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55 Years Ago: One Month Until the Moon Landing

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With the dress rehearsal completed during Apollo 10 in May 1969, only a few weeks remained until Apollo 11, the actual Moon landing mission to meet President Kennedy’s goal set in 1961. Apollo 11 astronauts Neil A. Armstrong, Michael Collins, and Edwin E. “Buzz” Aldrin and their backups James A. Lovell, William A. Anders, and Fred W. Haise entered the final phase of their training, rehearsing their mission in simulators and practicing for the lunar surface activities. Teams in Mission Control supported the simulations. A successful countdown demonstration cleared the way to start the actual countdown leading to launch. In the Pacific Ocean, U.S. Navy and NASA teams prepared for the recovery of the astronauts returning from the Moon, and for their postflight quarantine.

Apollo 10

After returning from their successful Moon landing dress rehearsal mission on May 26, 1969, Apollo 10 astronauts Thomas P. Stafford, John W. Young, and Eugene A. Cernan passed on their knowledge and lessons learned to the Apollo 11 Moon landing crew during postflight debriefs. On June 8, they accepted Emmy Awards on behalf of all Apollo crews for their television broadcasts from space, with special recognition for Apollo 10’s first use of color TV in space. On June 19, Stafford, Young, and Cernan returned to NASA’s Kennedy Space Center (KSC) in Florida to thank the employees there for getting them safely into orbit. On June 30, President Richard M. Nixon hosted them and their wives at a White House black tie dinner in their honor.

Apollo 10 astronauts debrief their mission with the Apollo 11 astronauts Apollo 10 astronauts John W. Young, left, Eugene A. Cernan, and Thomas P. Stafford hold their Emmy Awards At NASA’s Kennedy Space Center (KSC) in Florida, Stafford, left, Young, and Cernan hold photographs of their launch presented to them by KSC Launch Director Rocco A. Petrone
Left: Apollo 10 astronauts debrief their mission with the Apollo 11 astronauts. Middle: Apollo 10 astronauts John W. Young, left, Eugene A. Cernan, and Thomas P. Stafford hold their Emmy Awards. Right: At NASA’s Kennedy Space Center (KSC) in Florida, Stafford, left, Young, and Cernan hold photographs of their launch presented to them by KSC Launch Director Rocco A. Petrone.

Apollo 10 astronauts Thomas P. Stafford, left, John W. Young, and Eugene A. Cernan wave to employees as they ride in a convertible through NASA’s Kennedy Space Center in Florida
Apollo 10 astronauts Thomas P. Stafford, left, John W. Young, and Eugene A. Cernan wave to employees as they ride in a convertible through NASA’s Kennedy Space Center in Florida.

Apollo 11

moon-landing-l-1-month-5-apollo-11-omsf-
The document from NASA’s Office of Manned Space Flight stating Apollo 11’s primary objective.

On June 26, Samuel C. Phillips, Apollo Program Director, and George E. Mueller, Associate Administrator for Manned Space Flight at NASA Headquarters in Washington, D.C., signed the directive stating Apollo 11’s primary objective: perform a manned lunar landing and return. The focus of the crew’s training, and all the other preparatory activities happening across the agency, aimed at accomplishing that seemingly simple, yet in truth extremely complex and never before accomplished, task.

moon-landing-l-1-month-6-apollo-11-armst moon-landing-l-1-month-7-apollo-11-colli
Left: Apollo 11 astronauts Neil A. Armstrong, left, and Edwin E. “Buzz” Aldrin in the Lunar Module simulator at NASA’s Kennedy Space Center (KSC) in Florida. Right: Apollo 11 astronaut Michael Collins in KSC’s Command Module simulator.

moon-landing-l-1-month-8-apollo-11-fligh
Apollo 11 Flight Directors Eugene F. Kranz, left, Glynn S. Lunney, Clifford E. Charlesworth, Milton L. Windler, and Gerald D. Griffin pose in Mission Control.

