NASA’s Space Launch System (SLS) rocket with the Orion spacecraft atop launches the agency’s Artemis I flight test, Wednesday, Nov. 16 from Launch Complex 39B at NASA’s Kennedy Space Center in Florida. The Moon rocket and spacecraft lifted off at 1:47 a.m. ET. The Artemis I mission is the first integrated test of the agency’s deep space exploration systems: the Space Launch System rocket, Orion spacecraft, and supporting ground systems. The mission is the first in a series of increasingly complex missions to the Moon. With Artemis missions, NASA will land the first woman and first person of color on the Moon, using innovative technologies to explore more of the lunar surface than ever before.

Teams move the core stage liquid hydrogen tank for the Artemis III mission to a priming cell near the Vertical Assembly Building at NASA’s Michoud Assembly Facility in New Orleans Nov. 21. Technichians will sand down and prepare the suface of the tank before coating it in a primer. Primer is applied to the barrel section of the tank by an automated robotic tool, whereas the forward and aft domes are primed manually. Once priming is complete, technicians with NASA and Boeing, the SLS core stage prime contractor, will apply a foam-based thermal protection system, which protects the propellant tank from the extreme temperatures it will face during launch and flight while also regulating the super-chilled propellant within it. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

Teams move the core stage liquid hydrogen tank for the Artemis III mission to a priming cell near the Vertical Assembly Building at NASA’s Michoud Assembly Facility in New Orleans Nov. 21. Technichians will sand down and prepare the suface of the tank before coating it in a primer. Primer is applied to the barrel section of the tank by an automated robotic tool, whereas the forward and aft domes are primed manually. Once priming is complete, technicians with NASA and Boeing, the SLS core stage prime contractor, will apply a foam-based thermal protection system, which protects the propellant tank from the extreme temperatures it will face during launch and flight while also regulating the super-chilled propellant within it. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

SLS Liquid Hydrogen Tank Test Article Moved at NASA’s Michoud Assembly Facility

SLS Liquid Hydrogen Tank Test Article Moved at NASA’s Michoud Assembly Facility

Teams move the core stage liquid hydrogen tank for the Artemis III mission to a priming cell near the Vertical Assembly Building at NASA’s Michoud Assembly Facility in New Orleans Nov. 21. Technichians will sand down and prepare the suface of the tank before coating it in a primer. Primer is applied to the barrel section of the tank by an automated robotic tool, whereas the forward and aft domes are primed manually. Once priming is complete, technicians with NASA and Boeing, the SLS core stage prime contractor, will apply a foam-based thermal protection system, which protects the propellant tank from the extreme temperatures it will face during launch and flight while also regulating the super-chilled propellant within it. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

NASA’s Space Launch System (SLS) rocket with the Orion spacecraft aboard is seen atop the mobile launcher at Launch 39B at NASA’s Kennedy Space Center in Florida. Artemis I mission is the first integrated test of the agency’s deep space exploration systems: the Space Launch System rocket, Orion spacecraft, and supporting ground systems. The mission is the first in a series of increasingly complex missions to the Moon. Launch of the uncrewed flight test is targeted for no earlier than Aug. 29 at 8:33 a.m. ET. With Artemis missions, NASA will land the first woman and first person of color on the Moon, using innovative technologies to explore more of the lunar surface than ever before.

Teams move the core stage liquid hydrogen tank for the Artemis III mission to a priming cell near the Vertical Assembly Building at NASA’s Michoud Assembly Facility in New Orleans Nov. 21. Technichians will sand down and prepare the suface of the tank before coating it in a primer. Primer is applied to the barrel section of the tank by an automated robotic tool, whereas the forward and aft domes are primed manually. Once priming is complete, technicians with NASA and Boeing, the SLS core stage prime contractor, will apply a foam-based thermal protection system, which protects the propellant tank from the extreme temperatures it will face during launch and flight while also regulating the super-chilled propellant within it. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

Teams move the core stage liquid hydrogen tank for the Artemis III mission to a priming cell near the Vertical Assembly Building at NASA’s Michoud Assembly Facility in New Orleans Nov. 21. Technichians will sand down and prepare the suface of the tank before coating it in a primer. Primer is applied to the barrel section of the tank by an automated robotic tool, whereas the forward and aft domes are primed manually. Once priming is complete, technicians with NASA and Boeing, the SLS core stage prime contractor, will apply a foam-based thermal protection system, which protects the propellant tank from the extreme temperatures it will face during launch and flight while also regulating the super-chilled propellant within it. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

Teams move the core stage liquid hydrogen tank for the Artemis III mission to a priming cell near the Vertical Assembly Building at NASA’s Michoud Assembly Facility in New Orleans Nov. 21. Technichians will sand down and prepare the suface of the tank before coating it in a primer. Primer is applied to the barrel section of the tank by an automated robotic tool, whereas the forward and aft domes are primed manually. Once priming is complete, technicians with NASA and Boeing, the SLS core stage prime contractor, will apply a foam-based thermal protection system, which protects the propellant tank from the extreme temperatures it will face during launch and flight while also regulating the super-chilled propellant within it. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

SLS Liquid Hydrogen Tank Test Article Moved at NASA’s Michoud Assembly Facility

NASA finished assembling and joining the main structural components for the largest rocket stage the agency has built since the Saturn V that sent Apollo astronauts to the Moon. Engineers at the agency’s Michoud Assembly Facility in New Orleans connected the last of the five sections of the Space Launch System (SLS) rocket core stage Sept. 19. The stage will produce 2 million pounds of thrust to send Artemis I, the first flight SLS and NASA’s Orion spacecraft to the Moon. The engine section is located at the bottom of the 212-foot-tall stage and houses the four RS-25 engines. The core stage’s two liquid propellant tanks and four RS-25 engines will produce more than 2 million pounds of thrust to send the SLS rocket and Orion on the Artemis lunar missions. The engine section houses the four RS-25 engines and includes vital systems for mounting, controlling and delivering fuel form the propellant tanks to the rocket’s engines. Offering more payload mass, volume capability and energy to speed missions through space, the SLS rocket, along with NASA’s Gateway in lunar orbit and Orion, is part of NASA’s backbone for deep space exploration and the Artemis lunar program. No other rocket is capable of carrying astronauts in Orion around the Moon in a single mission.

Teams move the core stage liquid hydrogen tank for the Artemis III mission to a priming cell near the Vertical Assembly Building at NASA’s Michoud Assembly Facility in New Orleans Nov. 21. Technichians will sand down and prepare the suface of the tank before coating it in a primer. Primer is applied to the barrel section of the tank by an automated robotic tool, whereas the forward and aft domes are primed manually. Once priming is complete, technicians with NASA and Boeing, the SLS core stage prime contractor, will apply a foam-based thermal protection system, which protects the propellant tank from the extreme temperatures it will face during launch and flight while also regulating the super-chilled propellant within it. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

SLS Liquid Hydrogen Tank Test Article Moved at NASA’s Michoud Assembly Facility

NASA’s Space Launch System (SLS) rocket with the Orion spacecraft atop launches the agency’s Artemis I flight test, Wednesday, Nov. 16 from Launch Complex 39B at NASA’s Kennedy Space Center in Florida. The Moon rocket and spacecraft lifted off at 1:47 a.m. ET. The Artemis I mission is the first integrated test of the agency’s deep space exploration systems: the Space Launch System rocket, Orion spacecraft, and supporting ground systems. The mission is the first in a series of increasingly complex missions to the Moon. With Artemis missions, NASA will land the first woman and first person of color on the Moon, using innovative technologies to explore more of the lunar surface than ever before.

NASA’s Space Launch System (SLS) rocket with the Orion spacecraft atop launches the agency’s Artemis I flight test, Wednesday, Nov. 16 from Launch Complex 39B at NASA’s Kennedy Space Center in Florida. The Moon rocket and spacecraft lifted off at 1:47 a.m. ET. The Artemis I mission is the first integrated test of the agency’s deep space exploration systems: the Space Launch System rocket, Orion spacecraft, and supporting ground systems. The mission is the first in a series of increasingly complex missions to the Moon. With Artemis missions, NASA will land the first woman and first person of color on the Moon, using innovative technologies to explore more of the lunar surface than ever before.

