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50 Years Ago: Launch of Skylab 4, The Final Mission to Skylab

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The third and final crewed mission to the Skylab space station, Skylab 4, got underway on Nov. 16, 1973, with a thunderous launch from NASA’s Kennedy Space Center (KSC) in Florida. Docking eight hours later, astronauts Gerald P. Carr, Edward G. Gibson, and William R. Pogue began a planned 56-day mission that program managers extended to a record-breaking 84 days. During their first month, as they adjusted to weightlessness and their new surroundings, they completed the first of four spacewalks. They began an extensive science program, investigating the effects of long-duration spaceflight on human physiology, examining the Sun, conducting observations of the Earth, as well as technology and student-led experiments. They began their systematic observations of recently discovered Comet Kohoutek as it approached the Sun.

Crew patch of the third and final crewed mission to Skylab Photo of the Skylab 4 crew of Gerald P. Carr, Edward G. Gibson, and William R. Pogue Photo of the Skylab 4 backup crew of Vance D. Brand, left, William B. Lenoir, and Don L. Lind
Left: Crew patch of the third and final crewed mission to Skylab. Middle: Official photo of the Skylab 4 crew of Gerald P. Carr, left, Edward G. Gibson, and William R. Pogue. Right: The Skylab 4 backup crew of Vance D. Brand, left, William B. Lenoir, and Don L. Lind.

In January 1972, NASA announced the astronauts it had selected for the Skylab program. For Skylab 4, the third crewed mission and at the time planned to last 56 days, NASA named Carr as commander, Gibson as science pilot, and Pogue as pilot to serve as the prime crew, the first all-rookie prime crew since Gemini VIII in 1966. For the backup crew, NASA designated Vance D. Brand, William B. Lenoir, and Don L. Lind, who also served as the backup crew for Skylab 3. Brand and Lind would serve as the two-person crew for a possible rescue mission.

The S-IB first stage for the Skylab 4 mission’s SA-208 Saturn IB rocket arrives at the Vehicle Assembly Building (VAB) at NASA’s Kennedy Space Center in Florida The two S-IVB second stages for the Skylab 4 SA-208 rocket, right, and the SA-209 Skylab rescue rocket sit side by side in the VAB Image of workers in the VAB stack the second stage onto the first stage for the Skylab 4 Saturn IB
Left: The S-IB first stage for the Skylab 4 mission’s SA-208 Saturn IB rocket arrives at the Vehicle Assembly Building (VAB) at NASA’s Kennedy Space Center in Florida. Middle: The two S-IVB second stages for the Skylab 4 SA-208 rocket, right, and the SA-209 Skylab rescue rocket sit side by side in the VAB. Right: Workers in the VAB stack the second stage onto the first stage for the Skylab 4 Saturn IB.

Preparations at KSC for the Skylab 4 mission began on Nov. 4, 1971, with the arrival of the S-IVB second stage of the SA-208 Saturn IB rocket. Workers placed it in long-term storage in the Vehicle Assembly Building (VAB). The rocket’s S-IB first stage arrived on June 20, 1973. Workers in the VAB mounted it on Mobile Launcher 1 on July 31, adding the second stage later that same day.

Photo of the arrival of the Skylab 4 Command Module (CM), front, and Service Module, partly hidden at left, in the Manned Spacecraft Operations Building (MSOB) at NASA’s Kennedy Space Center in Florida Photo of Skylab 4 astronauts conduct an altitude test aboard their CM in the MSOB Photo of the rollout of the Skylab 4 vehicle from the Vehicle Assembly Building to Launch Pad 39B Photo of workers at Launch Pad 39B replace the eight stabilization fins on the Saturn IB rocket’s first stage
Left: The arrival of the Skylab 4 Command Module (CM), front, and Service Module, partly hidden at left, in the Manned Spacecraft Operations Building (MSOB) at NASA’s Kennedy Space Center in Florida. Middle left: The Skylab 4 astronauts conduct an altitude test aboard their CM in the MSOB. Middle right: Rollout of the Skylab 4 vehicle from the Vehicle Assembly Building to Launch Pad 39B. Right: Workers at Launch Pad 39B replace the eight stabilization fins on the Saturn IB rocket’s first stage.