The final weeks leading up to the launch of their historic mission proved quite busy for Apollo 11 astronauts Armstrong, Collins, and Aldrin and their backups Lovell, Anders, and Haise, as well as the ground teams preparing their rocket and spacecraft for flight. To train for the different phases of their mission, the astronauts conducted many sessions in Command Module (CM) and Lunar Module (LM) simulators at both the Manned Spacecraft Center (MSC), now NASA’s Johnson Space Center in Houston, and at KSC. For many of these sessions, teams of operators in MSC’s Mission Control monitored their activities as they would during the actual mission. Flight Directors Eugene F. Kranz, left, Glynn S. Lunney, Clifford E. Charlesworth, Milton L. Windler, and Gerald D. Griffin led the Mission Control teams.

Apollo 11 astronauts Neil A. Armstrong, left, and Edwin E. “Buzz Apollo 11 astronauts Neil A. Armstrong, left, and Edwin E. “Buzz
Apollo 11 astronauts Neil A. Armstrong, left, and Edwin E. “Buzz” Aldrin practice their lunar surface activities at the Manned Spacecraft Center, now NASA’s Johnson Space Center in Houston, left, and at NASA’s Kennedy Space Center in Florida.

Apollo 11 would conduct the first spacewalk on another celestial body and only the second spacewalk of the Apollo program. At training facilities at MSC and KSC, Armstrong and Aldrin practiced setting up a television camera that would relay their activities back to Earth during the 2.5-hour excursion, deploying the three science experiments, and collecting rock and regolith samples for return to Earth.

Apollo 11 Commander Neil A. Armstrong prepares to fly the Lunar Landing Training Vehicle (LLTV) at Ellington Air Force Base in Houston Armstrong airborne in the LLTV Apollo 11 backup Commander James A. Lovell following a flight in the LLTV
Left: Apollo 11 Commander Neil A. Armstrong prepares to fly the Lunar Landing Training Vehicle (LLTV) at Ellington Air Force Base in Houston. Middle: Armstrong airborne in the LLTV. Right: Apollo 11 backup Commander James A. Lovell following a flight in the LLTV.

On June 6, NASA managers approved the resumption of astronaut training flights in the Lunar Landing Training Vehicle (LLTV) at Ellington Air Force Base (AFB) near MSC. The LLTV simulated the flight characteristics of the LM and astronauts used it to train for the final 200 feet of the descent to the lunar surface. Managers reached the decision after reviewing findings from the Review Board headed by astronaut Walter M. Schirra that investigated the Dec. 8, 1968 crash of LLTV-1 as well as results from flights in LLTV-2 made by MSC test pilots Harold E. “Bud” Ream and Jere B. Cobb. Between June 14 and 16, Armstrong flew LLTV-2 eight times to complete his training program with the vehicle. He had previously completed 12 simulated Moon landings in the LLTV and its predecessor, the Lunar Landing Research Vehicle (LLRV), narrowly escaping the crash of LLRV-1 in May 1968. Backup Commander Lovell completed four flights in the LLTV between June 19 and July 1. Armstrong, Aldrin, Lovell, and Haise also practiced landings in the Lunar Landing Research Facility (LLRF) at NASA’s Langley Research Center in Hampton, Virginia.

Senior NASA managers monitor the Apollo 11 Countdown Demonstration Test (CDDT) in Firing Room 1 of the Launch Control Center at NASA’s Kennedy Space Center The team of controllers in Firing Room 1 monitor the Apollo 11 CDDT
Left: Senior NASA managers monitor the Apollo 11 Countdown Demonstration Test (CDDT) in Firing Room 1 of the Launch Control Center at NASA’s Kennedy Space Center. Right: The team of controllers in Firing Room 1 monitor the Apollo 11 CDDT.