NASA’s Space Launch System (SLS) rocket with the Orion spacecraft atop launches the agency’s Artemis I flight test, Wednesday, Nov. 16 from Launch Complex 39B at NASA’s Kennedy Space Center in Florida. The Moon rocket and spacecraft lifted off at 1:47 a.m. ET. The Artemis I mission is the first integrated test of the agency’s deep space exploration systems: the Space Launch System rocket, Orion spacecraft, and supporting ground systems. The mission is the first in a series of increasingly complex missions to the Moon. With Artemis missions, NASA will land the first woman and first person of color on the Moon, using innovative technologies to explore more of the lunar surface than ever before.

Teams move the core stage liquid hydrogen tank for the Artemis III mission to a priming cell near the Vertical Assembly Building at NASA’s Michoud Assembly Facility in New Orleans Nov. 21. Technichians will sand down and prepare the suface of the tank before coating it in a primer. Primer is applied to the barrel section of the tank by an automated robotic tool, whereas the forward and aft domes are primed manually. Once priming is complete, technicians with NASA and Boeing, the SLS core stage prime contractor, will apply a foam-based thermal protection system, which protects the propellant tank from the extreme temperatures it will face during launch and flight while also regulating the super-chilled propellant within it. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

SLS Liquid Hydrogen Tank Test Article Moved at NASA’s Michoud Assembly Facility

Teams move the core stage liquid hydrogen tank for the Artemis III mission to a priming cell near the Vertical Assembly Building at NASA’s Michoud Assembly Facility in New Orleans Nov. 21. Technichians will sand down and prepare the suface of the tank before coating it in a primer. Primer is applied to the barrel section of the tank by an automated robotic tool, whereas the forward and aft domes are primed manually. Once priming is complete, technicians with NASA and Boeing, the SLS core stage prime contractor, will apply a foam-based thermal protection system, which protects the propellant tank from the extreme temperatures it will face during launch and flight while also regulating the super-chilled propellant within it. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

SLS Liquid Hydrogen Tank Test Article Moved at NASA’s Michoud Assembly Facility

SLS Liquid Hydrogen Tank Test Article Moved at NASA’s Michoud Assembly Facility

Space Launch System Corestage-1 in production at the Michoud Assembly Facility in New Orleans.

Teams move the core stage liquid hydrogen tank for the Artemis III mission to a priming cell near the Vertical Assembly Building at NASA’s Michoud Assembly Facility in New Orleans Nov. 21. Technichians will sand down and prepare the suface of the tank before coating it in a primer. Primer is applied to the barrel section of the tank by an automated robotic tool, whereas the forward and aft domes are primed manually. Once priming is complete, technicians with NASA and Boeing, the SLS core stage prime contractor, will apply a foam-based thermal protection system, which protects the propellant tank from the extreme temperatures it will face during launch and flight while also regulating the super-chilled propellant within it. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

These photos and videos show how technicians at NASA’s Michoud Assembly Facility in New Orleans installed the third and fourth RS-25 engines onto the core stage for the agency’s SLS (Space Launch System) rocket that will help power NASA’s first crewed Artemis mission to the Moon. Technicians added the first engine to the SLS core stage Sept. 11. The second engine was installed onto the stage Sept. 15 with the third and fourth engines following Sept. 19 and Sept. 20. Engineers consider the engines to be “soft” mated to the rocket stage. Technicians with NASA, Aerojet Rocketdyne, an L3Harris Technologies company and the RS-25 engines lead contractor, along with Boeing, the core stage lead contractor, will now focus efforts on the complex tax of fully securing the engines to the stage and integrating the propulsion and electrical systems within the structure. NASA is working to land the first woman and first person of color on the Moon under Artemis. SLS is part of NASA’s backbone for deep space exploration, along with Orion and the Gateway in orbit around the Moon. SLS is the only rocket that can send Orion, astronauts, and supplies to the Moon in a single mission.

Teams at NASA’s Michoud Assembly Facility in New Orleans move a liquid hydrogen tank for the agency’s SLS (Space Launch System) rocket into the factory’s final assembly area on April 22. Having recently completed application of the thermal protection system, teams will now continue outfitting the 130-foot-tall tank with critical systems to ready it for its designated Artemis III mission. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce more than two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

Melody Lovin, Space Launch Delta 45 weather officer, participates in a prelaunch media briefing following a mission management team meeting for Artemis I on Sept. 1, 2022, at NASA’s Kennedy Space Center in Florida. Artemis I is scheduled to launch at 2:17 p.m. EDT on Sept. 3, from Kennedy’s Launch Complex 39B. Launch was waved off on Aug. 29 due to an issue during tanking. The first in a series of increasingly complex missions, Artemis I will provide a foundation for human deep space exploration and demonstrate NASA’s capability to extend human presence to the Moon and beyond. The primary goal of Artemis I is to thoroughly test the integrated systems before crewed missions by operating the spacecraft in a deep space environment, testing Orion’s heat shield, and recovering the crew module after reentry, descent, and splashdown.

Teams move a liquid hydrogen tank for NASA’s SLS (Space Launch System) rocket out of a priming cell and into an adjacent cell on May 20 at the agency’s Michoud Assembly Facility in New Orleans. Inside the cell, the tank, which will be used on the core stage of NASA’s Artemis III mission, will receive its thermal protection system. The thermal protection system, or spray-on foam insulation, provides protection to the core stage during launch. It is flexible enough to move with the rocket yet can withstand the aerodynamic pressures as the SLS accelerates from 0 to 17,500 mph and soars to more than 100 miles above the Earth. This third-generation insulation is more environmentally friendly and keeps the cryogenic propellant, which powers the rocket’s four RS-25 engines, extremely cold (the liquid hydrogen must remain at minus 423 degrees Fahrenheit/253 degrees Celsius) to remain in its liquid state. When applied the thermal protection system is a light-yellow color, which “tans” once exposed to the Sun’s ultraviolet rays, giving the SLS core stage its signature orange color.

Teams move a liquid hydrogen tank for NASA’s SLS (Space Launch System) rocket out of a priming cell and into an adjacent cell on May 20 at the agency’s Michoud Assembly Facility in New Orleans. Inside the cell, the tank, which will be used on the core stage of NASA’s Artemis III mission, will receive its thermal protection system. The thermal protection system, or spray-on foam insulation, provides protection to the core stage during launch. It is flexible enough to move with the rocket yet can withstand the aerodynamic pressures as the SLS accelerates from 0 to 17,500 mph and soars to more than 100 miles above the Earth. This third-generation insulation is more environmentally friendly and keeps the cryogenic propellant, which powers the rocket’s four RS-25 engines, extremely cold (the liquid hydrogen must remain at minus 423 degrees Fahrenheit/253 degrees Celsius) to remain in its liquid state. When applied the thermal protection system is a light-yellow color, which “tans” once exposed to the Sun’s ultraviolet rays, giving the SLS core stage its signature orange color.

Mike Sarafin, Artemis mission manager, participates in a prelaunch media briefing following a mission management team meeting for Artemis I on Sept. 1, 2022, at NASA’s Kennedy Space Center in Florida. Artemis I is scheduled to launch at 2:17 p.m. EDT on Sept. 3, from Kennedy’s Launch Complex 39B. Launch was waved off on Aug. 29 due to an issue during tanking. The first in a series of increasingly complex missions, Artemis I will provide a foundation for human deep space exploration and demonstrate NASA’s capability to extend human presence to the Moon and beyond. The primary goal of Artemis I is to thoroughly test the integrated systems before crewed missions by operating the spacecraft in a deep space environment, testing Orion’s heat shield, and recovering the crew module after reentry, descent, and splashdown.