Meanwhile, Command and Service Module-118 (CSM-118) for the mission arrived in KSC’s Manned Spacecraft and Operations Building (MSOB) on Feb. 10, 1973, where engineers placed it inside a vacuum chamber. The prime and backup crews conducted altitude tests of the CSM in early August. With the thruster problems aboard the Skylab 3 spacecraft docked to the space station, managers accelerated the processing flow for the Skylab 4 vehicle to enable a launch as early as Sept. 9 in case they had to implement a rescue mission. Workers mated CSM-118 to the Saturn rocket on Aug. 10 and rolled the stack to Launch Pad 39B four days later. By this time, the need for a rescue had diminished and the processing flow readjusted to enable a launch on need within nine days until the Skylab 3 splashdown on Sept. 25. Normal processing then resumed for a planned Nov. 9 launch, later adjusted to Nov. 11. Carr, Gibson, and Pogue entered their preflight health stabilization plan quarantine on Oct. 20. On Nov. 6, workers found hairline cracks in the mounting brackets of the Saturn IB’s stabilizing fins, requiring a slip of the launch date to Nov. 16 to complete their replacement at the pad. The Skylab 4 countdown began on Nov. 14, the day after the astronauts arrived at KSC.

Photo of Skylab 4 astronauts William R. Pogue, left, Edward G. Gibson, and Gerald P. Carr training in the Skylab training mockup Photo of Gibson, left, Carr, and Pogue display a model of the Skylab space station at the conclusion of their preflight press conference Photo of Gibson, left, Carr, and Pogue pose in front of a T-38 Talon aircraft at Ellington Air Force Base in Houston prior to their departure for NASA’s Kennedy Space Center in Florida for the launch
Left: Skylab 4 astronauts William R. Pogue, left, Edward G. Gibson, and Gerald P. Carr training in the Skylab training mockup. Middle: Gibson, left, Carr, and Pogue display a model of the Skylab space station at the conclusion of their preflight press conference. Right: Gibson, left, Carr, and Pogue pose in front of a T-38 Talon aircraft at Ellington Air Force Base in Houston prior to their departure for NASA’s Kennedy Space Center in Florida for the launch.

Photo of Skylab 4 astronauts William R. Pogue, left, Edward G. Gibson, and Gerald P. Carr enjoy the traditional prelaunch breakfast Carr, Gibson, and Pogue test the pressure integrity of their spacesuits before launch Photo of Carr, front, Gibson, and Pogue exit crew quarters to board the transfer van for the ride to Launch Pad 39B
Left: Skylab 4 astronauts William R. Pogue, left, Edward G. Gibson, and Gerald P. Carr enjoy the traditional prelaunch breakfast. Middle: Carr, front, Gibson, and Pogue test the pressure integrity of their spacesuits before launch. Right: Carr, front, Gibson, and Pogue exit crew quarters to board the transfer van for the ride to Launch Pad 39B.

Liftoff of Skylab 4
Liftoff of Skylab 4!

The third and final mission to the Skylab space station got underway on Nov. 16, 1973, with a thunderous liftoff from KSC’s Launch Pad 39B. Although officially planned as a 56-day mission for several years, mission managers had confidence of an extension to 84 days and planned accordingly, with the astronauts bringing additional food, supplies, and science experiments.

Photo of Skylab during the rendezvous and docking Three astronaut manikins wear the Skylab 4 crew’s flight overalls
Left: Skylab during the rendezvous and docking. Right: Left by the Skylab 3 crew before their departure from the station, three astronaut manikins wear the Skylab 4 crew’s flight overalls.

Eight hours after launch, and following two unsuccessful attempts, Carr hard docked the spacecraft to the space station. Pogue, who on Earth appeared resistant to all forms of motion sickness, developed a case of space motion sickness during the crew’s first evening, requiring several days to fully recover. This incident along with an overly packed timeline caused the astronauts to fall behind in accomplishing their tasks as they adjusted to weightlessness and learned their way around the large space station. The astronauts spent their first night in space aboard the Command Module, opening the hatch the next morning to begin reactivating Skylab. To their surprise, the station appeared to already have three occupants. As a joke, before they left the station in September, the Skylab 3 crew stuffed their successors’ flight suits with used clothing and left them in strategic places throughout the workshop. Carr, Gibson, and Pogue began settling into the routine aboard Skylab, preparing meals, exercising, and starting the large number of experiments. They continued the science program begun by the previous two Skylab crews, including biomedical investigations on the effects of long-duration space flight on the human body, Earth observations using the Earth Resources Experiment Package (EREP), and solar observations with instruments mounted on the Apollo Telescope Mount (ATM). With the prediction earlier in the year that newly discovered Comet Kohoutek would make its closest approach to the Sun in late December, scientists added cometary observations to the crew’s already busy schedule. The astronauts brought a Far Ultraviolet Electronographic Camera, the backup to the instrument deployed on the Moon during Apollo 16, to Skylab especially for observations of the comet, and used it for cometary photography during two spacewalks added to the mission.

