboratory at NASA's Kennedy Space Center in Florida, student interns, from the left, Jeremiah House, Thomas Muller and Austin Langdon are joining agency scientists, contributing in the area of Exploration Research and Technology. House is studying computer/electrical engineering at John Brown University in Siloam Springs, Arkansas. Muller is pursuing a degree in computer engineering and control systems and Florida Tech. Langdon is an electrical engineering major at the University of Kentucky. The agency attracts its future workforce through the NASA Internship, Fellowships and Scholarships, or NIFS, Program.

In the Swamp Works laboratory at NASA's Kennedy Space Center in Florida, student interns such as Thomas Muller, left, and Austin Langdon are joining agency scientists, contributing in the area of Exploration Research and Technology. Muller is pursuing a degree in computer engineering and control systems and Florida Tech. Langdon is an electrical engineering major at the University of Kentucky. The agency attracts its future workforce through the NASA Internship, Fellowships and Scholarships, or NIFS, Program.

NASA’s RASSOR (Regolith Advanced Surface Systems Operations Robot) conducts excavation testing of simulated regolith, or lunar dust found on the Moon’s surface, inside of the Granular Mechanics and Regolith Operations Lab at the agency’s Kennedy Space Center in Florida on Tuesday, May 27, 2025. RASSOR is designed to work in low-gravity situations, using counter rotating bucket drums on each arm to collect and dump regolith for the extraction of hydrogen, oxygen, or water, resources critical for sustaining a habitable presence.

NASA’s RASSOR (Regolith Advanced Surface Systems Operations Robot) conducts excavation testing of simulated regolith, or lunar dust found on the Moon’s surface, inside of the Granular Mechanics and Regolith Operations Lab at the agency’s Kennedy Space Center in Florida on Tuesday, May 27, 2025. RASSOR is designed to work in low-gravity situations, using counter rotating bucket drums on each arm to collect and dump regolith for the extraction of hydrogen, oxygen, or water, resources critical for sustaining a habitable presence.

NASA’s RASSOR (Regolith Advanced Surface Systems Operations Robot) conducts excavation testing of simulated regolith, or lunar dust found on the Moon’s surface, inside of the Granular Mechanics and Regolith Operations Lab at the agency’s Kennedy Space Center in Florida on Tuesday, May 27, 2025. RASSOR is designed to work in low-gravity situations, using counter rotating bucket drums on each arm to collect and dump regolith for the extraction of hydrogen, oxygen, or water, resources critical for sustaining a habitable presence.

NASA’s RASSOR (Regolith Advanced Surface Systems Operations Robot) conducts excavation testing of simulated regolith, or lunar dust found on the Moon’s surface, inside of the Granular Mechanics and Regolith Operations Lab at the agency’s Kennedy Space Center in Florida on Tuesday, May 27, 2025. RASSOR is designed to work in low-gravity situations, using counter rotating bucket drums on each arm to collect and dump regolith for the extraction of hydrogen, oxygen, or water, resources critical for sustaining a habitable presence.

NASA’s RASSOR (Regolith Advanced Surface Systems Operations Robot) conducts excavation testing of simulated regolith, or lunar dust found on the Moon’s surface, inside of the Granular Mechanics and Regolith Operations Lab at the agency’s Kennedy Space Center in Florida on Tuesday, May 27, 2025. RASSOR is designed to work in low-gravity situations, using counter rotating bucket drums on each arm to collect and dump regolith for the extraction of hydrogen, oxygen, or water, resources critical for sustaining a habitable presence.

NASA’s RASSOR (Regolith Advanced Surface Systems Operations Robot) conducts excavation testing of simulated regolith, or lunar dust found on the Moon’s surface, inside of the Granular Mechanics and Regolith Operations Lab at the agency’s Kennedy Space Center in Florida on Tuesday, May 27, 2025. RASSOR is designed to work in low-gravity situations, using counter rotating bucket drums on each arm to collect and dump regolith for the extraction of hydrogen, oxygen, or water, resources critical for sustaining a habitable presence.

NASA’s RASSOR (Regolith Advanced Surface Systems Operations Robot) conducts excavation testing of simulated regolith, or lunar dust found on the Moon’s surface, inside of the Granular Mechanics and Regolith Operations Lab at the agency’s Kennedy Space Center in Florida on Tuesday, May 27, 2025. RASSOR is designed to work in low-gravity situations, using counter rotating bucket drums on each arm to collect and dump regolith for the extraction of hydrogen, oxygen, or water, resources critical for sustaining a habitable presence.

Ben Burdess, mechanical engineer, observes NASA’s RASSOR (Regolith Advanced Surface Systems Operations Robot) excavation testing of simulated regolith, or lunar dust found on the Moon’s surface, inside of the Granular Mechanics and Regolith Operations Lab at the agency’s Kennedy Space Center in Florida on Tuesday, May 27, 2025. RASSOR is designed to work in low-gravity situations, using counter rotating bucket drums on each arm to collect and dump regolith for the extraction of hydrogen, oxygen, or water, resources critical for sustaining a habitable presence.

Steve Jurczyk, Acting Administrator of STMD, Visits Swamp Works at NASA's Kennedy Space Center

Steve Jurczyk, Acting Administrator of STMD, Visits Swamp Works at NASA's Kennedy Space Center

Steve Jurczyk, Acting Administrator of STMD, Visits Swamp Works at NASA's Kennedy Space Center

Work of the Wind

Daphnis At Work

Students try on a sleep restraint like the ones used by astronauts. This demonstration is part of a program called 'Living and Working in Space,' that is presented by NASA's Stennis Space Center in the StenniSphere Auditorium and in the community.