Apollo 11 astronauts Neil A. Armstrong, front, Michael Collins, and Edwin E. “Buzz” Aldrin about to board the transfer van to Launch Pad 39A for the Countdown Demonstration Test (CDDT) Workers in the White Room assist Collins, left, Armstrong, and Aldrin to enter their spacecraft for the CDDT Armstrong, left, Aldrin, and Collins leave Launch Pad 39A at the conclusion of the CDDT
Left: Apollo 11 astronauts Neil A. Armstrong, front, Michael Collins, and Edwin E. “Buzz” Aldrin about to board the transfer van to Launch Pad 39A for the Countdown Demonstration Test (CDDT). Middle: Workers in the White Room assist Collins, left, Armstrong, and Aldrin to enter their spacecraft for the CDDT. Right: Armstrong, left, Aldrin, and Collins leave Launch Pad 39A at the conclusion of the CDDT.

At KSC, engineers completed the three-day Flight Readiness Test on June 6, ensuring the flight readiness of the Saturn V rocket and the Apollo spacecraft perched on Launch Pad 39A. On June 17, top managers from NASA Headquarters and the Directors of MSC, KSC, and the Marshall Space Flight Center in Huntsville, Alabama, held the Flight Readiness Review at KSC. The meeting reviewed all aspects of readiness for the launch and mission, clearing the way for the next milestone, the Countdown Demonstration Test (CDDT). The CDDT, a full dress rehearsal for the actual countdown to launch, consisted of two parts. The “wet” test, conducted from June 27 to July 2, included fueling the rocket as if for flight, with the countdown stopping just prior to first stage engine ignition, and did not involve the flight crew. The “dry” test followed on July 3, an abbreviated countdown without fueling the rocket but with the astronauts boarding the CM as if on launch day. Controllers in Firing Room 1 of the Launch Control Center at Launch Complex 39 monitored all aspects of the CDDT as they would for an actual countdown. The successful test cleared the way for the start of the launch countdown at 8 p.m. EDT on July 10, leading to launch on July 16.

The Lunar Flag Assembly The stainless steel commemorative plaque The silicon disc containing messages of goodwill from world leaders
The three commemorative items carried aboard Apollo 11. Left: The Lunar Flag Assembly. Middle: The stainless steel commemorative plaque. Right: The silicon disc containing messages of goodwill from world leaders.

On July 2, NASA announced that Armstrong and Aldrin would leave three symbolic items behind on the Moon to commemorate the historic first landing – an American flag, a commemorative plaque, and a silicon disc bearing messages from world leaders. The astronauts would plant the three-by-five-foot flag near their LM during their spacewalk. The stainless steel plaque bore the images of the two hemispheres of the Earth and this inscription,

HERE MEN FROM THE PLANET EARTH

FIRST SET FOOT UPON THE MOON

JULY 1969 A.D.

WE CAME IN PEACE FOR ALL MANKIND

The signatures of the three astronauts and President Richard M. Nixon also appeared on the plaque. Workers mounted it on the forward landing leg strut of the LM. The one-and-one-half-inch silicon disc contained messages of goodwill from 73 world leaders, etched on the disk using the technique to make microcircuits for electronic equipment. The crew placed the disc on the lunar surface at the end of their spacewalk.

Apollo 11 astronauts Neil A. Armstrong, left, Edwin E. “Buzz” Aldrin, and Michael Collins hold a copy of the commemorative plaque they will leave behind on the Moon and their mission patch The Apollo 11 astronauts in the glass-enclosed room at the Lunar Receiving Laboratory
Left: Apollo 11 astronauts Neil A. Armstrong, left, Edwin E. “Buzz” Aldrin, and Michael Collins hold a copy of the commemorative plaque they will leave behind on the Moon and their mission patch. Right: The Apollo 11 astronauts in the glass-enclosed room at the Lunar Receiving Laboratory.