NASA astronaut Anne McClain talks with student essay winners Amanda Gutierrez, left, and Taia Saurer at the agency’s news center at Kennedy Space Center in Florida on Sept. 2, 2022. Gutierrez and Saurer won the Artemis Moon Pod Essay Contest – a nationwide event involving nearly 14,000 students – for their creative visions of a pioneering journey to the Moon. The grand prize was a trip to Kennedy to watch the launch of Artemis I. Gutierrez, 17, is an 11th-grader from Lincoln, Nebraska, while Saurer, 14, is an eighth-grader from Laguna Beach, California.

From left to right, NASA astronaut candidates Anil Menon, Deniz Burnham, and Marcos Berrios, and NASA astronaut Zena Cardman pose for a photograph in front of NASA’s Artemis I Space Launch System and Orion spacecraft atop the mobile launcher on the pad at Launch Complex 39B at the agency’s Kennedy Space Center in Florida on Sept. 2, 2022. The first in a series of increasingly complex missions, Artemis I will provide a foundation for human deep space exploration and demonstrate our commitment and capability to extend human presence to the Moon and beyond. The primary goal of Artemis I is to thoroughly test the integrated systems before crewed missions by operating the spacecraft in a deep space environment, testing Orion’s heat shield, and recovering the crew module after reentry, descent, and splashdown. In later missions, NASA will land the first woman and the first person of color on the surface of the Moon, paving the way for a long-term lunar presence and serving as a steppingstone on the way to Mars.

Teams move a liquid hydrogen tank for NASA’s SLS (Space Launch System) rocket out of a priming cell and into an adjacent cell on May 20 at the agency’s Michoud Assembly Facility in New Orleans. Inside the cell, the tank, which will be used on the core stage of NASA’s Artemis III mission, will receive its thermal protection system. The thermal protection system, or spray-on foam insulation, provides protection to the core stage during launch. It is flexible enough to move with the rocket yet can withstand the aerodynamic pressures as the SLS accelerates from 0 to 17,500 mph and soars to more than 100 miles above the Earth. This third-generation insulation is more environmentally friendly and keeps the cryogenic propellant, which powers the rocket’s four RS-25 engines, extremely cold (the liquid hydrogen must remain at minus 423 degrees Fahrenheit/253 degrees Celsius) to remain in its liquid state. When applied the thermal protection system is a light-yellow color, which “tans” once exposed to the Sun’s ultraviolet rays, giving the SLS core stage its signature orange color.

These photos and videos show how technicians at NASA’s Michoud Assembly Facility in New Orleans installed the third and fourth RS-25 engines onto the core stage for the agency’s SLS (Space Launch System) rocket that will help power NASA’s first crewed Artemis mission to the Moon. Technicians added the first engine to the SLS core stage Sept. 11. The second engine was installed onto the stage Sept. 15 with the third and fourth engines following Sept. 19 and Sept. 20. Engineers consider the engines to be “soft” mated to the rocket stage. Technicians with NASA, Aerojet Rocketdyne, an L3Harris Technologies company and the RS-25 engines lead contractor, along with Boeing, the core stage lead contractor, will now focus efforts on the complex tax of fully securing the engines to the stage and integrating the propulsion and electrical systems within the structure. NASA is working to land the first woman and first person of color on the Moon under Artemis. SLS is part of NASA’s backbone for deep space exploration, along with Orion and the Gateway in orbit around the Moon. SLS is the only rocket that can send Orion, astronauts, and supplies to the Moon in a single mission.

These photos and videos show teams at NASA’s Michoud Assembly Facility in New Orleans preparing, moving, and loading the engine section of a future SLS (Space Launch System) rocket to NASA’s Pegasus barge Aug. 28. The hardware will form the bottom-most section of the SLS core stage that will power NASA’s Artemis IV mission, which will be the first mission to the Gateway space station in lunar orbit under the Artemis campaign. The barge will transport the spaceflight hardware to NASA’s Kennedy Space Center in Florida via the agency’s Pegasus barge. Once in Florida, the engine section will undergo final outfitting inside Kennedy’s Space Station Processing Facility.

NASA astronaut Anne McClain poses for a photograph in front of NASA’s Artemis I Space Launch System and Orion spacecraft atop the mobile launcher on the pad at Launch Complex 39B at the agency’s Kennedy Space Center in Florida on Sept. 2, 2022. The first in a series of increasingly complex missions, Artemis I will provide a foundation for human deep space exploration and demonstrate our commitment and capability to extend human presence to the Moon and beyond. The primary goal of Artemis I is to thoroughly test the integrated systems before crewed missions by operating the spacecraft in a deep space environment, testing Orion’s heat shield, and recovering the crew module after reentry, descent, and splashdown. In later missions, NASA will land the first woman and the first person of color on the surface of the Moon, paving the way for a long-term lunar presence and serving as a steppingstone on the way to Mars.

A group of young children with an Artemis flag are photographed on the Max Brewer Bridge in Titusville, Florida, as they wait to watch the launch of NASA’s Artemis I mission on Sept. 3, 2022. The launch was waived off for the day. The first in a series of increasingly complex missions, Artemis I will provide a foundation for human deep space exploration and demonstrate our commitment and capability to extend human presence to the Moon and beyond. The primary goal of Artemis I is to thoroughly test the integrated systems before crewed missions by operating the spacecraft in a deep space environment, testing Orion’s heat shield, and recovering the crew module after reentry, descent, and splashdown.

A family wearing matching Artemis shirts are on the Max Brewer Bridge in Titusville, Florida, to witness the launch of NASA’s Artemis I mission on Sept. 3, 2022. The launch was waived off for the day. The first in a series of increasingly complex missions, Artemis I will provide a foundation for human deep space exploration and demonstrate our commitment and capability to extend human presence to the Moon and beyond. The primary goal of Artemis I is to thoroughly test the integrated systems before crewed missions by operating the spacecraft in a deep space environment, testing Orion’s heat shield, and recovering the crew module after reentry, descent, and splashdown.

NASA astronaut candidate Marcos Berrios poses for a photograph in front of NASA’s Artemis I Space Launch System and Orion spacecraft atop the mobile launcher on the pad at Launch Complex 39B at the agency’s Kennedy Space Center in Florida on Sept. 2, 2022. The first in a series of increasingly complex missions, Artemis I will provide a foundation for human deep space exploration and demonstrate our commitment and capability to extend human presence to the Moon and beyond. The primary goal of Artemis I is to thoroughly test the integrated systems before crewed missions by operating the spacecraft in a deep space environment, testing Orion’s heat shield, and recovering the crew module after reentry, descent, and splashdown. In later missions, NASA will land the first woman and the first person of color on the surface of the Moon, paving the way for a long-term lunar presence and serving as a steppingstone on the way to Mars.

Rachel Kraft, NASA Communications, moderates a prelaunch media briefing following a mission management team meeting for Artemis I on Sept. 1, 2022, at NASA’s Kennedy Space Center in Florida. Artemis I is scheduled to launch at 2:17 p.m. EDT on Sept. 3, from Kennedy’s Launch Complex 39B. Launch was waved off on Aug. 29 due to an issue during tanking. The first in a series of increasingly complex missions, Artemis I will provide a foundation for human deep space exploration and demonstrate NASA’s capability to extend human presence to the Moon and beyond. The primary goal of Artemis I is to thoroughly test the integrated systems before crewed missions by operating the spacecraft in a deep space environment, testing Orion’s heat shield, and recovering the crew module after reentry, descent, and splashdown.

Teams at NASA’s Michoud Assembly Facility in New Orleans move a liquid hydrogen tank for the agency’s SLS (Space Launch System) rocket into the factory’s final assembly area on April 22. Having recently completed application of the thermal protection system, teams will now continue outfitting the 130-foot-tall tank with critical systems to ready it for its designated Artemis III mission. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce more than two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

Teams at NASA’s Michoud Assembly Facility in New Orleans move the engine section flight hardware to the agency’s Pegasus barge Sunday, Dec. 4. The barge will ferry the engine section of NASA’s Space Launch System (SLS) rocket for Artemis III to the agency’s Kennedy Space Center in Florida. Once there, teams at Kennedy will finish outfitting the engine section, which comprises the tail-end of the rocket’s 212-foot-tall core stage, before integrating it to the rest of the stage. Beginning with production for Artemis III, NASA and core stage lead contractor Boeing will use Michoud, where the SLS core stages are currently manufactured, to produce and outfit the core stage’s five elements, and available space at Kennedy for final assembly and integration.

