Astronomy:Lunar lander

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Short description: Spacecraft intended to land on the surface of the Moon


Apollo Apollo Lunar Module-5 Eagle as seen from CSM-107 Columbia

A lunar lander or Moon lander is a spacecraft designed to land on the surface of the Moon. As of 2023, the Apollo Lunar Module is the only lunar lander to have ever been used in human spaceflight, completing six lunar landings from 1969 to 1972 during the United States Apollo Program. Several robotic landers have reached the surface, and some have returned samples to Earth.

The design requirements for these landers depend on factors imposed by the payload, flight rate, propulsive requirements, and configuration constraints.[1] Other important design factors include overall energy requirements, mission duration, the type of mission operations on the lunar surface, and life support system if crewed. The relatively high gravity (higher than all known asteroids, but lower than all Solar System planets) and lack of lunar atmosphere negates the use of aerobraking, so a lander must use propulsion to decelerate and achieve a soft landing.

History

(In order to avoid unnecessarily lengthy citations in this section, please see the relevant hyperlinked Wikipedia pages for extensive sources for each historical item).

1958-1976

The Luna program was a series of robotic impactors, flybys, orbiters, and landers flown by the Soviet Union between 1958 and 1976. Luna 9 was the first spacecraft to achieve a soft landing on the Moon on February 3, 1966, after 11 unsuccessful attempts. Three Luna Spacecraft returned lunar soil samples to Earth from 1972 to 1976. Two other Luna spacecraft soft-landed the Lunokhod robotic lunar rover in 1970 and 1973. Luna achieved a total of seven successful soft-landings out of 27 landing attempts.

The United States Surveyor program first soft-landed Surveyor 1 on June 2, 1966, this initial success was followed by four additional successful soft-landings, the last occurring on January 10, 1968. The Surveyor program achieved a total of five successful soft landings out of seven landing attempts through January 10, 1968.

The Apollo Lunar Module was the lunar lander for the United States' Apollo program. As of 2022, it is the only crewed lunar lander. The Apollo program completed six successful lunar soft-landings from 1969 until 1972; a seventh lunar landing attempt by the Apollo program was aborted when Apollo 13's service module suffered explosive venting from its oxygen tanks.

The LK lunar module was the lunar lander developed by the Soviet Union as a part of several Soviet crewed lunar programs. Several LK lunar modules were flown without crew in low Earth orbit, but the LK lunar module never flew to the Moon, as the development of the N1 Rocket Launch Vehicle required for the lunar flight suffered setbacks (including several launch failures), and after the first human Moon landings were achieved by the United States , the Soviet Union cancelled both the N1 Rocket and the LK Lunar Module programs without any further development.

2013-2023

The Chinese Lunar Exploration Program (also known as the Chang'e project) includes robotic lander, rover, and sample-return components; the program realized an initial successful lunar soft-landing with the Chang'e 3 spacecraft on 14 December 2013. As of 2023, the CLEP has achieved three successful soft-landings out of three landing attempts, namely Chang'e 3, Chang'e 4 and Chang'e 5. Chang'e 4 made history by making humanity's first ever soft-landing on the far side of the moon.

Israel's SpaceIL attempted a robotic lunar landing by its Beresheet lander on 4 April 2019; the attempt failed. As of 2023, SpaceIL has plans for another soft-landing attempt using a follow-up robotic lander named Beresheet 2.

India's Chandrayaan Programme conducted an unsuccessful robotic lunar soft-landing attempt on 6 September 2019 as part of its Chandrayaan-2 spacecraft with the lander crashing on the Moon's surface.[2] On 23 August 2023, the program's follow-up Chandrayaan-3 lander achieved India's first robotic soft-landing.

Japan's ispace (not to be confused with China's i-Space) attempted a lunar soft-landing by its Hakuto-R Mission 1 robotic lander on 25 April 2023. The attempt was unsuccessful and the lander crashed into the lunar surface. The company currently has plans for another landing attempt in 2024.