Robotics Software Engineer II Chris Rampolla runs benchtop verifications on Astrobotic’s CubeRover – a lightweight, modular planetary rover – before delivery to Swamp Works at NASA’s Kennedy Space Center in Florida on June 30, 2022. Astrobotic – a Pittsburgh-based space robotics company – is planning to use Swamp Work’s Granular Mechanics and Regolith Operations Laboratory’s regolith bin, which holds approximately 120 tons of lunar regolith simulant, to depict how the company’s CubeRover would perform on the Moon. NASA’s Small Business Innovation Research program provided the funding for initial development, and a $2 million Tipping Point award from the agency has provided additional funding for continued development into a more mature rover.

Nathan Gelino, a NASA research engineer at Kennedy Space Center in Florida, is working on a Zero Launch Mass 3-D printer in the center's Swamp Works that can be used for construction projects on the Moon and Mars, and even for troops in remote locations here on Earth. Zero launch mass refers to the fact that the printer uses pellets made from simulated lunar regolith, or dirt, and polymers to prove that space explorers can use resources at their destination instead of taking everything with them, saving them launch mass and money. Gelino and his team are working with Marshall Space Flight Center in Huntsville, Alabama, and the U.S. Army Corps of Engineers to develop a system that can 3-D print barracks in remote locations on Earth, using the resources they have where they are.

Research engineers at NASA's Kennedy Space Center in Florida are working on a Zero Launch Mass 3-D printer at the center's Swamp Works. The printer can be used for construction projects on the Moon and Mars, and even for troops in remote locations on Earth. Zero launch mass refers to the fact that the printer uses pellets made from simulated lunar regolith, or dirt, and polymers to prove that space explorers can use resources at their destination instead of taking everything with them, saving them launch mass and money. The group is working with Marshall Space Flight Center in Huntsville, Alabama, and the U.S. Army Corps of Engineers to develop a system that can 3-D print barracks in remote locations on Earth, using the resources they have where they are.

Nathan Gelino, a NASA research engineer at Kennedy Space Center in Florida displays a 3-D printed cylinder used for compression testing. Engineers at the center’s Swamp Works measured how much force it takes to break the structure before moving on to 3-D printing with a simulated lunar regolith, or dirt, and polymers. Next, Gelino and his group are working on a Zero Launch Mass 3-D printer that can be used for construction projects on the Moon and Mars, even for troops in remote locations here on Earth. Zero launch mass refers to the fact that the printer uses these pellets to prove that space explorers can use resources at their destination instead of taking everything with them, saving them launch mass and money. Gelino and his team are working with Marshall Space Flight Center in Huntsville, Alabama, and the U.S. Army Corps of Engineers to develop a system that can 3-D print barracks in remote locations on Earth, using the resources they have where they are.

Research engineers at NASA's Kennedy Space Center in Florida are working on a Zero Launch Mass 3-D printer at the center's Swamp Works. The printer can be used for construction projects on the Moon and Mars, and even for troops in remote locations on Earth. Zero launch mass refers to the fact that the printer uses pellets made from simulated lunar regolith, or dirt, and polymers to prove that space explorers can use resources at their destination instead of taking everything with them, saving them launch mass and money. The group is working with Marshall Space Flight Center in Huntsville, Alabama, and the U.S. Army Corps of Engineers to develop a system that can 3-D print barracks in remote locations on Earth, using the resources they have where they are.

Nathan Gelino, a NASA research engineer at Kennedy Space Center in Florida displays a 3-D printed cylinder used for compression testing. Engineers at the center’s Swamp Works measured how much force it takes to break the structure before moving on to 3-D printing with a simulated lunar regolith, or dirt, and polymers. Next, Gelino and his group are working on a Zero Launch Mass 3-D printer that can be used for construction projects on the Moon and Mars, even for troops in remote locations here on Earth. Zero launch mass refers to the fact that the printer uses these pellets to prove that space explorers can use resources at their destination instead of taking everything with them, saving them launch mass and money. Gelino and his team are working with Marshall Space Flight Center in Huntsville, Alabama, and the U.S. Army Corps of Engineers to develop a system that can 3-D print barracks in remote locations on Earth, using the resources they have where they are.

Researchers at NASA's Kennedy Space Center in Florida are developing a Zero Launch Mass 3-D printer at the center's Swamp Works. The printer can be used for construction projects on the Moon and Mars. Zero launch mass refers to the fact that the printer uses pellets made from simulated lunar regolith, or dirt, and polymers. This will prove that space explorers can use resources at their destination instead of taking everything with them, saving them launch mass and money. The Kennedy team is working with Marshall Space Flight Center in Huntsville, Alabama, and the U.S. Army Corps of Engineers to develop a system that can 3-D print barracks in remote locations on Earth, using the resources they have where they are.

A Zero Launch Mass 3-D printer is being developed by researchers in Swamp Works at NASA's Kennedy Space Center in Florida. The printer can be used for construction projects on the Moon and Mars. Zero launch mass refers to the fact that the printer uses pellets made from simulated lunar regolith, or dirt, and polymers. This will prove that space explorers can use resources at their destination instead of taking everything with them, saving them launch mass and money. The Kennedy team is working with Marshall Space Flight Center in Huntsville, Alabama, and the U.S. Army Corps of Engineers to develop a system that can 3-D print barracks in remote locations on Earth, using the resources they have where they are.

