Lander (spacecraft)

A lander is a spacecraft that descends towards, and comes to rest on, the surface of an astronomical body.[1][page needed] In contrast to an impact probe, which makes a hard landing that damages or destroys the probe upon reaching the surface, a lander makes a soft landing after which the probe remains functional.

The Apollo 16 Extended Apollo Lunar Module, a lunar lander
Mars Polar Lander prep

For bodies with atmospheres, the landing occurs after atmospheric entry. In these cases, landers may employ parachutes to slow them down enough to maintain a low terminal velocity. In some cases, small landing rockets will be fired just before impact in order to reduce the lander's velocity. Landing may be accomplished by controlled descent and set down on landing gear, with the possible addition of a post-landing attachment mechanism (such as the mechanism used by Philae) for celestial bodies with low gravity. Some missions (for example, Luna 9 and Mars Pathfinder) used inflatable airbags to cushion the lander's impact rather than utilizing more traditional landing gear.

When a high velocity impact is intentionally planned in order to study the consequences of impact, the spacecraft is called an impactor.[2]

Several terrestrial bodies have been subject to lander or impactor exploration. Among them are Earth's Moon; the planets Venus, Mars, and Mercury; Saturn's moon Titan; and asteroids and comets.

LandersEdit

LunarEdit

 
The lunar surface through an Apollo Lunar Module window shortly after landing
 
Surveyor 3 on the Moon

Beginning with Luna 2 in 1959, the first few spacecraft to reach the lunar surface were impactors, not landers. They were part of the Soviet Luna program or the American Ranger program.

In 1966, the Soviet Luna 9 became the first spacecraft to achieve a lunar soft landing and to transmit photographic data to Earth. The American Surveyor program (1966–1968) was designed to determine where Apollo could land safely. As a result, these robotic missions required soft landers to sample the lunar soil and determine the thickness of the dust layer, which was unknown before Surveyor.

The U.S.-crewed Apollo Lunar Modules (1969–1972) with rovers (1971–1972) and late Soviet large robotic landers (1969–), Lunokhods (1970–1973) and sample return missions (1970–1976) used a rocket descent engine for a soft landing of astronauts and lunar rovers on the Moon.

The Altair spacecraft, previously known as the "Lunar Surface Access Module" or "LSAM", was the planned lander for the Constellation program prior to the cancellation of Project Constellation.

As of August 2012 NASA is developing vehicles that use a rocket descent engine permitting them to land on the Moon and other locations. These vehicles include the Mighty Eagle lander and the Morpheus lander. The Project Morpheus lander may have sufficient thrust to propel a crewed ascent stage.

Russia has plans for the Luna-Grunt mission to return samples from the Moon by 2021.

The Chinese Chang'e 3 mission and its Yutu ('Jade Rabbit') rover landed on 14 December 2013. In 2019, China's Chang'e 4 mission successfully landed the Yutu-2 rover on the far side of the Moon.[3] Chang'e 5 and Chang'e 6 are designed to be sample return missions.[4] Chang'e 5 is currently scheduled for 2020, while Chang'e 6 is planned for 2023[5] or 2024.[4]

Lander Vikram on Chandrayaan-2, a maiden soft landing effort by the Indian Space Research Organization, lost contact to control on 6 September 2019, some minutes before landing.[citation needed]

VenusEdit

The Soviet Venera program included a number of Venus landers, some of which were crushed during descent much as Galileo's Jupiter "lander" and others which successfully touched down. Venera 3 in 1966 and Venera 7 in 1970 became the first impact and soft landing on Venus respectively. The Soviet Vega program also placed two balloons in the Venusian atmosphere in 1985, which were the first aerial tools on other planets.

MarsEdit

The Soviet Union's Mars 1962B became the first Earth-based mission intended to impact on Mars in 1962. In 1971, the lander of the Mars 3 probe conducted the first soft landing on Mars, but communication was lost within a minute after touchdown, which occurred during one of the worst global dust storms since the beginning of telescopic observations of the Red Planet. Three other landers, Mars 2 in 1971 and Mars 5 and Mars 6 in 1973, either crashed or failed to even enter the planet's atmosphere. All four landers used an aeroshell-like heat shield during atmospheric entry. Mars 2 and Mars 3 landers carried the first small skis-walking Mars rovers that did not work on the planet.

The Soviet Union planned the heavy Marsokhod Mars 4NM mission in 1973 and the Mars sample return Mars 5NM mission in 1975, but neither occurred due to needing the N1 super-launcher that was never flown successfully. A double-launching Soviet Mars 5M (Mars-79) sample return mission was planned for 1979 but cancelled due to complexity and technical problems.