Photo of Edward G. Gibson, left, William R. Pogue, and Gerald P. Carr prepare a meal in the Skylab wardroom Photo of Carr using the Thornton treadmill to exercise Carr “weighs” himself in weightlessness using the body mass measurement device
Left: Edward G. Gibson, left, William R. Pogue, and Gerald P. Carr prepare a meal in the Skylab wardroom. Middle: Carr uses the Thornton treadmill to exercise. Right: Carr “weighs” himself in weightlessness using the body mass measurement device.

One of the lessons learned from the first two Skylab missions indicated that the onboard bicycle ergometer alone did not provide enough exercise to maintain leg and back muscle mass and strength. To remedy this problem, physician and Skylab support astronaut Dr. William E. Thornton designed a makeshift treadmill that the third crew brought with them to the station. The treadmill device consisted of a teflon-coated aluminum plate bolted to the floor of the workshop. Bungee cords attached to the floor and to the ergometer harness supplied the downward force for the back and leg muscles with the astronauts sliding over the teflon-coated plate while walking or jogging in stocking feet. Because the exercise provided quite a strenuous workout, the crew dubbed it “Thornton’s revenge.” They also increased the overall amount of time they spent exercising.

Photo of William R. Pogue replaces film in the Apollo Telescope Mount during the mission’s first spacewalk Gerald P. Carr flies the Astronaut Maneuvering Unit Overall view showing the large volume of the Skylab Orbital Workshop
Left: William R. Pogue replaces film in the Apollo Telescope Mount during the mission’s first spacewalk. Middle: Gerald P. Carr flies the Astronaut Maneuvering Unit. Right: Overall view showing the large volume of the Skylab Orbital Workshop.

In addition to the heavy science experiment load, the astronauts spent the first week in orbit preparing for the first spacewalk of the mission. On Nov. 22, their seventh day in space and also Thanksgiving Day, Gibson and Pogue suited up and stepped outside the space station with Gibson exclaiming, “Boy, if this isn’t the great outdoors.” During this six-hour 33-minute spacewalk, they replaced film canisters in the ATM and deployed an experiment package on the ATM truss. They took photographs with a camera that had originally been intended for the airlock now blocked by the sunshade that the first crew deployed in May to help cool the station. Gibson and Pogue accomplished all the tasks planned for this first spacewalk. Back inside the station, the astronauts settled in for the first Thanksgiving meal in space. For their dinner, Carr selected prime rib, Gibson went with traditional turkey, and Pogue chose chicken.

The S-IB first stage for Saturn-IB SA-209, the Skylab 4 rescue mission, arrives at the Vehicle Assembly Building (VAB) at NASA’s Kennedy Space Center Photo of the S-IVB second stage for SA-209 inside the VAB Workers stack the Command and Service Module CSM-119, the Skylab 4 rescue spacecraft, atop SA-209 Image of the Skylab 4 rescue vehicle at Launch Pad 39B
Left: The S-IB first stage for Saturn-IB SA-209, the Skylab 4 rescue mission, arrives at the Vehicle Assembly Building (VAB) at NASA’s Kennedy Space Center. Middle left: The S-IVB second stage for SA-209 inside the VAB. Middle right: Workers stack the Command and Service Module CSM-119, the Skylab 4 rescue spacecraft, atop SA-209. Right: The Skylab 4 rescue vehicle at Launch Pad 39B.

The inclusion of two docking ports on the Skylab space station enabled an in-flight rescue capability for the first time in human spaceflight history. In case a failure of the docked CSM stranded the onboard three-person crew, a two-person crew would launch in a second Apollo spacecraft specially configured with two extra couches to return all five astronauts. For the first two Skylab missions, the rocket and spacecraft for the subsequent mission served as the potential rescue vehicle. The failure of two Service Module thruster groups during Skylab 3 nearly required the rescue capability. Since Skylab 4 was the final mission, NASA procured an additional Saturn IB rocket, SA-209, and Apollo spacecraft, CSM-119, for the rescue role. The spacecraft arrived at KSC on May 2, 1973, and workers placed it in storage in the MSOB. In September, the backup crew of Brand, Lenoir, and Lind completed altitude chamber tests with the CSM, although only Brand and Lenoir would fly any the rescue mission. The S-IVB second stage for Saturn IB SA-209 arrived at KSC on Jan. 12, 1972, and workers placed it in storage in the VAB. The S-IB first stage arrived on Aug. 20, 1973. Because only one Mobile Launcher included the milkstool to launch a Saturn IB, assembly of the rescue vehicle had to await its return from the launch pad the day after the Skylab 4 liftoff. Assembly of the rocket in the VAB began on Nov. 26, and workers topped the rocket off with the spacecraft four days later. The stacked vehicle rolled out to Launch Pad 39B on Dec. 3 where engineers prepared the vehicle so that after Dec. 20, it could support a launch within nine days, should the need arise. The vehicle remained at the pad until Feb. 14, 1974, six days after the Skylab 4 splashdown.