A Zero Launch Mass 3-D printer is being tested at the Swamp Works at NASA's Kennedy Space Center in Florida. The printer can be used for construction projects on the Moon and Mars. Zero launch mass refers to the fact that the printer uses pellets made from simulated lunar regolith, or dirt, and polymers. This will prove that space explorers can use resources at their destination instead of taking everything with them, saving them launch mass and money. The Kennedy team is working with Marshall Space Flight Center in Huntsville, Alabama, and the U.S. Army Corps of Engineers to develop a system that can 3-D print barracks in remote locations on Earth, using the resources they have where they are.

Researchers demonstrate a Zero Launch Mass 3-D printer in Swamp Works at NASA's Kennedy Space Center in Florida. The printer can be used for construction projects on the Moon and Mars. Zero launch mass refers to the fact that the printer uses pellets made from simulated lunar regolith, or dirt, and polymers. This will prove that space explorers can use resources at their destination instead of taking everything with them, saving them launch mass and money. The Kennedy team is working with Marshall Space Flight Center in Huntsville, Alabama, and the U.S. Army Corps of Engineers to develop a system that can 3-D print barracks in remote locations on Earth, using the resources they have where they are.

Senior Software Engineer Taylor Whitaker reports the results of a drawbar pull run to Astrobotic staff outside of the Granular Mechanics and Regolith Operations (GMRO) Laboratory’s regolith pit at NASA Kennedy Space Center’s Swamp Works facility on June 30, 2022. Astrobotic – a Pittsburgh-based space robotics company – is using the GMRO lab’s regolith bin, which holds approximately 120 tons of lunar regolith simulant, to depict how the company’s CubeRover would perform on the Moon. NASA’s Small Business Innovation Research program provided the funding for initial development, and a $2 million Tipping Point award from the agency has provided additional funding for continued development into a more mature rover.

In their Swamp Works laboratory at NASA's Kennedy Space Center, Dr. Carlos Calle and Jay Phillips are testing an electrostatic precipitator using dust that closely approximates the make-up of that on Mars. They upgraded their electrostatic precipitator to fully simulate Martian atmosphere by designing and constructing a dust aerosolization pre-chamber. The agency's Journey to Mars requires cutting-edge technologies to solve the problems explorers will face on the Red Planet. Scientists are developing some of the needed solutions by adapting a device to remove the ever-present dust from valuable elements in the Martian atmosphere. Those commodities include oxygen, water and methane.

Astrobotic’s mass-offloaded CubeRover – a lightweight, modular planetary rover – undergoes mobility testing inside the Granular Mechanics and Regolith Operations (GMRO) Laboratory’s regolith pit at NASA Kennedy Space Center’s Swamp Works facility on June 30, 2022. Astrobotic – a Pittsburgh-based space robotics company – is using the GMRO lab’s regolith bin, which holds approximately 120 tons of lunar regolith simulant, to depict how the company’s CubeRover would perform on the Moon. NASA’s Small Business Innovation Research program provided the funding for initial development, and a $2 million Tipping Point award from the agency has provided additional funding for continued development into a more mature rover.

Astrobotic’s CubeRover – a lightweight, modular planetary rover – undergoes mobility testing inside the Granular Mechanics and Regolith Operations (GMRO) Laboratory’s regolith pit at NASA Kennedy Space Center’s Swamp Works facility on June 30, 2022. Astrobotic – a Pittsburgh-based space robotics company – is using the GMRO lab’s regolith bin, which holds approximately 120 tons of lunar regolith simulant, to depict how the company’s CubeRover would perform on the Moon. NASA’s Small Business Innovation Research program provided the funding for initial development, and a $2 million Tipping Point award from the agency has provided additional funding for continued development into a more mature rover.

Jose Nunez of NASA Kennedy Space Center’s Exploration Research and Technology Programs talks to students in the My Brother’s Keeper program outside the Florida spaceport’s Swamp Works Lab. Kennedy is one of six NASA centers that participated in My Brother’s Keeper National Lab Week. The event is a nationwide effort to bring youth from underrepresented communities into federal labs and centers for hands-on activities, tours and inspirational speakers. Sixty students from the nearby cities of Orlando and Sanford visited Kennedy, where they toured the Vehicle Assembly Building, the Space Station Processing Facility and the center’s innovative Swamp Works Labs. The students also had a chance to meet and ask questions of a panel of subject matter experts from across Kennedy.

Pellets made from simulated lunar regolith, or dirt, and polymers are being used to test a Zero Launch Mass 3-D printer in the Swamp Works at NASA's Kennedy Space Center in Florida. The printer can be used for construction projects on the Moon and Mars, and even for troops in remote locations on Earth. Zero launch mass refers to the fact that the printer uses these pellets to prove that space explorers can use resources at their destination instead of taking everything with them, saving them launch mass and money. The group is working with Marshall Space Flight Center in Huntsville, Alabama, and the U.S. Army Corps of Engineers to develop a system that can 3-D print barracks in remote locations on Earth, using the resources they have where they are.

A Zero Launch Mass 3-D printer is being tested at the Swamp Works at NASA's Kennedy Space Center in Florida. The printer can be used for construction projects on the Moon and Mars, and even for troops in remote locations on Earth. Zero launch mass refers to the fact that the printer uses pellets made from simulated lunar regolith, or dirt, and polymers to prove that space explorers can use resources at their destination instead of taking everything with them, saving them launch mass and money. The group is working with Marshall Space Flight Center in Huntsville, Alabama, and the U.S. Army Corps of Engineers to develop a system that can 3-D print barracks in remote locations on Earth, using the resources they have where they are.

