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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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    • NASA
      How NASA’s Roman Mission Will Unveil Our Home Galaxy Using Cosmic Dust
      By NASA
      NASA’s Nancy Grace Roman Space Telescope will help scientists better understand our Milky Way galaxy’s less sparkly components — gas and dust strewn between stars, known as the interstellar medium.
      One of Roman’s major observing programs, called the Galactic Plane Survey, will peer through our galaxy to its most distant edge, mapping roughly 20 billion stars—about four times more than have currently been mapped. Scientists will use data from these stars to study and map the dust their light travels through, contributing to the most complete picture yet of the Milky Way’s structure, star formation, and the origins of our solar system.
      Our Milky Way galaxy is home to more than 100 billion stars that are often separated by trillions of miles. The spaces in between, called the interstellar medium, aren’t empty — they’re sprinkled with gas and dust that are both the seeds of new stars and the leftover crumbs from stars long dead. Studying the interstellar medium with observatories like NASA’s upcoming Nancy Grace Roman Space Telescope will reveal new insight into the galactic dust recycling system.
      Credit: NASA/Laine Havens; Music credit: Building Heroes by Enrico Cacace [BMI], Universal Production Music “With Roman, we’ll be able to turn existing artist’s conceptions of the Milky Way into more data-driven models using new constraints on the 3D distribution of interstellar dust,” said Catherine Zucker, an astrophysicist at the Center for Astrophysics | Harvard & Smithsonian in Cambridge, Massachusetts.
      Solving Milky Way mystery
      Scientists know how our galaxy likely looks by combining observations of the Milky Way and other spiral galaxies. But dust clouds make it hard to work out the details on the opposite side of our galaxy. Imagine trying to map a neighborhood while looking through the windows of a house surrounded by a dense fog.
      Roman will see through the “fog” of dust using a specialized camera and filters that observe infrared light — light with longer wavelengths than our eyes can detect. Infrared light is more likely to pass through dust clouds without scattering.
      This artist’s concept visualizes different types of light moving through a cloud of particles. Since infrared light has a longer wavelength, it can pass more easily through the dust. That means astronomers observing in infrared light can peer deeper into dusty regions.Credit: NASA’s Goddard Space Flight Center Light with shorter wavelengths, including blue light produced by stars, more easily scatters. That means stars shining through dust appear dimmer and redder than they actually are.
      By comparing the observations with information on the source star’s characteristics, astronomers can disentangle the star’s distance from how much its colors have been reddened. Studying those effects reveals clues about the dust’s properties.
      “I can ask, ‘how much redder and dimmer is the starlight that Roman detects at different wavelengths?’ Then, I can take that information and relate it back to the properties of the dust grains themselves, and in particular their size,” said Brandon Hensley, a scientist who studies interstellar dust at NASA’s Jet Propulsion Laboratory in Southern California.
      Scientists will also learn about the dust’s composition and probe clouds to investigate the physical processes behind changing dust properties.
      Clues in dust-influenced starlight hint at the amount of dust between us and a star. Piecing together results from many stars allows astronomers to construct detailed 3D dust maps. That would enable scientists like Zucker to create a model of the Milky Way, which will show us how it looks from the outside. Then scientists can better compare the Milky Way with other galaxies that we only observe from the outside, slotting it into a cosmological perspective of galaxy evolution.
      “Roman will add a whole new dimension to our understanding of the galaxy because we’ll see billions and billions more stars,” Zucker said. “Once we observe the stars, we’ll have the dust data as well because its effects are encoded in every star Roman detects.”
      Galactic life cycles
      The interstellar medium does more than mill about the Milky Way — it fuels star and planet formation. Dense blobs of interstellar medium form molecular clouds, which can gravitationally collapse and kick off the first stages of star development. Young stars eject hot winds that can cause surrounding dust to clump into planetary building blocks.
      “Dust carries a lot of information about our origins and how everything came to be,” said Josh Peek, an associate astronomer and head of the data science mission office at the Space Telescope Science Institute in Baltimore, Maryland. “Right now, we’re basically standing on a really large dust grain — Earth was built out of lots and lots of really tiny grains that grew together into a giant ball.”
      Roman will identify young clusters of stars in new, distant star-forming regions as well as contribute data on “star factories” previously identified by missions like NASA’s retired Spitzer Space Telescope.
      “If you want to understand star formation in different environments, you have to understand the interstellar landscape that seeds it,” Zucker said. “Roman will allow us to link the 3D structure of the interstellar medium with the 3D distribution of young stars across the galaxy’s disk.”
      Roman’s new 3D dust maps will refine our understanding of the Milky Way’s spiral structure, the pinwheel-like pattern where stars, gas, and dust bunch up like galactic traffic jams. By combining velocity data with dust maps, scientists will compare observations with predictions from models to help identify the cause of spiral structure—currently unclear.
      The role that this spiral pattern plays in star formation remains similarly uncertain. Some theories suggest that galactic congestion triggers star formation, while others contend that these traffic jams gather material but do not stimulate star birth.
      Roman will help to solve mysteries like these by providing more data on dusty regions across the entire Milky Way. That will enable scientists to compare many galactic environments and study star birth in specific structures, like the galaxy’s winding spiral arms or its central stellar bar.
      NASA’s Nancy Grace Roman Space Telescope will conduct a Galactic Plane Survey to explore our home galaxy, the Milky Way. The survey will map around 20 billion stars, each encoding information about intervening dust and gas called the interstellar medium. Studying the interstellar medium could offer clues about our galaxy’s spiral arms, galactic recycling, and much more.
      Credit: NASA, STScI, Caltech/IPAC The astronomy community is currently in the final stages of planning for Roman’s Galactic Plane Survey.
      “With Roman’s massive survey of the galactic plane, we’ll be able to have this deep technical understanding of our galaxy,” Peek said.
      After processing, Roman’s data will be available to the public online via the Roman Research Nexus and the Barbara A. Mikulski Archive for Space Telescopes, which will each provide open access to the data for years to come.
      “People who aren’t born yet are going to be able to do really cool analyses of this data,” Peek said. “We have a really beautiful piece of our heritage to hand down to future generations and to celebrate.”
      Roman is slated to launch no later than May 2027, with the team working toward a potential early launch as soon as fall 2026.
      The Nancy Grace Roman Space Telescope is managed at NASA’s Goddard Space Flight Center in Greenbelt, Maryland, with participation by NASA’s Jet Propulsion Laboratory and Caltech/IPAC in Southern California, the Space Telescope Science Institute in Baltimore, and a science team comprising scientists from various research institutions. The primary industrial partners are BAE Systems Inc. in Boulder, Colorado; L3Harris Technologies in Rochester, New York; and Teledyne Scientific & Imaging in Thousand Oaks, California.
      Download additional images and video from NASA’s Scientific Visualization Studio.
      For more information about the Roman Space Telescope, visit:
      https://www.nasa.gov/roman
      By Laine Havens
      NASA’s Goddard Space Flight Center, Greenbelt, Md.
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      Last Updated Sep 16, 2025 EditorAshley BalzerContactAshley Balzerashley.m.balzer@nasa.govLocationGoddard Space Flight Center Related Terms
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