During a July 5 press conference in the MSC auditorium, the Apollo 11 astronauts revealed the call signs for their spacecraft. They named their CM Columbia and their LM Eagle. “We selected these as being representative of the flight, the nation’s hope,” said Armstrong. Columbia served as a national symbol represented by a statue atop the Capitol in Washington, D.C. They named the LM after the symbol of the United States, the bald eagle, featured on the Apollo 11 mission patch. In a second event, the astronauts answered reporters’ questions from inside a glass-enclosed conference room at MSC’s Lunar Receiving Laboratory (LRL). After their mission, the returning astronauts completed their 21-day quarantine in the LRL to prevent any back contamination of the Earth by any possible lunar microorganisms.

On the loading dock of the Lunar Receiving Laboratory (LRL) at the Manned Spacecraft Center, now NASA’s Johnson Space Center in Houston, workers simulate the arrival of the first Moon rocks and other items returned from Apollo 11 Workers practice docking the Mobile Quarantine Facility (MQF) with the LRL In Pearl Harbor, Hawaii, workers barge the prime and backup MQFs to load them onto the U.S.S. Hornet
NASA’s Johnson Space Center in Houston, workers simulate the arrival of the first Moon rocks and other items returned from Apollo 11. Middle: Workers practice docking the Mobile Quarantine Facility (MQF) with the LRL. Right: In Pearl Harbor, Hawaii, workers barge the prime and backup MQFs to load them onto the U.S.S. Hornet. Image credit: courtesy U.S. Navy.

At the LRL, other preparations for the return of the Apollo 11 astronauts from the Moon included a simulation of the arrival and processing of the Moon rocks and other items following the mission. The rocks, crew biological samples, and film would be flown from the prime recovery ship to Houston ahead of the crew. Engineers and technicians also rehearsed the arrival of the crew with a dry run of docking a Mobile Quarantine Facility (MQF) to the LRL’s loading dock. Following the test, workers loaded two MQFs, a prime and a backup, onto a cargo plane for transport to Hawaii and loading onto the prime recovery ship.

Workers in Pearl Harbor, Hawaii, prepare to lift a boilerplate Apollo Command Module onto the U.S.S. Hornet for splashdown and recovery rehearsals Crews from the U.S.S. Hornet practice recovery operations Recovery team members dry their Biological Isolation Garments aboard the U.S.S. Hornet following a recovery exercise
Left: Workers in Pearl Harbor, Hawaii, prepare to lift a boilerplate Apollo Command Module onto the U.S.S. Hornet for splashdown and recovery rehearsals. Image credit: courtesy U.S. Navy Bob Fish. Middle: Crews from the U.S.S. Hornet practice recovery operations. Right: Recovery team members dry their Biological Isolation Garments aboard the U.S.S. Hornet following a recovery exercise.