A Zero Launch Mass 3-D printer is being tested at the Swamp Works at NASA's Kennedy Space Center in Florida. The printer can be used for construction projects on the Moon and Mars, and even for troops in remote locations on Earth. Zero launch mass refers to the fact that the printer uses pellets made from simulated lunar regolith, or dirt, and polymers to prove that space explorers can use resources at their destination instead of taking everything with them, saving them launch mass and money. The group is working with Marshall Space Flight Center in Huntsville, Alabama, and the U.S. Army Corps of Engineers to develop a system that can 3-D print barracks in remote locations on Earth, using the resources they have where they are.

Senior Software Engineer Taylor Whitaker stages Astrobotic’s mass-offloaded CubeRover – a lightweight, modular planetary rover – for a drawbar pull test inside the Granular Mechanics and Regolith Operations (GMRO) Laboratory’s regolith pit at NASA Kennedy Space Center’s Swamp Works facility on June 30, 2022. Astrobotic – a Pittsburgh-based space robotics company – is using the GMRO lab’s regolith bin, which holds approximately 120 tons of lunar regolith simulant, to depict how the company’s CubeRover would perform on the Moon. NASA’s Small Business Innovation Research program provided the funding for initial development, and a $2 million Tipping Point award from the agency has provided additional funding for continued development into a more mature rover.

A mass-offloaded version of Astrobotic’s CubeRover – a lightweight, modular planetary rover – is used to simulate mobility in low lunar gravity inside the Granular Mechanics and Regolith Operations (GMRO) Laboratory’s regolith pit at NASA Kennedy Space Center’s Swamp Works facility on June 30, 2022. Astrobotic – a Pittsburgh-based space robotics company – is using the GMRO lab’s regolith bin, which holds approximately 120 tons of lunar regolith simulant, to depict how the company’s CubeRover would perform on the Moon. NASA’s Small Business Innovation Research program provided the funding for initial development, and a $2 million Tipping Point award from the agency has provided additional funding for continued development into a more mature rover.

Astrobotic’s CubeRover – a lightweight, modular planetary rover – is photographed in its benchtop testing configuration at NASA’s Kennedy Space Center in Florida on June 30, 2022. Astrobotic – a Pittsburgh-based space robotics company – is planning to use the spaceport’s Swamp Works facility and Granular Mechanics and Regolith Operations Laboratory to conduct mobility testing of their rover. The laboratory’s regolith bin, which holds approximately 120 tons of lunar regolith simulant, will help depict how the company’s CubeRover would perform on the Moon. NASA’s Small Business Innovation Research program provided the funding for initial development, and a $2 million Tipping Point award from the agency has provided additional funding for continued development into a more mature rover.

Senior Software Engineer Taylor Whitaker (right) and Software Engineering intern Ashten Akemoto create a mobility routine for Astrobotic’s CubeRover – a lightweight, modular planetary rover – using the company’s ground software at NASA’s Kennedy Space Center in Florida on June 30, 2022. Astrobotic – a Pittsburgh-based space robotics company – is using the spaceport’s Swamp Works facility and the Granular Mechanics and Regolith Operations Laboratory to conduct mobility testing of their rover. The laboratory’s regolith bin, which holds approximately 120 tons of lunar regolith simulant, will help depict how the company’s CubeRover would perform on the Moon. NASA’s Small Business Innovation Research program provided the funding for initial development, and a $2 million Tipping Point award from the agency has provided additional funding for continued development into a more mature rover.

Senior Embedded Software Engineer Aamer Almujahed (left) and Software Engineering intern Ashten Akemoto run the ground software for Astrobotic’s CubeRover drawbar pull test inside the Granular Mechanics and Regolith Operations (GMRO) Laboratory’s regolith pit at NASA Kennedy Space Center’s Swamp Works facility on June 30, 2022. Astrobotic – a Pittsburgh-based space robotics company – is using the GMRO lab’s regolith bin, which holds approximately 120 tons of lunar regolith simulant, to depict how the company’s CubeRover would perform on the Moon. NASA’s Small Business Innovation Research program provided the funding for initial development, and a $2 million Tipping Point award from the agency has provided additional funding for continued development into a more mature rover.

Robotics Software Engineer II Chris Rampolla (right) and Software Engineering intern Ashten Akemoto issue commands to Astrobotic’s CubeRover using the company’s ground software during mobility testing at NASA’s Kennedy Space Center in Florida on June 30, 2022. Astrobotic – a Pittsburgh-based space robotics company – is using the spaceport’s Swamp Works facility and the Granular Mechanics and Regolith Operations Laboratory to conduct mobility testing of their rover. The laboratory’s regolith bin, which holds approximately 120 tons of lunar regolith simulant, will help depict how the company’s CubeRover would perform on the Moon. NASA’s Small Business Innovation Research program provided the funding for initial development, and a $2 million Tipping Point award has provided additional funding for continued development into a more mature rover.

Hundreds of children participated in the annual Take Our Children to Work Day at Stennis Space Center on July 29. During the day, children of Stennis employees received a tour of facilities and took part in various activities, including demonstrations in cryogenics and robotics.

To celebrate its 10-year anniversary, the Swamp Works team poses for a group photograph inside the Swamp Works laboratory area at NASA’s Kennedy Space Center in Florida on April 21, 2023. Swamp Works includes several laboratories where hands-on, cutting-edge technology is developed for NASA and its exploration goals, as well as for benefits on Earth.

Work of Wind on Pavonis Mons

Phoenix Lander Work Area

Sojourner APXS at Work

Spirit Winter Work Site

Spirit Back at Work

At Work in the Plains of Meridiani

Abrasion Work on Uchben

NASA astronaut Jessica Watkins visits the Granular Mechanics and Regolith Operations Laboratory inside Swamp Works at Kennedy Space Center in Florida on Wednesday, Aug. 27, 2025, to view some of the evolving technologies in development that astronauts may use to explore the Moon’s surface, prepare it for sustainable outposts, and to handle the dust that is collected during moonwalks.