Gerald P. Carr monitors Edward G. Gibson during a lower body negative pressure test of his cardiovascular system Gibson works out on the bicycle ergometer during a test of his cardiopulmonary function Gibson in the rotating chair to test his vestibular system
Left: Gerald P. Carr monitors Edward G. Gibson during a lower body negative pressure test of his cardiovascular system. Middle: Gibson works out on the bicycle ergometer during a test of his cardiopulmonary function. Right: Gibson in the rotating chair to test his vestibular system.

To add to their packed timeline, one of the station’s three control moment gyros (CMGs) failed the day after the first spacewalk. Skylab used CMGs to control the station’s attitude without expending precious attitude control gas, a non-renewable resource heavily depleted early in the station’s life. Engineers on the ground worked out a plan to control the station’s attitude using only the two working CMGs, thereby enabling completion of the remaining science, especially the Earth resource passes and comet Kohoutek observations. Pogue made the first measurements of Comet Kohoutek on Nov. 23 from inside the station using a photometric camera brought to Skylab especially to observe the comet. The astronauts practiced flying the Astronaut Maneuvering Unit, a precursor of the Manned Maneuvering Unit used during the space shuttle program to retrieve satellites, inside the large dome of the workshop.

Image of Edward G. Gibson at the controls of the Apollo Telescope Mount Image of William R. Pogue, left, and Gerald P. Carr at the control panel for the Earth Resources Experiment package inside the Multiple Docking Adapter
Left: Edward G. Gibson at the controls of the Apollo Telescope Mount. Right: William R. Pogue, left, and Gerald P. Carr at the control panel for the Earth Resources Experiment package inside the Multiple Docking Adapter.

Image of a massive solar flare taken by one of the Apollo Telescope Mount instruments Earth Resources Experiment Package photograph of the San Francisco Bay area Crew handheld photograph of a cyclone in the South Pacific
Left: Image of a massive solar flare taken by one of the Apollo Telescope Mount instruments. Middle: Earth Resources Experiment Package photograph of the San Francisco Bay area. Right: Crew handheld photograph of a cyclone in the South Pacific.

On Dec. 13, the mission’s 28th day, program officials assessed the astronauts’ performance and the status of the station and fully expected that they could complete the nominal 56-day mission and most likely the full 84 days. Despite being overworked and often behind the timeline, Carr, Gibson, and Pogue had already accomplished 84 hours of solar observations, 12 Earth resources passes, 80 photographic and visual Earth observations, all of the scheduled medical experiments, as well as numerous other activities such as student experiments, and science demonstrations. The astronaut’s major concern centered around the timelining process that had not given them time to adjust to their new environment and did not take into account their on-orbit daily routine. Despite the crew sending taped verbal messages to the ground asking for help in fixing these issues, the problem persisted. Skylab 4 Lead Flight Director Neil B. Hutchinson later admitted that the ground team learned many lessons about timelining long duration missions during the first few weeks of Skylab 4.

For more insight into the Skylab 4 mission, read Carr’s, Gibson’s, and Pogue’s oral histories with the JSC History Office.

To be continued …

With special thanks to Ed Hengeveld for his expert contributions on Skylab imagery.