Artemis I managers hold a final briefing on Aug. 26, 2022, at NASA’s Kennedy Space Center in Florida to confirm all is ready for launch team call to stations in Firing Room 1 of the Rocco A Petrone Launch Control Center. The agency’s Space Launch System rocket and Orion spacecraft are scheduled to launch no earlier than Aug. 29, 2022, at 8:33 a.m. EDT from Kennedy’s Launch Complex 39B. The first in a series of increasingly complex missions, Artemis I will provide a foundation for human deep space exploration and demonstrate our commitment and capability to extend human presence to the Moon and beyond. The primary goal of Artemis I is to thoroughly test the integrated systems before crewed missions by operating the spacecraft in a deep space environment, testing Orion’s heat shield, and recovering the crew module after reentry, descent, and splashdown.

From left to right, NASA astronaut candidates Anil Menon, Deniz Burnham, and Marcos Berrios pose for a photograph in front of NASA’s Artemis I Space Launch System and Orion spacecraft atop the mobile launcher on the pad at Launch Complex 39B at the agency’s Kennedy Space Center in Florida on Sept. 2, 2022. The first in a series of increasingly complex missions, Artemis I will provide a foundation for human deep space exploration and demonstrate our commitment and capability to extend human presence to the Moon and beyond. The primary goal of Artemis I is to thoroughly test the integrated systems before crewed missions by operating the spacecraft in a deep space environment, testing Orion’s heat shield, and recovering the crew module after reentry, descent, and splashdown. In later missions, NASA will land the first woman and the first person of color on the surface of the Moon, paving the way for a long-term lunar presence and serving as a steppingstone on the way to Mars.

Teams move a liquid hydrogen tank for NASA’s SLS (Space Launch System) rocket out of a priming cell and into an adjacent cell on May 20 at the agency’s Michoud Assembly Facility in New Orleans. Inside the cell, the tank, which will be used on the core stage of NASA’s Artemis III mission, will receive its thermal protection system. The thermal protection system, or spray-on foam insulation, provides protection to the core stage during launch. It is flexible enough to move with the rocket yet can withstand the aerodynamic pressures as the SLS accelerates from 0 to 17,500 mph and soars to more than 100 miles above the Earth. This third-generation insulation is more environmentally friendly and keeps the cryogenic propellant, which powers the rocket’s four RS-25 engines, extremely cold (the liquid hydrogen must remain at minus 423 degrees Fahrenheit/253 degrees Celsius) to remain in its liquid state. When applied the thermal protection system is a light-yellow color, which “tans” once exposed to the Sun’s ultraviolet rays, giving the SLS core stage its signature orange color.

Teams move a liquid hydrogen tank for NASA’s SLS (Space Launch System) rocket out of a priming cell and into an adjacent cell on May 20 at the agency’s Michoud Assembly Facility in New Orleans. Inside the cell, the tank, which will be used on the core stage of NASA’s Artemis III mission, will receive its thermal protection system. The thermal protection system, or spray-on foam insulation, provides protection to the core stage during launch. It is flexible enough to move with the rocket yet can withstand the aerodynamic pressures as the SLS accelerates from 0 to 17,500 mph and soars to more than 100 miles above the Earth. This third-generation insulation is more environmentally friendly and keeps the cryogenic propellant, which powers the rocket’s four RS-25 engines, extremely cold (the liquid hydrogen must remain at minus 423 degrees Fahrenheit/253 degrees Celsius) to remain in its liquid state. When applied the thermal protection system is a light-yellow color, which “tans” once exposed to the Sun’s ultraviolet rays, giving the SLS core stage its signature orange color.

A young child waving an Artemis flag poses with members of the Titusville Police Dept. on the Max Brewer Bridge on Aug. 29, 2022, during Artemis I countdown festivities. The launch was waved off for the day at the agency’s Kennedy Space Center. The first in a series of increasingly complex missions, Artemis I will provide a foundation for human deep space exploration and demonstrate our commitment and capability to extend human presence to the Moon and beyond. The primary goal of Artemis I is to thoroughly test the integrated systems before crewed missions by operating the spacecraft in a deep space environment, testing Orion’s heat shield, and recovering the crew module after reentry, descent, and splashdown.

NASA astronauts and astronaut candidates view NASA’s Artemis I Space Launch System and Orion spacecraft atop the mobile launcher on the pad at Launch Complex 39B at the agency’s Kennedy Space Center in Florida on Sept. 2, 2022. The astronauts are, from left to right: Zena Cardman, NASA astronaut; Deniz Burnham and Anil Menon, NASA astronaut candidates; Anne McClain, NASA astronaut; Marcos Berrios, NASA astronaut candidate; and Victor Glover, NASA astronaut. The first in a series of increasingly complex missions, Artemis I will provide a foundation for human deep space exploration and demonstrate our commitment and capability to extend human presence to the Moon and beyond. The primary goal of Artemis I is to thoroughly test the integrated systems before crewed missions by operating the spacecraft in a deep space environment, testing Orion’s heat shield, and recovering the crew module after reentry, descent, and splashdown. In later missions, NASA will land the first woman and the first person of color on the surface of the Moon, paving the way for a long-term lunar presence and serving as a steppingstone on the way to Mars.

Teams at NASA’s Michoud Assembly Facility in New Orleans move the engine section flight hardware to the agency’s Pegasus barge Sunday, Dec. 4. The barge will ferry the engine section of NASA’s Space Launch System (SLS) rocket for Artemis III to the agency’s Kennedy Space Center in Florida. Once there, teams at Kennedy will finish outfitting the engine section, which comprises the tail-end of the rocket’s 212-foot-tall core stage, before integrating it to the rest of the stage. Beginning with production for Artemis III, NASA and core stage lead contractor Boeing will use Michoud, where the SLS core stages are currently manufactured, to produce and outfit the core stage’s five elements, and available space at Kennedy for final assembly and integration.

NASA astronauts and astronaut candidates view NASA’s Artemis I Space Launch System and Orion spacecraft atop the mobile launcher on the pad at Launch Complex 39B at the agency’s Kennedy Space Center in Florida on Sept. 2, 2022. The astronauts are, from left to right: Zena Cardman (partially obscured), NASA astronaut; Deniz Burnham and Anil Menon, NASA astronaut candidates; Anne McClain, NASA astronaut; Marcos Berrios, NASA astronaut candidate; and Victor Glover, NASA astronaut. The first in a series of increasingly complex missions, Artemis I will provide a foundation for human deep space exploration and demonstrate our commitment and capability to extend human presence to the Moon and beyond. The primary goal of Artemis I is to thoroughly test the integrated systems before crewed missions by operating the spacecraft in a deep space environment, testing Orion’s heat shield, and recovering the crew module after reentry, descent, and splashdown. In later missions, NASA will land the first woman and the first person of color on the surface of the Moon, paving the way for a long-term lunar presence and serving as a steppingstone on the way to Mars.

Teams move a liquid hydrogen tank for NASA’s SLS (Space Launch System) rocket out of a priming cell and into an adjacent cell on May 20 at the agency’s Michoud Assembly Facility in New Orleans. Inside the cell, the tank, which will be used on the core stage of NASA’s Artemis III mission, will receive its thermal protection system. The thermal protection system, or spray-on foam insulation, provides protection to the core stage during launch. It is flexible enough to move with the rocket yet can withstand the aerodynamic pressures as the SLS accelerates from 0 to 17,500 mph and soars to more than 100 miles above the Earth. This third-generation insulation is more environmentally friendly and keeps the cryogenic propellant, which powers the rocket’s four RS-25 engines, extremely cold (the liquid hydrogen must remain at minus 423 degrees Fahrenheit/253 degrees Celsius) to remain in its liquid state. When applied the thermal protection system is a light-yellow color, which “tans” once exposed to the Sun’s ultraviolet rays, giving the SLS core stage its signature orange color.