NASA astronaut Jessica Watkins visits the Granular Mechanics and Regolith Operations Laboratory inside Swamp Works at Kennedy Space Center in Florida on Wednesday, Aug. 27, 2025, to view some of the evolving technologies in development that astronauts may use to explore the Moon’s surface, prepare it for sustainable outposts, and to handle the dust that is collected during moonwalks.

NASA astronaut Randy Bresnik visits the Granular Mechanics and Regolith Operations Laboratory inside Swamp Works at Kennedy Space Center in Florida on Wednesday, Aug. 27, 2025, to view some of the evolving technologies in development that astronauts may use to explore the Moon’s surface, prepare it for sustainable outposts, and to handle the dust that is collected during moonwalks.

NASA astronaut Jessica Watkins visits the Granular Mechanics and Regolith Operations Laboratory inside Swamp Works at Kennedy Space Center in Florida on Wednesday, Aug. 27, 2025, to view some of the evolving technologies in development that astronauts may use to explore the Moon’s surface, prepare it for sustainable outposts, and to handle the dust that is collected during moonwalks.

NASA astronaut Jessica Watkins visits the Granular Mechanics and Regolith Operations Laboratory inside Swamp Works at Kennedy Space Center in Florida on Wednesday, Aug. 27, 2025, to view some of the evolving technologies in development that astronauts may use to explore the Moon’s surface, prepare it for sustainable outposts, and to handle the dust that is collected during moonwalks.

To celebrate its 10-year anniversary, the Swamp Works team poses for a group photograph inside the Space Station Processing Facility conference room at NASA’s Kennedy Space Center in Florida on April 21, 2023. Swamp Works includes several laboratories where hands-on, cutting-edge technology is developed for NASA and its exploration goals, as well as for benefits on Earth.

YOUNG PEOPLE PARTICIPATING IN “TAKE OUR CHILDREN TO WORK DAY,” AIDED BY STUDENTS AND TEACHERS ON THE MOULTON ROBOTICS TECHNOLOGIES TEAM FROM MOULTON MIDDLE SCHOOL AND LAWRENCE COUNTY HIGH SCHOOL, BOTH IN MOULTON, ALABAMA, LEARNED TO OPERATE ROBOTS

NASA astronauts Randy Bresnik (left) and Jessica Watkins (center) visit the Granular Mechanics and Regolith Operations Laboratory inside Swamp Works at Kennedy Space Center in Florida on Wednesday, Aug. 27, 2025, to view some of the evolving technologies in development that astronauts may use to explore the Moon’s surface, prepare it for sustainable outposts, and to handle the dust that is collected during moonwalks.

NASA astronauts Randy Bresnik (center) and Jessica Watkins (right) visit the Granular Mechanics and Regolith Operations Laboratory inside Swamp Works at Kennedy Space Center in Florida on Wednesday, Aug. 27, 2025, to view some of the evolving technologies in development that astronauts may use to explore the Moon’s surface, prepare it for sustainable outposts, and to handle the dust that is collected during moonwalks. Bresnick holds an instrument designed to help astronauts electromagnetically remove accumulated lunar dust.

NASA astronauts Randy Bresnik and Jessica Watkins visit the Granular Mechanics and Regolith Operations Laboratory inside Swamp Works at Kennedy Space Center in Florida on Wednesday, Aug. 27, 2025, to view some of the evolving technologies in development that astronauts may use to explore the Moon’s surface, prepare it for sustainable outposts, and to handle the dust that is collected during moonwalks.

NASA astronauts Randy Bresnik (far left) and Jessica Watkins (center) visit the Granular Mechanics and Regolith Operations Laboratory inside Swamp Works at Kennedy Space Center in Florida on Wednesday, Aug. 27, 2025, to view some of the evolving technologies in development that NASA astronauts may use to explore the Moon’s surface, prepare it for sustainable outposts, and to handle the dust that is collected during moonwalks. Watkins holds an instrument designed to help astronauts electromagnetically remove accumulated lunar dust.

NASA astronauts Jessica Watkins and Randy Bresnik visit the Granular Mechanics and Regolith Operations Laboratory inside Swamp Works at Kennedy Space Center in Florida on Wednesday, Aug. 27, 2025, to view some of the evolving technologies in development that astronauts may use to explore the Moon’s surface, prepare it for sustainable outposts, and to handle the dust that is collected during moonwalks.

NASA astronauts Randy Bresnik (left) and Jessica Watkins (center) visit the Granular Mechanics and Regolith Operations Laboratory inside Swamp Works at Kennedy Space Center in Florida on Wednesday, Aug. 27, 2025, to view some of the evolving technologies in development that astronauts may use to explore the Moon’s surface, prepare it for sustainable outposts, and to handle the dust that is collected during moonwalks.

A.J. Nick, left, and Drew Smith, robotics engineers with the Exploration Research and Technology programs at NASA's Kennedy Space Center, test Bulk Metallic Glass Gears (BMGGs) in a vacuum inside a cryogenic cooler at Kennedy's Granular Mechanics and Regolith Operations lab on June 17, 2021. Made from a custom bulk metallic glass alloy, BMGGs could be used in heater-free gearboxes at extremely low temperatures in locations such as the Moon, Mars, and Europa, one of Jupiter’s moons. NASA’s Jet Propulsion Laboratory is working with commercial partners to create the gears.