Russia's Luna-Glob program, the successor program to the Soviet Union's Luna program, launched the Luna 25 lunar lander on 10 August 2023; the probe's intended destination was near the lunar south pole, but on 19 August 2023 the lander crashed on the Moon's surface.[3]

Japan's Smart Lander for Investigating Moon launched on 6 September 2023. The probe made a successful lunar landing on 19 January 2024, near the Shioli crater on the lunar near side; the lander carries two small rovers on board.[4] It landed on 19 January 2024 at 15:20 UTC, making Japan the 5th country to soft land on the moon.[5] Although it landed successfully, its in wrong attitude, because the solar panels are oriented westwards facing opposite the Sun at the start of lunar day, thereby failing to generate enough power. The lander operated on internal battery power, which was fully drained that day.[6] The mission's operators hope that the lander will wake up after a few days when sunlight should hit the solar panels.[7]

Irrespective of this solar array issue on lander, the two LEV 1 and 2 rovers, deployed during hovering just before final landing are working as expected and LEV-1 communicating independently to the ground stations.[7] LEV-1 conducted six hops on lunar surface. Images taken by LEV-2 show the wrong attitude landing with loss of an engine nozzle during descent and even possible sustained damage to lander's Earth bound antenna, that is not pointed towards Earth.[8] Irrespective of wrong attitude and loss of communication with the lander, the mission is already successful after confirmation of its primary goal landing within 100 m (330 ft) of its landing spot was already achieved.[9][10][11]

2024-Present

On 8 January 2024, the first mission of the NASA-funded CLPS program, Peregrine Mission One, was placed into an elliptical High Earth orbit; the mission's lunar lander was expected to execute a number of propulsive maneuvers to achieve a low lunar orbit prior to making a lunar landing attempt on 23 February 2024. However, a fuel leak was detected on the spacecraft several hours after launch with the result that it will lose its ability to maintain attitude control and to charge its battery, thereby rendering the acquisition of lunar orbit unlikely and precluding a landing attempt.[12]

Landing outcomes

The following table details the success rates of past and on-going lunar soft-landing attempts by robotic and crewed lunar-landing programs. Landing programs which have not launched any probes are not included in the table; they are added as their initial robotic and/or crewed landers are launched from Earth.

Due to prior usage in this article, the term "landing attempt" includes any mission that was launched with the intent to land on the moon, including all missions which failed to reach lunar orbit for any reason.

Program Country/Orgs. Time-span[lower-alpha 1] Type Landing attempts Soft-landed Outcome pending Notes
Luna Soviet Union USSR 1963-1976 robotic 27 7 not applicable Historical program; Russia's Luna 25 (2023) is part of successor program
Surveyor United States NASA 1966-1968 robotic 7 5 not applicable Historical program
Apollo United States NASA 1969-1972 crewed 7 6 not applicable Historical program
Soviet crewed lunar programs Soviet Union USSR N/A crewed 0 0 not applicable Historical programs; 3 uncrewed T2K variant of the LK lunar lander were tested in Earth orbit between November 1970 and August 1971
Chang'e China CNSA 2013-present robotic 3 3 landers/rovers, sample-returns, future ISRU missions
Beresheet Israel spaceIL 2019-present robotic 1 0
Chandrayaan India ISRO 2019-present robotic 2 1
Hakuto-R Japan ispace 2022-present robotic 1 0
Luna-Glob Russia Roscosmos 2023-present robotic 1 0 Successor program to the Soviet Luna programme.
JAXA programs Japan JAXA 2023-present robotic 1 1 SLIM (successful "pinpoint landing" within 100 m (330 ft) of target with incorrect attitude; power problems post landing)[13]
CLPS United States NASA 2024-present robotic 1 0 CLPS-1 Peregrine lander (spacecraft failure)

Proposed landers and research craft

Uncrewed

Crewed

Main pages: Engineering:List of crewed lunar landers and Astronomy:Lunar module

Research craft (earthbound)