On June 12, the U.S. Navy notified NASA that it had selected the U.S.S. Hornet (CVS-12) as the prime recovery ship for Apollo 11 to undertake the most complex recovery of an astronaut crew. The same day, with Hornet docked in her home port of Long Beach, California, its commanding officer, Capt. Carl J. Seiberlich, held the first recovery team meeting to review the Apollo Recovery Operations Manual, written by MSC’s Landing and Recovery Division. Between June 12 and 25, Hornet onloaded NASA equipment required for the recovery. On June 27, Hornet left Long Beach for a three-hour stop in San Diego, where air group maintenance and support personnel embarked. The next day, after Hornet left for Pearl Harbor, Hawaii, pilots flew the aircraft required to support the recovery onto the carrier. During the cruise to Pearl Harbor, Hornet’s 90-man team detailed for Apollo 11 recovery operations held numerous meetings and table-top simulations. After arriving in Hawaii on July 2, workers loaded a boilerplate Apollo capsule onto the aircraft carrier to be used for recovery practice. The NASA recovery team, the Frogmen swimmers from the U.S. Navy’s Underwater Demolition Team 11 (UDT-11) who assisted with the recovery, and some media personnel arrived onboard. For the recovery operation, Capt. Seiberlich adopted the motto “Hornet Plus Three,” indicating the goal of a safe recovery of the three astronauts returning from the Moon. On July 3, Capt. Seiberlich introduced the 35-member NASA recovery team to the Hornet’s crew. Donald E. Stullken, Chief of the Recovery Operations Branch at MSC and inventor of the inflatable flotation collar attached by swimmers to the capsule after splashdown, led the NASA team. His assistant John C. Stonesifer oversaw the decontamination and quarantine operations. Stullken and Stonesifer briefed Hornet’s Command Module Retrieval Team on all events associated with the recovery and retrieval of an Apollo capsule and its crew. On July 6, workers loaded the two MQFs aboard Hornet. The prime MQF would house the returning astronauts, a flight surgeon, and an engineer from shortly after splashdown until their arrival at the LRL in Houston several days later. The second MQF served as a backup should a problem arise with the first or if violations of quarantine protocols required additional personnel to be isolated. Along with the MQFs, Navy personnel loaded other equipment necessary for the recovery, including 55 one-gallon containers of sodium hypochlorite to be used as a disinfectant. Between July 7 and 9, the Hornet conducted nine Simulated Recovery Exercises in local Hawaiian waters. Lieutenant Clarence J. “Clancy” Hatleberg led the team as the designated decontamination swimmer with U.S. Navy Frogmen serving as stand-ins for the astronauts, all wearing Biological Isolation Garments as they would on recovery day. The Hornet returned to Pearl Harbor to pick up the rest of the NASA recovery team before setting sail on July 12 for its first recovery position. 

Apollo 12

moon-landing-l-1-month-30-apollo-12-csm- Conrad after completing a flight in the Lunar Landing Training Vehicle
Left: Apollo 12 astronauts Charles “Pete” Conrad, left, Alan L. Bean, and Richard F. Gordon prepare to enter their Command Module for an altitude test. Right: Conrad after completing a flight in the Lunar Landing Training Vehicle.

In the Manned Spacecraft Operations Building (MSOB) at NASA’s Kennedy Space Center, workers finish attaching the landing gear to the Apollo 12 Lunar Module (LM) Workers in the MSOB prepare to mate the Apollo 12 Command and Service Modules with the Spacecraft LM Adapter Workers move the assembled Apollo 12 spacecraft from the MSOB to the Vehicle Assembly Building (VAB) In the VAB. workers lower the Apollo 12 spacecraft onto its Saturn V rocket
Left: In the Manned Spacecraft Operations Building (MSOB) at NASA’s Kennedy Space Center, workers finish attaching the landing gear to the Apollo 12 Lunar Module (LM). Middle left: Workers in the MSOB prepare to mate the Apollo 12 Command and Service Modules with the Spacecraft LM Adapter. Middle right: Workers move the assembled Apollo 12 spacecraft from the MSOB to the Vehicle Assembly Building (VAB). Right: In the VAB. workers lower the Apollo 12 spacecraft onto its Saturn V rocket.

With Apollo 11 on its launch pad, workers continued to prepare Apollo 12 for its eventual journey to the Moon, targeting a September launch should Apollo 11 not succeed. If Apollo 11 succeeded in its Moon landing mission, Apollo 12 would fly later, most likely in November, to attempt the second Moon landing at a different location. In KSC’s Vehicle Assembly Building (VAB), the three-stage Saturn V stood on its Mobile Launcher, awaiting the arrival of the Apollo spacecraft. In the nearby Manned Spacecraft Operations Building, the Apollo 12 prime crew of Charles “Pete” Conrad, Richard F. Gordon, and Alan L. Bean and their backups David R. Scott, Alfred M. Worden, and James B. Irwin completed altitude chamber tests of the CM and LM during the first two weeks of June. Workers removed the spacecraft from the vacuum chambers, mated them on June 27, and transferred them to the VAB on July 1 for stacking on the Saturn V rocket. At Ellington AFB in Houston, Conrad completed his first flights aboard LLTV-2 on July 9-10.