Drew Smith, a robotics engineer and lab manager with the Exploration Research and Technology programs at NASA's Kennedy Space Center, prepares a Bulk Metallic Glass Gear (BMGG) for ambient temperature tests in a vacuum inside a cryogenic cooler at Kennedy's Granular Mechanics and Regolith Operations lab on June 17, 2021. Made from a custom bulk metallic glass alloy, BMGGs could be used in heater-free gearboxes at extremely low temperatures in locations such as the Moon, Mars, and Europa, one of Jupiter’s moons. NASA’s Jet Propulsion Laboratory is working with commercial partners to create the gears.

Drew Smith, a robotics engineer and lab manager with the Exploration Research and Technology programs at NASA's Kennedy Space Center, prepares a Bulk Metallic Glass Gear (BMGG) for ambient temperature tests in a vacuum inside a cryogenic cooler at Kennedy's Granular Mechanics and Regolith Operations lab on June 17, 2021. Made from a custom bulk metallic glass alloy, BMGGs could be used in heater-free gearboxes at extremely low temperatures in locations such as the Moon, Mars, and Europa, one of Jupiter’s moons. NASA’s Jet Propulsion Laboratory is working with commercial partners to create the gears.

Employees at NASA's John C. Stennis Space Center work to maneuver a structural steam beam into place on the A-1 Test Stand on Jan. 13. The beam was one of several needed to form the thrust takeout structure that will support a new thrust measurement system being installed on the stand for future rocket engine testing. Once lifted onto the stand, the beams had to be hoisted into place through the center of the test stand, with only two inches of clearance on each side. The new thrust measurement system represents a state-of-the-art upgrade from the equipment installed more than 40 years ago when the test stand was first constructed.

NASA’s RASSOR (Regolith Advanced Surface Systems Operations Robot) manipulates simulated regolith, or lunar dust found on the Moon’s surface, to create a three-foot berm during a site preparation test inside of the Granular Mechanics and Regolith Operations Lab at the agency’s Kennedy Space Center in Florida on Tuesday, June 3, 2025. The opposing motion of the bucket drums helps RASSOR grip the surface in low-gravity environments like the Moon or Mars. With this unique capability, RASSOR can traverse the rough surface to dig, load, haul, and dump regolith that could be used in construction or broken down into hydrogen, oxygen, or water, resources critical for sustaining human presence. RASSOR represents an earlier generation technology that informed the development of NASA’s IPEx (In-Situ Resource Utilization Pilot Excavator), serving as a precursor and foundational platform for the advanced excavation systems and autonomous capabilities now being demonstrated by this Moon-mining robot.

NASA’s RASSOR (Regolith Advanced Surface Systems Operations Robot) manipulates simulated regolith, or lunar dust found on the Moon’s surface, to create a three-foot berm during a site preparation test inside of the Granular Mechanics and Regolith Operations Lab at the agency’s Kennedy Space Center in Florida on Tuesday, June 3, 2025. The opposing motion of the bucket drums helps RASSOR grip the surface in low-gravity environments like the Moon or Mars. With this unique capability, RASSOR can traverse the rough surface to dig, load, haul, and dump regolith that could be used in construction or broken down into hydrogen, oxygen, or water, resources critical for sustaining human presence. RASSOR represents an earlier generation technology that informed the development of NASA’s IPEx (In-Situ Resource Utilization Pilot Excavator), serving as a precursor and foundational platform for the advanced excavation systems and autonomous capabilities now being demonstrated by this Moon-mining robot.

NASA’s RASSOR (Regolith Advanced Surface Systems Operations Robot) manipulates simulated regolith, or lunar dust found on the Moon’s surface, to create a three-foot berm during a site preparation test inside of the Granular Mechanics and Regolith Operations Lab at the agency’s Kennedy Space Center in Florida on Tuesday, June 3, 2025. The opposing motion of the bucket drums helps RASSOR grip the surface in low-gravity environments like the Moon or Mars. With this unique capability, RASSOR can traverse the rough surface to dig, load, haul, and dump regolith that could be used in construction or broken down into hydrogen, oxygen, or water, resources critical for sustaining human presence. RASSOR represents an earlier generation technology that informed the development of NASA’s IPEx (In-Situ Resource Utilization Pilot Excavator), serving as a precursor and foundational platform for the advanced excavation systems and autonomous capabilities now being demonstrated by this Moon-mining robot.

NASA’s RASSOR (Regolith Advanced Surface Systems Operations Robot) manipulates simulated regolith, or lunar dust found on the Moon’s surface, to create a three-foot berm during a site preparation test inside of the Granular Mechanics and Regolith Operations Lab at the agency’s Kennedy Space Center in Florida on Tuesday, June 3, 2025. The opposing motion of the bucket drums helps RASSOR grip the surface in low-gravity environments like the Moon or Mars. With this unique capability, RASSOR can traverse the rough surface to dig, load, haul, and dump regolith that could be used in construction or broken down into hydrogen, oxygen, or water, resources critical for sustaining human presence. RASSOR represents an earlier generation technology that informed the development of NASA’s IPEx (In-Situ Resource Utilization Pilot Excavator), serving as a precursor and foundational platform for the advanced excavation systems and autonomous capabilities now being demonstrated by this Moon-mining robot.

NASA’s RASSOR (Regolith Advanced Surface Systems Operations Robot) manipulates simulated regolith, or lunar dust found on the Moon’s surface, to create a three-foot berm during a site preparation test inside of the Granular Mechanics and Regolith Operations Lab at the agency’s Kennedy Space Center in Florida on Tuesday, June 3, 2025. The opposing motion of the bucket drums helps RASSOR grip the surface in low-gravity environments like the Moon or Mars. With this unique capability, RASSOR can traverse the rough surface to dig, load, haul, and dump regolith that could be used in construction or broken down into hydrogen, oxygen, or water, resources critical for sustaining human presence. RASSOR represents an earlier generation technology that informed the development of NASA’s IPEx (In-Situ Resource Utilization Pilot Excavator), serving as a precursor and foundational platform for the advanced excavation systems and autonomous capabilities now being demonstrated by this Moon-mining robot.