Challenges unique to lunar landing

Landing on any Solar System body comes with challenges unique to that body. The Moon has relatively high gravity compared to that of asteroids or comets—and some other planetary satellites—and no significant atmosphere. Practically, this means that the only method of descent and landing that can provide sufficient thrust with current technology is based on chemical rockets.[17] In addition, the Moon has a long solar day. Landers will be in direct sunlight for more than two weeks at a time, and then in complete darkness for another two weeks. This causes significant problems for thermal control.[18]

Lack of atmosphere

(As of 2019) space probes have landed on all three bodies other than Earth that have solid surfaces and atmospheres thick enough to make aerobraking possible: Mars, Venus, and Saturn's moon Titan. These probes were able to leverage the atmospheres of the bodies on which they landed to slow their descent using parachutes, reducing the amount of fuel they were required to carry. This in turn allowed larger payloads to be landed on these bodies for a given amount of fuel. For example, the 900-kg Curiosity rover was landed on Mars by a craft having a mass (at the time of Mars atmospheric entry) of 2400 kg,[19] of which only 390 kg was fuel. In comparison, the much lighter (292 kg) Surveyor 3 landed on the Moon in 1967 using nearly 700 kg of fuel.[20] The lack of an atmosphere, however, removes the need for a Moon lander to have a heat shield and also allows aerodynamics to be disregarded when designing the craft.

High gravity

Although it has much less gravity than Earth, the Moon has sufficiently high gravity that descent must be slowed considerably. This is in contrast to a small asteroid, in which "landing" is more often called "docking" and is a matter of rendezvous and matching velocity more than slowing a rapid descent.

Since rocketry is used for descent and landing, the Moon's gravity necessitates the use of more fuel than is needed for asteroid landing. Indeed, one of the central design constraints for the Apollo program's Moon landing was mass (as more mass requires more fuel to land) required to land and take off from the Moon.[21]

Thermal environment

The lunar thermal environment is influenced by the length of the lunar day. Temperatures can swing between approximately −250 to 120 °C (−418.0 to 248.0 °F) (lunar night to lunar day). These extremes occur for fourteen Earth days each, so thermal control systems must be designed to handle long periods of extreme cold or heat.[22] Most spacecraft instruments must be kept within a much stricter range of between −40 and 50 °C (−40 and 122 °F),[23] and human comfort requires a range of 20 to 24 °C (68 to 75 °F). This means that the lander must cool and heat its instruments or crew compartment.

The length of the lunar night makes it difficult to use solar electric power to heat the instruments, and nuclear heaters are often used.[18]

Landing stages

Achieving a soft landing is the overarching goal of any lunar lander, and distinguishes landers from impactors, which were the first type of spacecraft to reach the surface of the Moon.

All lunar landers require rocket engines for descent. Orbital speed around the Moon can, depending on altitude, exceed 1500 m/s. Spacecraft on impact trajectories can have speeds well in excess of that.[24] In the vacuum the only way to decelerate from that speed is to use a rocket engine.

The stages of landing can include:[25][26]

  1. Descent orbit insertion – the spacecraft enters an orbit favorable for final descent. This stage was not present in the early landing efforts, which did not begin with lunar orbit. Such missions began on a lunar impact trajectory instead.[24]
  2. Descent and braking – the spacecraft fires its engines until it is no longer in orbit. If the engines were to stop firing entirely at this stage the spacecraft would eventually impact the surface. During this stage, the spacecraft uses its rocket engine to reduce overall speed
  3. Final approach – The spacecraft is nearly at the landing site, and final adjustments for the exact location of touchdown can be made
  4. Touchdown – the spacecraft achieves soft landing on the Moon

Touchdown

Lunar landings typically end with the engine shutting down when the lander is several feet above the lunar surface. The idea is that engine exhaust and lunar regolith can cause problems if they were to be kicked back from the surface to the spacecraft, and thus the engines cut off just before touchdown. Engineers must ensure that the vehicle is protected enough to ensure that the fall without thrust does not cause damage.