These photos and videos show how technicians at NASA’s Michoud Assembly Facility in New Orleans installed the third and fourth RS-25 engines onto the core stage for the agency’s SLS (Space Launch System) rocket that will help power NASA’s first crewed Artemis mission to the Moon. Technicians added the first engine to the SLS core stage Sept. 11. The second engine was installed onto the stage Sept. 15 with the third and fourth engines following Sept. 19 and Sept. 20. Engineers consider the engines to be “soft” mated to the rocket stage. Technicians with NASA, Aerojet Rocketdyne, an L3Harris Technologies company and the RS-25 engines lead contractor, along with Boeing, the core stage lead contractor, will now focus efforts on the complex tax of fully securing the engines to the stage and integrating the propulsion and electrical systems within the structure. NASA is working to land the first woman and first person of color on the Moon under Artemis. SLS is part of NASA’s backbone for deep space exploration, along with Orion and the Gateway in orbit around the Moon. SLS is the only rocket that can send Orion, astronauts, and supplies to the Moon in a single mission.

These photos and videos show how technicians at NASA’s Michoud Assembly Facility in New Orleans installed the third and fourth RS-25 engines onto the core stage for the agency’s SLS (Space Launch System) rocket that will help power NASA’s first crewed Artemis mission to the Moon. Technicians added the first engine to the SLS core stage Sept. 11. The second engine was installed onto the stage Sept. 15 with the third and fourth engines following Sept. 19 and Sept. 20. Engineers consider the engines to be “soft” mated to the rocket stage. Technicians with NASA, Aerojet Rocketdyne, an L3Harris Technologies company and the RS-25 engines lead contractor, along with Boeing, the core stage lead contractor, will now focus efforts on the complex tax of fully securing the engines to the stage and integrating the propulsion and electrical systems within the structure. NASA is working to land the first woman and first person of color on the Moon under Artemis. SLS is part of NASA’s backbone for deep space exploration, along with Orion and the Gateway in orbit around the Moon. SLS is the only rocket that can send Orion, astronauts, and supplies to the Moon in a single mission.

Charlie Blackwell-Thompson, Artemis I launch director, participates in a prelaunch media briefing following a mission management team meeting for Artemis I on Sept. 1, 2022, at NASA’s Kennedy Space Center in Florida. Artemis I is scheduled to launch at 2:17 p.m. EDT on Sept. 3, from Kennedy’s Launch Complex 39B. Launch was waved off on Aug. 29 due to an issue during tanking. The first in a series of increasingly complex missions, Artemis I will provide a foundation for human deep space exploration and demonstrate NASA’s capability to extend human presence to the Moon and beyond. The primary goal of Artemis I is to thoroughly test the integrated systems before crewed missions by operating the spacecraft in a deep space environment, testing Orion’s heat shield, and recovering the crew module after reentry, descent, and splashdown.

Teams at NASA’s Michoud Assembly Facility in New Orleans move a liquid hydrogen tank for the agency’s SLS (Space Launch System) rocket into the factory’s final assembly area on April 22. Having recently completed application of the thermal protection system, teams will now continue outfitting the 130-foot-tall tank with critical systems to ready it for its designated Artemis III mission. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce more than two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

John Honeycutt, Space Launch System program manager, participates in a prelaunch media briefing following a mission management team meeting for Artemis I on Sept. 1, 2022, at NASA’s Kennedy Space Center in Florida. Artemis I is scheduled to launch at 2:17 p.m. EDT on Sept. 3, from Kennedy’s Launch Complex 39B. Launch was waved off on Aug. 29 due to an issue during tanking. The first in a series of increasingly complex missions, Artemis I will provide a foundation for human deep space exploration and demonstrate NASA’s capability to extend human presence to the Moon and beyond. The primary goal of Artemis I is to thoroughly test the integrated systems before crewed missions by operating the spacecraft in a deep space environment, testing Orion’s heat shield, and recovering the crew module after reentry, descent, and splashdown.

These photos and videos show teams at NASA’s Michoud Assembly Facility in New Orleans preparing, moving, and loading the engine section of a future SLS (Space Launch System) rocket to NASA’s Pegasus barge Aug. 28. The hardware will form the bottom-most section of the SLS core stage that will power NASA’s Artemis IV mission, which will be the first mission to the Gateway space station in lunar orbit under the Artemis campaign. The barge will transport the spaceflight hardware to NASA’s Kennedy Space Center in Florida via the agency’s Pegasus barge. Once in Florida, the engine section will undergo final outfitting inside Kennedy’s Space Station Processing Facility.

Teams at NASA’s Michoud Assembly Facility in New Orleans move a liquid hydrogen tank for the agency’s SLS (Space Launch System) rocket into the factory’s final assembly area on April 22. Having recently completed application of the thermal protection system, teams will now continue outfitting the 130-foot-tall tank with critical systems to ready it for its designated Artemis III mission. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce more than two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

Teams at NASA’s Michoud Assembly Facility in New Orleans move a liquid hydrogen tank for the agency’s SLS (Space Launch System) rocket into the factory’s final assembly area on April 22. Having recently completed application of the thermal protection system, teams will now continue outfitting the 130-foot-tall tank with critical systems to ready it for its designated Artemis III mission. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce more than two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

NASA astronaut candidate Deniz Burnham poses for a photograph in front of NASA’s Artemis I Space Launch System and Orion spacecraft atop the mobile launcher on the pad at Launch Complex 39B at the agency’s Kennedy Space Center in Florida on Sept. 2, 2022. The first in a series of increasingly complex missions, Artemis I will provide a foundation for human deep space exploration and demonstrate our commitment and capability to extend human presence to the Moon and beyond. The primary goal of Artemis I is to thoroughly test the integrated systems before crewed missions by operating the spacecraft in a deep space environment, testing Orion’s heat shield, and recovering the crew module after reentry, descent, and splashdown. In later missions, NASA will land the first woman and the first person of color on the surface of the Moon, paving the way for a long-term lunar presence and serving as a steppingstone on the way to Mars.

These images/video show how teams rolled out, or moved, the completed core stage for NASA’s Space Launch System rocket from NASA’s Michoud Assembly Facility in New Orleans. Crews moved the flight hardware for the first Artemis mission to NASA’s Pegasus barge on Jan. 8 in preparation for the core stage Green Run test series at NASA’s Stennis Space Center near Bay St. Louis, Mississippi. Pegasus, which was modified to ferry SLS rocket hardware, will transport the core stage from Michoud to Stennis for the comprehensive core stage Green Run test series. Once at Stennis, the Artemis rocket stage will be loaded into the B-2 Test Stand for the core stage Green Run test series. The comprehensive test campaign will progressively bring the entire core stage, including its avionics and engines, to life for the first time to verify the stage is fit for flight ahead of the launch of Artemis I. Assembly and integration of the core stage and its four RS-25 engines has been a collaborative, multistep process for NASA and its partners Boeing, the core stage lead contractor, and Aerojet Rocketdyne, the RS-25 engines lead contractor. Together with four RS-25 engines, the rocket’s massive 212-foot-tall core stage — the largest stage NASA has ever built — and its twin solid rocket boosters will produce 8.8 million pounds of thrust to send NASA’s Orion spacecraft, astronauts and supplies beyond Earth’s orbit to the Moon and, ultimately, Mars. Offering more payload mass, volume capability and energy to speed missions through space, the SLS rocket, along with NASA’s Gateway in lunar orbit and Orion, is part of NASA’s backbone for deep space exploration and the Artemis lunar program.