NASA’s RASSOR (Regolith Advanced Surface Systems Operations Robot) manipulates simulated regolith, or lunar dust found on the Moon’s surface, to create a three-foot berm during a site preparation test inside of the Granular Mechanics and Regolith Operations Lab at the agency’s Kennedy Space Center in Florida on Tuesday, June 3, 2025. The opposing motion of the bucket drums helps RASSOR grip the surface in low-gravity environments like the Moon or Mars. With this unique capability, RASSOR can traverse the rough surface to dig, load, haul, and dump regolith that could be used in construction or broken down into hydrogen, oxygen, or water, resources critical for sustaining human presence. RASSOR represents an earlier generation technology that informed the development of NASA’s IPEx (In-Situ Resource Utilization Pilot Excavator), serving as a precursor and foundational platform for the advanced excavation systems and autonomous capabilities now being demonstrated by this Moon-mining robot.

NASA’S MARSHALL SPACE FLIGHT CENTER KICKS OFF ITS ANNUAL "TAKE OUR CHILDREN TO WORK DAY" EVENTS JUNE 23 WITH OPENING REMARKS FROM LOUCIOUS HIRES, DIRECTOR OF MARSHALL’S OFFICE OF DIVERSITY AND EQUAL OPPORTUNITY. AN ESTIMATED 500 POTENTIAL FUTURE SPACEFARERS, SCIENTISTS AND ENGINEERS IN GRADES 3-12 TOOK PART IN THE DAY’S ACTIVITIES, TOURS AND PRESENTATIONS.

Groups from the Granular Mechanics and Regolith Operations (GMRO) laboratory and the Electrostatics and Surface Physics Laboratory (ESPL) gather for a photograph to celebrate the 10th anniversary of Swamp Works at NASA’s Kennedy Space Center in Florida on Feb. 13, 2023. Studies of the mechanics of materials in a launch pad environment are performed in the GMRO lab. The team also develops technologies for handling lunar and Martian regolith, including excavator technologies, pneumatic transport of soil, and magnetic handling of soil. The ESPL group performs scientific investigations to protect flight hardware and launch equipment from the phenomenon of electrostatic discharges, commonly known as sparks.

Groups from the Granular Mechanics and Regolith Operations (GMRO) laboratory and the Electrostatics and Surface Physics Laboratory (ESPL) gather for a photograph to celebrate the 10th anniversary of Swamp Works at NASA’s Kennedy Space Center in Florida on Feb. 13, 2023. Studies of the mechanics of materials in a launch pad environment are performed in the GMRO lab. The team also develops technologies for handling lunar and Martian regolith, including excavator technologies, pneumatic transport of soil, and magnetic handling of soil. The ESPL group performs scientific investigations to protect flight hardware and launch equipment from the phenomenon of electrostatic discharges, commonly known as sparks.

Opportunity at Work Inside Victoria Crater

KSC Protectice Services - Working Dogs Feature Story.

KSC Protectice Services - Working Dogs Feature Story.

Dr. Carlos Calle, lead scientist in the Kennedy Space Center's Electrostatics and Surface Physics Laboratory, left, and Jay Phillips, a research physicist, are modifying an electrostatic precipitator to help remove dust from a simulated Martian atmosphere. NASA's Journey to Mars requires cutting-edge technologies to solve the problems explorers will face on the Red Planet. Scientists are developing some of the needed solutions by adapting a device to remove the ever-present dust from valuable elements in the Martian atmosphere. Those commodities include oxygen, water and methane.

Jay Phillips, a research physicist in the Kennedy Space Center's Electrostatics and Surface Physics Laboratory, left, and Dr. Carlos Calle, lead scientist in the lab, are modifying an electrostatic precipitator to help remove dust from simulated Martian atmosphere. NASA's Journey to Mars requires cutting-edge technologies to solve the problems explorers will face on the Red Planet. Scientists are developing some of the needed solutions by adapting a device to remove the ever-present dust from valuable elements in the Martian atmosphere. Those commodities include oxygen, water and methane.

Dr. Carlos Calle, lead scientist in the Kennedy Space Center's Electrostatics and Surface Physics Laboratory, left, and Jay Phillips, a research physicist, are modifying an electrostatic precipitator to help remove dust from simulated Martian atmosphere. NASA's Journey to Mars requires cutting-edge technologies to solve the problems explorers will face on the Red Planet. Scientists are developing some of the needed solutions by adapting a device to remove the ever-present dust from valuable elements in the Martian atmosphere. Those commodities include oxygen, water and methane.

A team at NASA’s Kennedy Space Center in Florida tests small- and medium-sized bucket drums July 16, 2021, in the Granular Mechanics and Regolith Operations Lab’s “big bin” during prototype development for the pilot excavator, a robotic mission designed for lunar operations. The bucket drum excavated lunar regolith simulant. The Swamp Works team leveled and compacted the simulant before excavation as well as measured penetration during the excavator testing. Robotics engineers Jason Schuler and Austin Langton worked inside the bin, teaming up with software engineer Kurt Leucht, who worked just outside of it.