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      The mission will carry out a five-year baseline survey to find at least two-thirds of the unknown NEOs larger than 140 meters (460 feet). These are the objects large enough to cause major regional damage in the event of an Earth impact. By using two heat-sensitive infrared imaging channels, the telescope can also make more accurate measurements of the sizes of NEOs and gain information about their composition, shapes, rotational states, and orbits.
      The mission is tasked by NASA’s Planetary Science Division within the agency’s Science Mission Directorate at NASA Headquarters in Washington. Program oversight is provided by NASA’s Planetary Defense Coordination Office, which was established in 2016 to manage the agency’s ongoing efforts in planetary defense. NASA’s Planetary Missions Program Office at the agency’s Marshall Space Flight Center in Huntsville, Alabama, provides program management for NEO Surveyor. The project is being developed by NASA’s Jet Propulsion Laboratory in Southern California.
      Multiple aerospace and engineering companies are contracted to build the spacecraft and its instrumentation, including BAE Systems SMS (Space & Mission Systems), Space Dynamics Laboratory, and Teledyne. The Laboratory for Atmospheric and Space Physics at the University of Colorado, Boulder, will support operations, and the Infrared Processing and Analysis Center at the California Institute of Technology (Caltech) in Pasadena, California, is responsible for processing survey data and producing the mission’s data products. Caltech manages JPL for NASA. Mission team leadership includes the University of California, Los Angeles. NASA’s Launch Services Program at the agency’s Kennedy Space Center in Florida is responsible for managing the launch service.
      For more information about NEO Surveyor, visit:
      https://science.nasa.gov/mission/neo-surveyor/
      -end-
      Tiernan Doyle / Joshua Finch
      Headquarters, Washington
      202-358-1600 / 202-358-1100
      tiernan.doyle@nasa.gov / joshua.a.finch@nasa.gov
      Patti Bielling
      Kennedy Space Center, Florida
      321-501-7575
      patricia.a.bielling@nasa.gov
      Share
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      Last Updated Feb 21, 2025 LocationNASA Headquarters Related Terms
      Kennedy Space Center Launch Services Office Launch Services Program NEO Surveyor (Near-Earth Object Surveyor Space Telescope) Planetary Defense Coordination Office Planetary Science Division Science Mission Directorate Space Operations Mission Directorate View the full article
    • NASA
      NASA Sets Coverage for Intuitive Machines’ Next Commercial Moon Launch
      By NASA
      Caption: The Intuitive Machines lunar lander that will deliver NASA science and technology to the Moon as part of the agency’s CLPS (Commercial Lunar Payload Services) initiative and Artemis campaign is encapsulated in the fairing of the SpaceX Falcon 9 rocket. Credit: SpaceX Carrying NASA science and technology to the Moon as part of the agency’s CLPS (Commercial Lunar Payload Services) initiative and Artemis campaign, the Intuitive Machines IM-2 mission is targeted to launch no earlier than Wednesday, Feb. 26. The mission will lift off on a SpaceX Falcon 9 rocket from Launch Complex 39A at the agency’s Kennedy Space Center in Florida.

      Live launch coverage will air on NASA+ with prelaunch events starting Tuesday, Feb. 25. Learn how to watch NASA content through a variety of platforms, including social media. Follow all events at:
      https://www.nasa.gov/live
      After the launch, Intuitive Machines’ lunar lander, Athena, will spend approximately one week in transit to the Moon before landing on the lunar surface no earlier than Thursday, March 6. The lander will carry NASA science investigations and technology demonstrations to further our understanding of the Moon’s environment and help prepare for future human missions to the lunar surface, as part of the agency’s Moon to Mars exploration approach. 

      Among the items on Intuitive Machines’ lander, the IM-2 mission will be one of the first on-site demonstrations of resource use on the Moon. A drill and mass spectrometer will measure the potential presence of volatiles or gases from lunar soil in Mons Mouton, a lunar plateau in the Moon’s South Pole. In addition, a passive Laser Retroreflector Array (LRA) on the top deck of the lander will bounce laser light back at any orbiting or incoming spacecraft to give future spacecraft a permanent reference point on the lunar surface. Other technology instruments on this delivery will demonstrate a robust surface communications system and deploy a propulsive drone that can hop across the lunar surface.
      Launching as a rideshare with the IM-2 delivery, NASA’s Lunar Trailblazer spacecraft also will begin its journey to lunar orbit, where it will map the distribution of the different forms of water on the Moon.

      The deadline has passed for media accreditation for in-person coverage of this launch. The agency’s media accreditation policy is available online. More information about media accreditation is available by emailing: ksc-media-accreditat@mail.nasa.gov.