These images and videos show team members at Michoud Assembly Facility loading the first core stage that will help launch the first crewed flight of NASA’s SLS (Space Launch System) rocket for the agency’s Artemis II mission onto the Pegasus barge on Tuesday, July 16, 2024. The barge will ferry the core stage on a 900-mile journey from the agency’s Michoud Assembly Facility in New Orleans to its Kennedy Space Center in Florida. The core stage for the SLS mega rocket is the largest stage NASA has ever produced. At 212 feet tall, the stage consists of five major elements, including two huge propellant tanks that collectively hold more than 733,000 gallons of super chilled liquid propellant to feed four RS-25 engines at its base. During launch and flight, the stage will operate for just over eight minutes, producing more than 2 million pounds of thrust to help send a crew of four astronauts inside NASA’s Orion spacecraft onward to the Moon. All the major structures for every SLS core stage are fully manufactured at NASA Michoud. NASA is working to land the first woman, first person of color, and its first international partner astronaut on the Moon under Artemis. SLS is part of NASA’s backbone for deep space exploration, along with the Orion spacecraft and Gateway in orbit around the Moon and commercial human landing systems, next-generation space, next-generational spacesuits, and rovers on the lunar surface. SLS is the only rocket that can send Orion, astronauts, and supplies to the Moon in a single launch.

Teams move a liquid hydrogen tank for NASA’s SLS (Space Launch System) rocket out of a priming cell and into an adjacent cell on May 20 at the agency’s Michoud Assembly Facility in New Orleans. Inside the cell, the tank, which will be used on the core stage of NASA’s Artemis III mission, will receive its thermal protection system. The thermal protection system, or spray-on foam insulation, provides protection to the core stage during launch. It is flexible enough to move with the rocket yet can withstand the aerodynamic pressures as the SLS accelerates from 0 to 17,500 mph and soars to more than 100 miles above the Earth. This third-generation insulation is more environmentally friendly and keeps the cryogenic propellant, which powers the rocket’s four RS-25 engines, extremely cold (the liquid hydrogen must remain at minus 423 degrees Fahrenheit/253 degrees Celsius) to remain in its liquid state. When applied the thermal protection system is a light-yellow color, which “tans” once exposed to the Sun’s ultraviolet rays, giving the SLS core stage its signature orange color.

Teams at NASA’s Michoud Assembly Facility in New Orleans move a liquid hydrogen tank for the agency’s SLS (Space Launch System) rocket into the factory’s final assembly area on April 22. Having recently completed application of the thermal protection system, teams will now continue outfitting the 130-foot-tall tank with critical systems to ready it for its designated Artemis III mission. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce more than two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

The NASA Michoud Assembly Facility workforce and with other agency team members take a “family photo” with the SLS (Space Launch System) core stage for Artemis II in the background. The core stage will help launch the first crewed flight of NASA’s SLS rocket for the agency’s Artemis II mission. The move marked the first time a fully assembled Moon rocket stage for a crewed mission has rolled out from NASA’s Michoud Assembly Facility in New Orleans since the Apollo Program, The core stage was moved onto the agency’s Pegasus barge, where it will be ferried to NASA’s Kennedy Space Center in Florida. The core stage for the SLS mega rocket is the largest stage NASA has ever produced. At 212 feet tall, the stage consists of five major elements, including two huge propellant tanks that collectively hold more than 733,000 gallons of super chilled liquid propellant to feed four RS-25 engines at its base. During launch and flight, the stage will operate for just over eight minutes, producing more than 2 million pounds of thrust to help send a crew of four astronauts inside NASA’s Orion spacecraft onward to the Moon. NASA is working to land the first woman, first person of color, and its first international partner astronaut on the Moon under Artemis. SLS is part of NASA’s backbone for deep space exploration, along with the Orion spacecraft and Gateway in orbit around the Moon and commercial human landing systems, next-generation space, next-generational spacesuits, and rovers on the lunar surface. SLS is the only rocket that can send Orion, astronauts, and supplies to the Moon in a single launch.

Teams at NASA’s Michoud Assembly Facility in New Orleans move a liquid hydrogen tank for the agency’s SLS (Space Launch System) rocket into the factory’s final assembly area on April 22. Having recently completed application of the thermal protection system, teams will now continue outfitting the 130-foot-tall tank with critical systems to ready it for its designated Artemis III mission. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce more than two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

These photos and videos show teams at NASA’s Michoud Assembly Facility in New Orleans preparing, moving, and loading the engine section of a future SLS (Space Launch System) rocket to NASA’s Pegasus barge Aug. 28. The hardware will form the bottom-most section of the SLS core stage that will power NASA’s Artemis IV mission, which will be the first mission to the Gateway space station in lunar orbit under the Artemis campaign. The barge will transport the spaceflight hardware to NASA’s Kennedy Space Center in Florida via the agency’s Pegasus barge. Once in Florida, the engine section will undergo final outfitting inside Kennedy’s Space Station Processing Facility.

Teams at NASA’s Michoud Assembly Facility in New Orleans move a liquid hydrogen tank for the agency’s SLS (Space Launch System) rocket into the factory’s final assembly area on April 22. Having recently completed application of the thermal protection system, teams will now continue outfitting the 130-foot-tall tank with critical systems to ready it for its designated Artemis III mission. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce more than two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

NASA astronauts and astronaut candidates view NASA’s Artemis I Space Launch System and Orion spacecraft atop the mobile launcher on the pad at Launch Complex 39B at the agency’s Kennedy Space Center in Florida on Sept. 2, 2022. The astronauts are, from left to right: Victor Glover, NASA astronaut; Marcos Berrios, NASA astronaut candidate; Anne McClain, NASA astronaut; Anil Menon and Deniz Burnham, NASA astronaut candidates; and Zena Cardman, NASA astronaut. The first in a series of increasingly complex missions, Artemis I will provide a foundation for human deep space exploration and demonstrate our commitment and capability to extend human presence to the Moon and beyond. The primary goal of Artemis I is to thoroughly test the integrated systems before crewed missions by operating the spacecraft in a deep space environment, testing Orion’s heat shield, and recovering the crew module after reentry, descent, and splashdown. In later missions, NASA will land the first woman and the first person of color on the surface of the Moon, paving the way for a long-term lunar presence and serving as a steppingstone on the way to Mars.

The liquid oxygen tank for NASA’s SLS (Space Launch System) rocket core stage for the Artemis III mission is lifted into a production cell at the agency’s Michoud Assembly Facility in New Orleans on Nov. 7. Move crews use an overhead crane system to lift the tank from the mobile transporter, which carried it from another area of the factory and set it atop the previously loaded intertank. Once the liquid oxygen tank is mated to the intertank, team will mate the stage’s forward skirt atop the tank to complete the forward join. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce more than two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

The liquid oxygen tank for NASA’s SLS (Space Launch System) rocket core stage for the Artemis III mission is lifted into a production cell at the agency’s Michoud Assembly Facility in New Orleans on Nov. 7. Move crews use an overhead crane system to lift the tank from the mobile transporter, which carried it from another area of the factory and set it atop the previously loaded intertank. Once the liquid oxygen tank is mated to the intertank, team will mate the stage’s forward skirt atop the tank to complete the forward join. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce more than two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

The liquid oxygen tank for NASA’s SLS (Space Launch System) rocket core stage for the Artemis III mission is lifted into a production cell at the agency’s Michoud Assembly Facility in New Orleans on Nov. 7. Move crews use an overhead crane system to lift the tank from the mobile transporter, which carried it from another area of the factory and set it atop the previously loaded intertank. Once the liquid oxygen tank is mated to the intertank, team will mate the stage’s forward skirt atop the tank to complete the forward join. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce more than two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

The liquid oxygen tank for NASA’s SLS (Space Launch System) rocket core stage for the Artemis III mission is lifted into a production cell at the agency’s Michoud Assembly Facility in New Orleans on Nov. 7. Move crews use an overhead crane system to lift the tank from the mobile transporter, which carried it from another area of the factory and set it atop the previously loaded intertank. Once the liquid oxygen tank is mated to the intertank, team will mate the stage’s forward skirt atop the tank to complete the forward join. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce more than two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

The liquid oxygen tank for NASA’s SLS (Space Launch System) rocket core stage for the Artemis III mission is lifted into a production cell at the agency’s Michoud Assembly Facility in New Orleans on Nov. 7. Move crews use an overhead crane system to lift the tank from the mobile transporter, which carried it from another area of the factory and set it atop the previously loaded intertank. Once the liquid oxygen tank is mated to the intertank, team will mate the stage’s forward skirt atop the tank to complete the forward join. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce more than two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