A team at NASA’s Kennedy Space Center in Florida tests small- and medium-sized bucket drums July 16, 2021, in the Granular Mechanics and Regolith Operations Lab’s “big bin” during prototype development for the pilot excavator, a robotic mission designed for lunar operations. The bucket drum excavated lunar regolith simulant. The Swamp Works team leveled and compacted the simulant before excavation as well as measured penetration during the excavator testing. Robotics engineers Jason Schuler and Austin Langton worked inside the bin, teaming up with software engineer Kurt Leucht, who worked just outside of it.

A team at NASA’s Kennedy Space Center in Florida tests small- and medium-sized bucket drums July 16, 2021, in the Granular Mechanics and Regolith Operations Lab’s “big bin” during prototype development for the pilot excavator, a robotic mission designed for lunar operations. The bucket drum excavated lunar regolith simulant. The Swamp Works team leveled and compacted the simulant before excavation as well as measured penetration during the excavator testing. Robotics engineers Jason Schuler and Austin Langton worked inside the bin, teaming up with software engineer Kurt Leucht, who worked just outside of it.

A team at NASA’s Kennedy Space Center in Florida tests small- and medium-sized bucket drums July 16, 2021, in the Granular Mechanics and Regolith Operations Lab’s “big bin” during prototype development for the pilot excavator, a robotic mission designed for lunar operations. The bucket drum excavated lunar regolith simulant. The Swamp Works team leveled and compacted the simulant before excavation as well as measured penetration during the excavator testing. Robotics engineers Jason Schuler and Austin Langton worked inside the bin, teaming up with software engineer Kurt Leucht, who worked just outside of it.

A team at NASA’s Kennedy Space Center in Florida tests small- and medium-sized bucket drums July 16, 2021, in the Granular Mechanics and Regolith Operations Lab’s “big bin” during prototype development for the pilot excavator, a robotic mission designed for lunar operations. The bucket drum excavated lunar regolith simulant. The Swamp Works team leveled and compacted the simulant before excavation as well as measured penetration during the excavator testing. Robotics engineers Jason Schuler and Austin Langton worked inside the bin, teaming up with software engineer Kurt Leucht, who worked just outside of it.

A team at NASA’s Kennedy Space Center in Florida tests small- and medium-sized bucket drums July 16, 2021, in the Granular Mechanics and Regolith Operations Lab’s “big bin” during prototype development for the pilot excavator, a robotic mission designed for lunar operations. The bucket drum excavated lunar regolith simulant. The Swamp Works team leveled and compacted the simulant before excavation as well as measured penetration during the excavator testing. Robotics engineers Jason Schuler and Austin Langton worked inside the bin, teaming up with software engineer Kurt Leucht, who worked just outside of it.

A team at NASA’s Kennedy Space Center in Florida tests small- and medium-sized bucket drums July 16, 2021, in the Granular Mechanics and Regolith Operations Lab’s “big bin” during prototype development for the pilot excavator, a robotic mission designed for lunar operations. The bucket drum excavated lunar regolith simulant. The Swamp Works team leveled and compacted the simulant before excavation as well as measured penetration during the excavator testing. Robotics engineers Jason Schuler and Austin Langton worked inside the bin, teaming up with software engineer Kurt Leucht, who worked just outside of it.

A team at NASA’s Kennedy Space Center in Florida tests small- and medium-sized bucket drums July 16, 2021, in the Granular Mechanics and Regolith Operations Lab’s “big bin” during prototype development for the pilot excavator, a robotic mission designed for lunar operations. The bucket drum excavated lunar regolith simulant. The Swamp Works team leveled and compacted the simulant before excavation as well as measured penetration during the excavator testing. Robotics engineers Jason Schuler and Austin Langton worked inside the bin, teaming up with software engineer Kurt Leucht, who worked just outside of it.

Employees wear personal protective gear at Michoud Assembly Facility as the facility transitioned to Stage 3 of NASA’s Framework for Return To On-Site Work. Employees wear the appropriate personal protective equipment (PPE) and/or cloth face coverings as required for assigned tasks. Access to the facility is limited to authorized personnel working on mission-critical tasks that must be conducted onsite. Mission-critical tasks include slowly and methodically resuming Space Launch System (SLS) Core Stage and Orion production activities, particularly critical path deliverables to support the Artemis Program, at a pace that limits personnel and follows federal guidelines for social distancing and use of personal protective equipment such as face masks. For more information about SLS, visit nasa.gov/sls.

Employees wear personal protective gear at Michoud Assembly Facility as the facility transitioned to Stage 3 of NASA’s Framework for Return To On-Site Work. Employees wear the appropriate personal protective equipment (PPE) and/or cloth face coverings as required for assigned tasks. Access to the facility is limited to authorized personnel working on mission-critical tasks that must be conducted onsite. Mission-critical tasks include slowly and methodically resuming Space Launch System (SLS) Core Stage and Orion production activities, particularly critical path deliverables to support the Artemis Program, at a pace that limits personnel and follows federal guidelines for social distancing and use of personal protective equipment such as face masks. For more information about SLS, visit nasa.gov/sls.

Employees wear personal protective gear at Michoud Assembly Facility as the facility transitioned to Stage 3 of NASA’s Framework for Return To On-Site Work. Employees wear the appropriate personal protective equipment (PPE) and/or cloth face coverings as required for assigned tasks. Access to the facility is limited to authorized personnel working on mission-critical tasks that must be conducted onsite. Mission-critical tasks include slowly and methodically resuming Space Launch System (SLS) Core Stage and Orion production activities, particularly critical path deliverables to support the Artemis Program, at a pace that limits personnel and follows federal guidelines for social distancing and use of personal protective equipment such as face masks. For more information about SLS, visit nasa.gov/sls.