Apollo 13

In the Vehicle Assembly Building at NASA’s Kennedy Space Center (KSC) in Florida, workers place the first stage of the Apollo 13 Saturn V rocket onto the Mobile Launcher to begin the stacking process The Apollo 13 Command and Service Modules arrive at KSC The ascent stage of the Apollo 13 Lunar Module arrives at KSC
Left: In the Vehicle Assembly Building at NASA’s Kennedy Space Center (KSC) in Florida, workers place the first stage of the Apollo 13 Saturn V rocket onto the Mobile Launcher to begin the stacking process. Middle: The Apollo 13 Command and Service Modules arrive at KSC. Right: The ascent stage of the Apollo 13 Lunar Module arrives at KSC.

In the event that neither Apollo 11 nor 12 succeeded in landing on the Moon, NASA stood prepared to try a third time with Apollo 13 in November or December, still in time to meet President Kennedy’s deadline. The Apollo 13 Command and Service Modules arrived at KSC on June 26, followed by the LM ascent and descent stages on June 28 and 29, respectively. The Saturn V’s S-IC first stage arrived on June 16 and workers placed it on its Mobile Launcher two days later. The S-IVB third stage and S-II second stage arrived June 13 and 29, respectively, and workers stacked the stages in mid-July.

To be continued …

News from around the world in June 1969:

June 3 – Eric Carle publishes children’s picture book “The Very Hungry Caterpillar.”

June 3 – The final episode of Star Trek airs on NBC.

June 5 – The Tupolev Tu-144 became the first passenger jet to fly faster than the speed of sound.

June 10 – The Nixon Administration cancels the U.S. Air Force Manned Orbiting Laboratory program.

June 15 – “Hee Haw,” with Roy Clark and Buck Owens, premieres on CBS.

June 20 – Georges Pompidou sworn in as the 19th President of France.

June 20 – 200,000 attend Newport ’69, then largest-ever pop concert, in Northridge, California.

June 23 – Warren E. Burger sworn in as U.S. Supreme Court Chief Justice.

June 28 – Police carry out a raid at the Stonewall Inn in Greenwich Village, New York, beginning the modern LGBT rights movement.

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      Curiosity Rover
      Curiosity was the largest and most capable rover ever sent to Mars when it launched in 2011. Leading up the mission, Langley engineers performed millions of simulations of the entry, descent and landing phase — or the so-called “Seven Minutes of Terror” — that determines success or failure. Curiosity continues to look for signs that Mars once was – or still is – a habitable place for life as we know it.
      CLPS: 2023 – Present
      The Commercial Lunar Payload Services initiative takes the Artemis mission further by working with commercial partners to advance the technology needed to return humans to the Moon and enable humanity to explore Mars.
      NDL
      Navigation Doppler Lidar (NDL) technology, developed at Langley Research Center, uses lasers to assist spacecraft in identifying safe locations to land. In 2024, NDL flew on the Intuitive Machines’ uncrewed Nova-C lander, with its laser instruments designed to measure velocity and altitude to within a few feet. While NASA planetary landers have traditionally relied on radar and used radio waves, NDL technology has proven more accurate and less heavy, both major benefits for cost and space savings as we continue to pursue planetary missions.
      SCALPSS
      Like Lunar Orbiter and the Viking missions before it, Stereo Cameras for Lunar Plume Surface Studies (SCALPSS) set out to better understand the surface of another celestial body. These cameras affixed to the bottom of a lunar lander focus on the interaction between the lander’s rocket plumes and the lunar surface. The SCALPSS 1.1 instrument captured first-of-its-kind imagery as the engine plumes of Firefly’s Blue Ghost lander reached the Moon’s surface. These images will serve as key pieces of data as trips to the Moon increase in the coming years. 
      About the Author
      Angelique Herring