      Full coverage of this mission is as follows (all times Eastern):

      Tuesday, Feb. 25

      11 a.m. – Lunar science and technology media teleconference with the following participants:
      Joel Kearns, deputy associate administrator for exploration, Science Mission Directorate, NASA Headquarters Niki Werkheiser, director, technology maturation, Space Technology Mission Directorate, NASA Headquarters Jackie Quinn, Polar Resources Ice Mining Experiment 1 (PRIME-1) project manager, NASA Kennedy Daniel Cremons, LRA deputy principal investigator, NASA’s Goddard Space Flight Center Bethany Ehlmann, Lunar Trailblazer principal investigator, Caltech Trent Martin, senior vice president, space systems, Intuitive Machines Thierry Klein, president, Bell Labs Solution Research, Nokia Audio of the teleconference will stream live on the agency’s website:
      https://www.nasa.gov/live/
      Media may ask questions via phone only. For the dial-in number and passcode, please contact the Kennedy newsroom no later than 10 a.m. EST Tuesday, Feb. 25, at: ksc-newsroom@mail.nasa.gov.

      Wednesday, Feb. 26


      11:30 a.m. – Lunar delivery readiness media teleconference with the following participants:
      Nicky Fox, associate administrator, Science Mission Directorate, NASA Headquarters Clayton Turner, associate administrator, Space Technology Mission Directorate, NASA Headquarters Trent Martin, senior vice president, space systems, Intuitive Machines William Gerstenmaier, vice president, build and flight reliability, SpaceX Melody Lovin, launch weather officer, Cape Canaveral Space Force Station’s 45th Weather Squadron Audio of the teleconference will stream live on the agency’s website:
      https://www.nasa.gov/live/
      Media may ask questions via phone only. For the dial-in number and passcode, please contact the Kennedy newsroom no later than 10 a.m. EST Wednesday, Feb. 26, at: ksc-newsroom@mail.nasa.gov.

      Launch coverage will begin on NASA+ approximately 45 minutes before liftoff. A specific time will be shared the week of Feb. 24.

      NASA Launch Coverage
      Audio only of the media teleconferences and launch coverage will be carried on the NASA “V” circuits, which may be accessed by dialing 321-867-1220, -1240, or -7135. On launch day, the full mission broadcast can be heard on -1220 and -1240, while the countdown net only can be heard on -7135 beginning approximately one hour before the mission broadcast begins.

      On launch day, a “tech feed” of the launch without NASA TV commentary will be carried on the NASA TV media channel.

      NASA Website Launch Coverage
      Launch day coverage of the mission will be available on the NASA website. Coverage will include live streaming and blog updates beginning Feb. 26, as the countdown milestones occur. On-demand streaming video and photos of the launch will be available shortly after liftoff. For questions about countdown coverage, contact the Kennedy newsroom at 321-867-2468.

      NASA Virtual Guests for Launch
      Members of the public can register to attend this launch virtually. Registrants will receive mission updates and activities by email, including curated mission resources, schedule updates, and a virtual guest passport stamp following a successful launch. Print your passport and get ready to add your stamp!

      Watch, Engage on Social Media
      Let people know you’re following the mission on X, Facebook, and Instagram by using the hashtag #Artemis. You can also stay connected by following and tagging these accounts:

      X: @NASA, @NASAKennedy, @NASAArtemis, @NASAMoon

      Facebook: NASA, NASAKennedy, NASAArtemis

      Instagram: @NASA, @NASAKennedy, @NASAArtemis

      Coverage en Español
      Did you know NASA has a Spanish section called NASA en español? Check out NASA en español on X, Instagram, Facebook, and YouTube for additional mission coverage.

      Para obtener información sobre cobertura en español en el Centro Espacial Kennedy o si desea solicitar entrevistas en español, comuníquese con Antonia Jaramillo o Messod Bendayan a: antonia.jaramillobotero@nasa.gov o messod.c.bendayan@nasa.gov.

      For more information about the agency’s CLPS initiative, see:
      https://www.nasa.gov/clps
      -end-
      Karen Fox / Jasmine Hopkins
      Headquarters, Washington
      301-286-6284 / 321-432-4624
      karen.c.fox@nasa.gov / jasmine.s.hopkins@nasa.gov

      Natalia Riusech / Nilufar Ramji
      Johnson Space Center, Houston
      281-483-5111
      nataila.s.riusech@nasa.gov / nilufar.ramji@nasa.gov
      Antonia Jaramillo
      Kennedy Space Center, Florida
      321-501-8425
      antonia.jaramillobotero@nasa.gov
      Share
      Details
      Last Updated Feb 21, 2025 Related Terms
      Missions Artemis Commercial Lunar Payload Services (CLPS) Science Mission Directorate Space Technology Mission Directorate View the full article

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