The liquid oxygen tank for NASA’s SLS (Space Launch System) rocket core stage for the Artemis III mission is lifted into a production cell at the agency’s Michoud Assembly Facility in New Orleans on Nov. 7. Move crews use an overhead crane system to lift the tank from the mobile transporter, which carried it from another area of the factory and set it atop the previously loaded intertank. Once the liquid oxygen tank is mated to the intertank, team will mate the stage’s forward skirt atop the tank to complete the forward join. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce more than two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

The liquid oxygen tank for NASA’s SLS (Space Launch System) rocket core stage for the Artemis III mission is lifted into a production cell at the agency’s Michoud Assembly Facility in New Orleans on Nov. 7. Move crews use an overhead crane system to lift the tank from the mobile transporter, which carried it from another area of the factory and set it atop the previously loaded intertank. Once the liquid oxygen tank is mated to the intertank, team will mate the stage’s forward skirt atop the tank to complete the forward join. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce more than two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

The liquid oxygen tank for NASA’s SLS (Space Launch System) rocket core stage for the Artemis III mission is lifted into a production cell at the agency’s Michoud Assembly Facility in New Orleans on Nov. 7. Move crews use an overhead crane system to lift the tank from the mobile transporter, which carried it from another area of the factory and set it atop the previously loaded intertank. Once the liquid oxygen tank is mated to the intertank, team will mate the stage’s forward skirt atop the tank to complete the forward join. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce more than two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

The liquid oxygen tank for NASA’s SLS (Space Launch System) rocket core stage for the Artemis III mission is lifted into a production cell at the agency’s Michoud Assembly Facility in New Orleans on Nov. 7. Move crews use an overhead crane system to lift the tank from the mobile transporter, which carried it from another area of the factory and set it atop the previously loaded intertank. Once the liquid oxygen tank is mated to the intertank, team will mate the stage’s forward skirt atop the tank to complete the forward join. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce more than two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

The liquid oxygen tank for NASA’s SLS (Space Launch System) rocket core stage for the Artemis III mission is lifted into a production cell at the agency’s Michoud Assembly Facility in New Orleans on Nov. 7. Move crews use an overhead crane system to lift the tank from the mobile transporter, which carried it from another area of the factory and set it atop the previously loaded intertank. Once the liquid oxygen tank is mated to the intertank, team will mate the stage’s forward skirt atop the tank to complete the forward join. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce more than two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

The liquid oxygen tank for NASA’s SLS (Space Launch System) rocket core stage for the Artemis III mission is lifted into a production cell at the agency’s Michoud Assembly Facility in New Orleans on Nov. 7. Move crews use an overhead crane system to lift the tank from the mobile transporter, which carried it from another area of the factory and set it atop the previously loaded intertank. Once the liquid oxygen tank is mated to the intertank, team will mate the stage’s forward skirt atop the tank to complete the forward join. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce more than two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

The liquid oxygen tank for NASA’s SLS (Space Launch System) rocket core stage for the Artemis III mission is lifted into a production cell at the agency’s Michoud Assembly Facility in New Orleans on Nov. 7. Move crews use an overhead crane system to lift the tank from the mobile transporter, which carried it from another area of the factory and set it atop the previously loaded intertank. Once the liquid oxygen tank is mated to the intertank, team will mate the stage’s forward skirt atop the tank to complete the forward join. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce more than two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

The liquid oxygen tank for NASA’s SLS (Space Launch System) rocket core stage for the Artemis III mission is lifted into a production cell at the agency’s Michoud Assembly Facility in New Orleans on Nov. 7. Move crews use an overhead crane system to lift the tank from the mobile transporter, which carried it from another area of the factory and set it atop the previously loaded intertank. Once the liquid oxygen tank is mated to the intertank, team will mate the stage’s forward skirt atop the tank to complete the forward join. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce more than two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

The liquid oxygen tank for NASA’s SLS (Space Launch System) rocket core stage for the Artemis III mission is lifted into a production cell at the agency’s Michoud Assembly Facility in New Orleans on Nov. 7. Move crews use an overhead crane system to lift the tank from the mobile transporter, which carried it from another area of the factory and set it atop the previously loaded intertank. Once the liquid oxygen tank is mated to the intertank, team will mate the stage’s forward skirt atop the tank to complete the forward join. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce more than two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

The liquid oxygen tank for NASA’s SLS (Space Launch System) rocket core stage for the Artemis III mission is lifted into a production cell at the agency’s Michoud Assembly Facility in New Orleans on Nov. 7. Move crews use an overhead crane system to lift the tank from the mobile transporter, which carried it from another area of the factory and set it atop the previously loaded intertank. Once the liquid oxygen tank is mated to the intertank, team will mate the stage’s forward skirt atop the tank to complete the forward join. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce more than two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

The liquid oxygen tank for NASA’s SLS (Space Launch System) rocket core stage for the Artemis III mission is lifted into a production cell at the agency’s Michoud Assembly Facility in New Orleans on Nov. 7. Move crews use an overhead crane system to lift the tank from the mobile transporter, which carried it from another area of the factory and set it atop the previously loaded intertank. Once the liquid oxygen tank is mated to the intertank, team will mate the stage’s forward skirt atop the tank to complete the forward join. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce more than two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

The liquid oxygen tank for NASA’s SLS (Space Launch System) rocket core stage for the Artemis III mission is lifted into a production cell at the agency’s Michoud Assembly Facility in New Orleans on Nov. 7. Move crews use an overhead crane system to lift the tank from the mobile transporter, which carried it from another area of the factory and set it atop the previously loaded intertank. Once the liquid oxygen tank is mated to the intertank, team will mate the stage’s forward skirt atop the tank to complete the forward join. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce more than two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

The liquid oxygen tank for NASA’s SLS (Space Launch System) rocket core stage for the Artemis III mission is lifted into a production cell at the agency’s Michoud Assembly Facility in New Orleans on Nov. 7. Move crews use an overhead crane system to lift the tank from the mobile transporter, which carried it from another area of the factory and set it atop the previously loaded intertank. Once the liquid oxygen tank is mated to the intertank, team will mate the stage’s forward skirt atop the tank to complete the forward join. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce more than two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

The liquid oxygen tank for NASA’s SLS (Space Launch System) rocket core stage for the Artemis III mission is lifted into a production cell at the agency’s Michoud Assembly Facility in New Orleans on Nov. 7. Move crews use an overhead crane system to lift the tank from the mobile transporter, which carried it from another area of the factory and set it atop the previously loaded intertank. Once the liquid oxygen tank is mated to the intertank, team will mate the stage’s forward skirt atop the tank to complete the forward join. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce more than two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

The liquid oxygen tank for NASA’s SLS (Space Launch System) rocket core stage for the Artemis III mission is lifted into a production cell at the agency’s Michoud Assembly Facility in New Orleans on Nov. 7. Move crews use an overhead crane system to lift the tank from the mobile transporter, which carried it from another area of the factory and set it atop the previously loaded intertank. Once the liquid oxygen tank is mated to the intertank, team will mate the stage’s forward skirt atop the tank to complete the forward join. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce more than two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

The liquid oxygen tank for NASA’s SLS (Space Launch System) rocket core stage for the Artemis III mission is lifted into a production cell at the agency’s Michoud Assembly Facility in New Orleans on Nov. 7. Move crews use an overhead crane system to lift the tank from the mobile transporter, which carried it from another area of the factory and set it atop the previously loaded intertank. Once the liquid oxygen tank is mated to the intertank, team will mate the stage’s forward skirt atop the tank to complete the forward join. The propellant tank is one of five major elements that make up the 212-foot-tall rocket stage. The core stage, along with its four RS-25 engines, produce more than two million pounds of thrust to help launch NASA’s Orion spacecraft, astronauts, and supplies beyond Earth’s orbit and to the lunar surface for Artemis.