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      Last Updated Apr 03, 2025 EditorAngelique HerringContactJoseph Scott Atkinsonjoseph.s.atkinson@nasa.govLocationNASA Langley Research Center Related Terms
      General Langley Research Center Explore More
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    • NASA
      Discovery Alert: Four Little Planets, One Big Step
      By NASA
      Explore This Section Exoplanets Home Exoplanets Overview Exoplanets Facts Types of Exoplanets Stars What is the Universe Search for Life The Big Questions Are We Alone? Can We Find Life? The Habitable Zone Why We Search Target Star Catalog Discoveries Discoveries Dashboard How We Find and Characterize Missions People Exoplanet Catalog Immersive The Exoplaneteers Exoplanet Travel Bureau 5 Ways to Find a Planet Strange New Worlds Universe of Monsters Galaxy of Horrors News Stories Blog Resources Get Involved Glossary Eyes on Exoplanets Exoplanet Watch More Multimedia ExEP This artist’s concept pictures the planets orbiting Barnard’s Star, as seen from close to the surface of one of them. Image credit: International Gemini Observatory/NOIRLab/NSF/AURA/P. Marenfeld The Discovery
      Four rocky planets much smaller than Earth orbit Barnard’s Star, the next closest to ours after the three-star Alpha Centauri system. Barnard’s is the nearest single star.
      Key Facts
      Barnard’s Star, six light-years away, is notorious among astronomers for a history of false planet detections. But with the help of high-precision technology, the latest discovery — a family of four — appears to be solidly confirmed. The tiny size of the planets is also remarkable: Capturing evidence of small worlds at great distance is a tall order, even using state-of-the-art instruments and observational techniques.
      Details
      Watching for wobbles in the light from a star is one of the leading methods for detecting exoplanets — planets orbiting other stars. This “radial velocity” technique tracks subtle shifts in the spectrum of starlight caused by the gravity of a planet pulling its star back and forth as the planet orbits. But tiny planets pose a major challenge: the smaller the planet, the smaller the pull. These four are each between about a fifth and a third as massive as Earth. Stars also are known to jitter and quake, creating background “noise” that potentially could swamp the comparatively quiet signals from smaller, orbiting worlds.
      Astronomers measure the back-and-forth shifting of starlight in meters per second; in this case the radial velocity signals from all four planets amount to faint whispers — from 0.2 to 0.5 meters per second (a person walks at about 1 meter per second). But the noise from stellar activity is nearly 10 times larger at roughly 2 meters per second.
      How to separate planet signals from stellar noise? The astronomers made detailed mathematical models of Barnard’s Star’s quakes and jitters, allowing them to recognize and remove those signals from the data collected from the star.
      The new paper confirming the four tiny worlds — labeled b, c, d, and e — relies on data from MAROON-X, an “extreme precision” radial velocity instrument attached to the Gemini Telescope on the Maunakea mountaintop in Hawaii. It confirms the detection of the “b” planet, made with previous data from ESPRESSO, a radial velocity instrument attached to the Very Large Telescope in Chile. And the new work reveals three new sibling planets in the same system.
      Fun Facts
      These planets orbit their red-dwarf star much too closely to be habitable. The closest planet’s “year” lasts a little more than two days; for the farthest planet, it’s is just shy of seven days. That likely makes them too hot to support life. Yet their detection bodes well in the search for life beyond Earth. Scientists say small, rocky planets like ours are probably the best places to look for evidence of life as we know it. But so far they’ve been the most difficult to detect and characterize. High-precision radial velocity measurements, combined with more sharply focused techniques for extracting data, could open new windows into habitable, potentially life-bearing worlds.
      Barnard’s star was discovered in 1916 by Edward Emerson Barnard, a pioneering astrophotographer.
      The Discoverers
      An international team of scientists led by Ritvik Basant of the University of Chicago published their paper on the discovery, “Four Sub-Earth Planets Orbiting Barnard’s Star from MAROON-X and ESPRESSO,” in the science journal, “The Astrophysical Journal Letters,” in March 2025. The planets were entered into the NASA Exoplanet Archive on March 13, 2025.
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      Last Updated Apr 01, 2025 Related Terms
      Exoplanets Radial Velocity Terrestrial Exoplanets Keep Exploring Discover More Topics From NASA
      Universe