The first soft lunar landing, performed by the Soviet Luna 9 probe, was achieved by first slowing the spacecraft to a suitable speed and altitude, then ejecting a payload containing the scientific experiments. The payload was stopped on the lunar surface using airbags, which provided cushioning as it fell.[27] Luna 13 used a similar method.[28]

Airbag methods are not typical. For example, NASA's Surveyor 1 probe, launched around the same time as Luna 9, did not use an airbag for final touchdown. Instead, after it arrested its velocity at an altitude of 3.4m it simply fell to the lunar surface. To accommodate the fall the spacecraft was equipped with crushable components that would soften the blow and keep the payload safe.[24] More recently, the Chinese Chang'e 3 lander used a similar technique, falling 4m after its engine shut down.[29]

Perhaps the most famous lunar landers, those of the Apollo Program, were robust enough to handle the drop once their contact probes detected that landing was imminent. The landing gear was designed to withstand landings with engine cut-out at up to 10 feet (3.0 m) of height, though it was intended for descent engine shutdown to commence when one of the 67-inch (170 cm) probes touched the surface. During Apollo 11 Neil Armstrong however touched down very gently by firing the engine until touchdown; some later crews shut down the engine before touchdown and felt noticeable bumps on landing, with greater compression of the landing struts.[30][31]

Notes

  1. "Time-span" in this case begins in the year that the relevant program launched its first lunar landing attempt.