Teams move a liquid hydrogen tank for NASA’s SLS (Space Launch System) rocket out of a priming cell and into an adjacent cell on May 20 at the agency’s Michoud Assembly Facility in New Orleans. Inside the cell, the tank, which will be used on the core stage of NASA’s Artemis III mission, will receive its thermal protection system. The thermal protection system, or spray-on foam insulation, provides protection to the core stage during launch. It is flexible enough to move with the rocket yet can withstand the aerodynamic pressures as the SLS accelerates from 0 to 17,500 mph and soars to more than 100 miles above the Earth. This third-generation insulation is more environmentally friendly and keeps the cryogenic propellant, which powers the rocket’s four RS-25 engines, extremely cold (the liquid hydrogen must remain at minus 423 degrees Fahrenheit/253 degrees Celsius) to remain in its liquid state. When applied the thermal protection system is a light-yellow color, which “tans” once exposed to the Sun’s ultraviolet rays, giving the SLS core stage its signature orange color.

These photos and videos show teams at NASA’s Michoud Assembly Facility in New Orleans preparing, moving, and loading the engine section of a future SLS (Space Launch System) rocket to NASA’s Pegasus barge Aug. 28. The hardware will form the bottom-most section of the SLS core stage that will power NASA’s Artemis IV mission, which will be the first mission to the Gateway space station in lunar orbit under the Artemis campaign. The barge will transport the spaceflight hardware to NASA’s Kennedy Space Center in Florida via the agency’s Pegasus barge. Once in Florida, the engine section will undergo final outfitting inside Kennedy’s Space Station Processing Facility.

Student essay winners Amanda Gutierrez, left, and Taia Saurer pose with NASA astronaut Anne McClain at the agency’s news center at Kennedy Space Center in Florida on Sept. 2, 2022. Gutierrez and Saurer won the Artemis Moon Pod Essay Contest – a nationwide event involving nearly 14,000 students – for their creative visions of a pioneering journey to the Moon. The grand prize was a trip to Kennedy to watch the launch of Artemis I. Gutierrez, 17, is an 11th-grader from Lincoln, Nebraska, while Saurer, 14, is an eighth-grader from Laguna Beach, California.

John Blevins, Space Launch System chief engineer, participates in a prelaunch media briefing following a mission management team meeting for Artemis I on Sept. 1, 2022, at NASA’s Kennedy Space Center in Florida. Artemis I is scheduled to launch at 2:17 p.m. EDT on Sept. 3, from Kennedy’s Launch Complex 39B. Launch was waved off on Aug. 29 due to an issue during tanking. The first in a series of increasingly complex missions, Artemis I will provide a foundation for human deep space exploration and demonstrate NASA’s capability to extend human presence to the Moon and beyond. The primary goal of Artemis I is to thoroughly test the integrated systems before crewed missions by operating the spacecraft in a deep space environment, testing Orion’s heat shield, and recovering the crew module after reentry, descent, and splashdown.

Artemis I managers gather for a final briefing on Aug. 26, 2022, at NASA’s Kennedy Space Center in Florida to confirm all is ready for launch team call to stations in Firing Room 1 of the Rocco A Petrone Launch Control Center. The agency’s Space Launch System rocket and Orion spacecraft are scheduled to launch no earlier than Aug. 29, 2022, at 8:33 a.m. EDT from Kennedy’s Launch Complex 39B. The first in a series of increasingly complex missions, Artemis I will provide a foundation for human deep space exploration and demonstrate our commitment and capability to extend human presence to the Moon and beyond. The primary goal of Artemis I is to thoroughly test the integrated systems before crewed missions by operating the spacecraft in a deep space environment, testing Orion’s heat shield, and recovering the crew module after reentry, descent, and splashdown.

Teams move a liquid hydrogen tank for NASA’s SLS (Space Launch System) rocket out of a priming cell and into an adjacent cell on May 20 at the agency’s Michoud Assembly Facility in New Orleans. Inside the cell, the tank, which will be used on the core stage of NASA’s Artemis III mission, will receive its thermal protection system. The thermal protection system, or spray-on foam insulation, provides protection to the core stage during launch. It is flexible enough to move with the rocket yet can withstand the aerodynamic pressures as the SLS accelerates from 0 to 17,500 mph and soars to more than 100 miles above the Earth. This third-generation insulation is more environmentally friendly and keeps the cryogenic propellant, which powers the rocket’s four RS-25 engines, extremely cold (the liquid hydrogen must remain at minus 423 degrees Fahrenheit/253 degrees Celsius) to remain in its liquid state. When applied the thermal protection system is a light-yellow color, which “tans” once exposed to the Sun’s ultraviolet rays, giving the SLS core stage its signature orange color.

A prelaunch media briefing is held following a mission management team meeting for Artemis I on Sept. 1, 2022, at NASA’s Kennedy Space Center in Florida. Participants are, from left, John Honeycutt, Space Launch System (SLS) program manager; John Blevins, SLS chief engineer; Charlie Blackwell-Thompson, Artemis launch director; and Melody Lovin, Space Launch Delta 45 weather officer. Artemis I is scheduled to launch at 2:17 p.m. EDT on Sept. 3, from Kennedy’s Launch Complex 39B. Launch was waved off on Aug. 29 due to an issue during tanking. The first in a series of increasingly complex missions, Artemis I will provide a foundation for human deep space exploration and demonstrate NASA’s capability to extend human presence to the Moon and beyond. The primary goal of Artemis I is to thoroughly test the integrated systems before crewed missions by operating the spacecraft in a deep space environment, testing Orion’s heat shield, and recovering the crew module after reentry, descent, and splashdown.

These images and videos show team members at Michoud Assembly Facility loading the first core stage that will help launch the first crewed flight of NASA’s SLS (Space Launch System) rocket for the agency’s Artemis II mission onto the Pegasus barge on Tuesday, July 16, 2024. The barge will ferry the core stage on a 900-mile journey from the agency’s Michoud Assembly Facility in New Orleans to its Kennedy Space Center in Florida. The core stage for the SLS mega rocket is the largest stage NASA has ever produced. At 212 feet tall, the stage consists of five major elements, including two huge propellant tanks that collectively hold more than 733,000 gallons of super chilled liquid propellant to feed four RS-25 engines at its base. During launch and flight, the stage will operate for just over eight minutes, producing more than 2 million pounds of thrust to help send a crew of four astronauts inside NASA’s Orion spacecraft onward to the Moon. All the major structures for every SLS core stage are fully manufactured at NASA Michoud. NASA is working to land the first woman, first person of color, and its first international partner astronaut on the Moon under Artemis. SLS is part of NASA’s backbone for deep space exploration, along with the Orion spacecraft and Gateway in orbit around the Moon and commercial human landing systems, next-generation space, next-generational spacesuits, and rovers on the lunar surface. SLS is the only rocket that can send Orion, astronauts, and supplies to the Moon in a single launch.

Teams at NASA’s Michoud Assembly Facility in New Orleans move the engine section flight hardware to the agency’s Pegasus barge Sunday, Dec. 4. The barge will ferry the engine section of NASA’s Space Launch System (SLS) rocket for Artemis III to the agency’s Kennedy Space Center in Florida. Once there, teams at Kennedy will finish outfitting the engine section, which comprises the tail-end of the rocket’s 212-foot-tall core stage, before integrating it to the rest of the stage. Beginning with production for Artemis III, NASA and core stage lead contractor Boeing will use Michoud, where the SLS core stages are currently manufactured, to produce and outfit the core stage’s five elements, and available space at Kennedy for final assembly and integration.

These photos and videos show teams at NASA’s Michoud Assembly Facility in New Orleans preparing, moving, and loading the engine section of a future SLS (Space Launch System) rocket to NASA’s Pegasus barge Aug. 28. The hardware will form the bottom-most section of the SLS core stage that will power NASA’s Artemis IV mission, which will be the first mission to the Gateway space station in lunar orbit under the Artemis campaign. The barge will transport the spaceflight hardware to NASA’s Kennedy Space Center in Florida via the agency’s Pegasus barge. Once in Florida, the engine section will undergo final outfitting inside Kennedy’s Space Station Processing Facility.