      Exoplanets



      Search for Life



      Exoplanet Catalog


      This exoplanet encyclopedia — continuously updated, with more than 5,600 entries — combines interactive 3D models and detailed data on…

      View the full article
    • European Space Agency
      ExoMars Rosalind Franklin rover will have a European landing platform
      By European Space Agency
      The European Space Agency (ESA) has selected Airbus to design and build the landing platform for the ExoMars Rosalind Franklin rover. In 2028, ESA will launch this ambitious exploration mission to search for past and present signs of life on Mars.
      View the full article
    • NASA
      The Sky’s Not the Limit: Testing Precision Landing Tech for Future Space Missions
      By NASA
      2 min read
      Preparations for Next Moonwalk Simulations Underway (and Underwater)
      A NASA F/A-18 research aircraft flies above California near NASA’s Armstrong Flight Research Center in Edwards, California, testing a commercial precision landing technology for future space missions. The Psionic Space Navigation Doppler Lidar (PSNDL) system is installed in a pod located under the right wing of the aircraft.NASA Nestled in a pod under an F/A-18 Hornet aircraft wing, flying above California, and traveling up to the speed of sound, NASA put a commercial sensor technology to the test. The flight tests demonstrated the sensor accuracy and navigation precision in challenging conditions, helping prepare the technology to land robots and astronauts on the Moon and Mars. 
      The Psionic Space Navigation Doppler Lidar (PSNDL) system is rooted in NASA technology that Psionic, Inc. of Hampton, Virginia, licensed and further developed. They miniaturized the NASA technology, added further functionality, and incorporated component redundancies that make it more rugged for spaceflight. The PSNDL navigation system also includes cameras and an inertial measurement unit to make it a complete navigation system capable of accurately determining a vehicle’s position and velocity for precision landing and other spaceflight applications. 
      NASA engineers and technicians install the Psionic Space Navigation Doppler Lidar (PSNDL) system into a testing pod on a NASA F/A-18 research aircraft ahead of February 2025 flight tests at NASA’s Armstrong Flight Research Center in Edwards, California.NASA The aircraft departed from NASA’s Armstrong Flight Research Center in Edwards, California, and conducted a variety of flight paths over several days in February 2025. It flew a large figure-8 loop and conducted several highly dynamic maneuvers over Death Valley, California, to collect navigation data at various altitudes, velocities, and orientations relevant for lunar and Mars entry and descent. Refurbished for these tests, the NASA F/A-18 pod can support critical data collection for other technologies and users at a low cost. 
      Doppler Lidar sensors provide a highly accurate measurement of speed by measuring the frequency shift between laser light emitted from the sensor reflected from the ground. Lidar are extremely useful in sunlight-challenged areas that may have long shadows and stark contrasts, such as the lunar South Pole. Pairing PSNDL with cameras adds the ability to visually compare pictures with surface reconnaissance maps of rocky terrain and navigate to landing at interesting locations on Mars. All the data is fed into a computer to make quick, real-time decisions to enable precise touchdowns at safe locations. 
      Psionic Space Navigation Doppler Lidar (PSNDL) system installed in a testing pod on a NASA F/A-18 research aircraft ahead of February 2025 flight tests at NASA’s Armstrong Flight Research Center in Edwards, California.NASA Since licensing NDL in 2016, Psionic has received funding and development support from NASA’s Space Technology Mission Directorate through its Small Business Innovative Research program and Tipping Point initiative. The company has also tested PSNDL prototypes on suborbital vehicles via the Flight Opportunities program. In 2024, onboard a commercial lunar lander, NASA successfully demonstrated the predecessor NDL system developed by the agency’s Langley Research Center in Hampton, Virginia. 
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      Last Updated Mar 26, 2025 EditorLoura Hall Related Terms
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