See also

References

  1. Lunar Lander Stage Requirements Based on the Civil Needs Data Base (PDF). John A. Mulqueen. NASA Marshall Space Flight Center. 1993.
  2. "India Admits Its Moon Lander Crashed, Cites Problem with Braking Thrusters". 26 November 2019. https://www.space.com/india-admits-moon-lander-crash.html. 
  3. Jones, Andrew (20 August 2023). "Luna-25 crashes into moon after orbit maneuver". SpaceNews. https://spacenews.com/luna-25-crashes-into-moon-after-orbit-maneuver/. 
  4. https://global.jaxa.jp/press/2023/12/20231205-1_e.html
  5. Chang, Kenneth (2024-01-19). "Japan Becomes Fifth Country to Land on the Moon". The New York Times. https://www.nytimes.com/live/2024/01/12/science/japan-moon-landing-slim. 
  6. "According to the telemetry data, SLIM’s solar cells are facing west. So if sunlight begins to shine on the lunar surface from the west, there is a possibility of generating power, and we are preparing for recovery. #SLIM can operate with power only from the solar cells. #JAXA". https://x.com/SLIM_JAXA/status/1749320575103995954?s=20. 
  7. 7.0 7.1 Sample, Ian (2024-01-19). "Japan’s Slim spacecraft lands on moon but struggles to generate power" (in en-GB). The Guardian. ISSN 0261-3077. https://www.theguardian.com/science/2024/jan/19/japan-slim-spacecraft-lands-on-moon-but-struggles-to-generate-power. 
  8. (in en) 小型月着陸実証機(SLIM)および小型プローブ(LEV)の月面着陸の結果・成果等 の記者会見, https://www.youtube.com/watch?v=U61i0wN01Uk, retrieved 2024-01-25 
  9. Jones, Andrew (2024-01-22). "Japan’s moon lander forced to power down but may yet be revived" (in en-US). https://spacenews.com/japans-moon-lander-forced-to-power-down-but-may-yet-be-revived/. 
  10. "SLIM Project Press Kit". https://global.jaxa.jp/countdown/slim/SLIM-mediakit-EN_2308.pdf. 
  11. (in en) 小型月着陸実証機(SLIM)および小型プローブ(LEV)の月面着陸の結果・成果等 の記者会見, https://www.youtube.com/watch?v=U61i0wN01Uk, retrieved 2024-01-25 
  12. Foust, Jeff (8 January 2024). "Peregrine lander suffers anomaly after launch". SpaceNews. https://spacenews.com/peregrine-lander-suffers-anomaly-after-launch/. 
  13. (in en) 小型月着陸実証機(SLIM)および小型プローブ(LEV)の月面着陸の結果・成果等 の記者会見, https://www.youtube.com/watch?v=U61i0wN01Uk, retrieved 2024-01-25 
  14. Brown, Katherine (2021-04-16). "NASA Picks SpaceX to Land Next Americans on Moon". http://www.nasa.gov/press-release/as-artemis-moves-forward-nasa-picks-spacex-to-land-next-americans-on-moon. 
  15. Andrew Jones (27 February 2023). "China unveils lunar lander to put astronauts on the moon". spacenews.com. https://spacenews.com/china-unveils-lunar-lander-to-put-astronauts-on-the-moon/. 
  16. Robotic Lunar Lander , NASA, 2010, accessed 2011-01-10.
  17. Wertz, James; Larson, Wiley (2003). Space Mission Analysis and Design (3rd ed.). California: Microcosm Press. ISBN 1-881883-10-8. 
  18. 18.0 18.1 Okishio, Shogo; Nagano, Hosei; Ogawa, Hiroyuki (December 2015). "A proposal and verification of the lunar overnight method by promoting the heat exchange with regolith". Applied Thermal Engineering 91 (5): 1176–1186. doi:10.1016/j.applthermaleng.2015.08.071. 
  19. "MSL Landing Special – MSL – Mars Science Laboratory". https://spaceflight101.com/msl/msl-landing-special/. 
  20. "NASA - NSSDCA - Spacecraft - Details". https://nssdc.gsfc.nasa.gov/nmc/spacecraft/display.action?id=1967-035A. 
  21. Cole, E.G. (November 1965). "Design and Development of the Apollo Three‐Man Spacecraft With Two‐Man Lunar Excursion Module (LEM)". Annals of the New York Academy of Sciences 134 (1): 39–57. doi:10.1111/j.1749-6632.1965.tb56141.x. Bibcode1965NYASA.134...39C. 
  22. Hager, P; Klaus, D; Walter, U (March 2014). "Characterizing transient thermal interactions between lunar regolith and surface spacecraft". Planetary and Space Science 92: 101–116. doi:10.1016/j.pss.2014.01.011. Bibcode2014P&SS...92..101H. 
  23. Gilmore, D. G. (2003). Spacecraft Thermal Control Handbook (2nd ed.). Segundo, California: Aerospace Press. ISBN 1-884989-11-X. 
  24. 24.0 24.1 24.2 "NASA - NSSDCA - Spacecraft - Details". https://nssdc.gsfc.nasa.gov/nmc/spacecraft/display.action?id=1966-045A. 
  25. "Apollo 11 Mission Overview". 2015-04-17. https://www.nasa.gov/mission_pages/apollo/missions/apollo11.html. 
  26. "Chang'e 3 – Change". https://spaceflight101.com/change/change-3/. 
  27. "NASA - NSSDCA - Spacecraft - Details". https://nssdc.gsfc.nasa.gov/nmc/spacecraft/display.action?id=1966-006A. 
  28. "The Mission of Luna 13: Christmas 1966 on the Moon". 2016-12-24. https://www.drewexmachina.com/2016/12/24/the-mission-of-luna-13-christmas-1966-on-the-moon/. 
  29. Rincon, Paul (2013-12-14). "China puts Jade Rabbit rover on Moon". BBC News. https://www.bbc.com/news/science-environment-25356603. 
  30. Jones, Eric M., ed (1995). "The First Lunar Landing". Apollo 11 Lunar Surface Journal. NASA. http://www.hq.nasa.gov/alsj/a11/a11.landing.html. 
  31. "Lunar Surface Sensing Probes". http://heroicrelics.org/info/lm/lunar-surface-probe.html.