First "clear" image ever transmitted from the surface of Mars – shows rocks near the Viking 1 lander (July 20, 1976)

Viking 1 and Viking 2 were launched respectively in August and September 1975, each comprising an orbiter vehicle and a lander. Viking 1 landed in July 1976 and Viking 2 in September 1976. The Viking program rovers were the first successful, functioning Mars landers. The mission ended in May 1983, after both landers had died.

In the 1970s, the US planned the Voyager-Mars mission. This would have consisted of two orbiters and two landers, launched by a single Saturn V rocket, but the mission was cancelled.

Mars 96 was the first complex post-Soviet Russian mission with an orbiter, lander, and penetrators. Planned for 1996, it failed at launch. A planned repeat of this mission, Mars 98, was cancelled due to lack of funding.

The U.S. Mars Pathfinder was launched in December 1996 and released the first acting rover on Mars, named Sojourner, in July 1997. It failed in September 1997, probably due to electronics failure caused by the cold temperatures. Mars Pathfinder was part of the canceled Mars Environmental Survey program with a set of 16 landers planned for 1999–2009.

 
The lander which brought the Spirit rover to the surface of Mars

The Mars Polar Lander ceased communication on 3 December 1999 prior to reaching the surface and is presumed to have crashed.

The European Beagle 2 lander deployed successfully from the Mars Express spacecraft but the signal confirming a landing which should have come on 25 December 2003 was not received. No communication was ever established and Beagle 2 was declared lost on 6 February 2004. The proposed 2009 British Beagle 3 lander mission to search for life, past or present, was not adopted.

The French/ESA NetLander mission for 2007 or 2009, with an orbiter and 4 landers, was canceled because it was too expensive. Its successor, a multi-lander mission for 2011–2019 called Mars MetNet, was not adopted by the ESA.

The American Mars Exploration Rovers Spirit and Opportunity were launched in June and July 2003. They reached the Martian surface in January 2004 using landers featuring airbags and parachutes to soften impact. Spirit ceased functioning in 2010, more than five years past its design lifetime.[6] As of 13 February 2017, Opportunity was declared effectively dead, having exceeded its three-month design lifetime by well over a decade.[7]

The U.S. spacecraft Phoenix successfully achieved soft landing on the surface of Mars on 25 May 2008, using a combination of parachutes and rocket descent engines.

Mars Science Laboratory, which carried the rover Curiosity, was successfully launched by NASA on 26 November 2011. It landed in the Aeolis Palus region of Gale Crater on Mars on 6 August 2012.

Planned for 2018, NASA's Mars Astrobiology Explorer-Cacher lander mission was canceled due to budget cuts.

Exploration of Mars including the use of landers continues to this day. Amongst them, Russia has planned a Mars sample return mission Mars-Grunt for around 2026, and China for around 2030.

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 Interactive image map of the global topography of Mars, overlain with locations of Mars landers and rovers. Hover over the image to see the names of over 60 prominent geographic features, and click to link to them. Coloring of the base map indicates relative elevations, based on data from the Mars Orbiter Laser Altimeter on NASA's Mars Global Surveyor. Whites and browns indicate the highest elevations (+12 to +8 km); followed by pinks and reds (+8 to +3 km); yellow is 0 km; greens and blues are lower elevations (down to −8 km). Axes are latitude and longitude; Polar regions are noted.
(   Rover  Lander  Future )

Martian moonsEdit

While several flybys conducted by Mars orbiting probes have provided images and other data about the Martian moons Phobos and Deimos, only few of them intended to land on the surface of these satellites. Two probes under the Soviet Phobos program were successfully launched in 1988, but in 1989 the intended landings on Phobos and Deimos were not conducted due to failures in the spacecraft system. The post-Soviet Russian Fobos-Grunt probe was an intended sample return mission to Phobos in 2012 but failed after launch in 2011.

In 2007 European Space Agency and EADS Astrium proposed and developed the mission to Phobos to 2016 with lander and sample return, but it stayed as a project. Since 2007 the Canadian Space Agency has considered a mission to Phobos called Phobos Reconnaissance and International Mars Exploration (PRIME), which would include an orbiter and lander. Recent proposals include a 2008 NASA Glenn Research Center Phobos and Deimos sample return mission, the 2013 Phobos Surveyor, and the OSIRIS-REx II mission concept.

The Japanese Aerospace Exploration Agency (JAXA) plans to launch the Martian Moons Exploration (MMX) mission in 2024, a sample return mission targeting Phobos.[8] MMX will land and collect samples from Phobos multiple times, along with deploying a rover jointly developed by CNES and the German Aerospace Center (DLR).[9] By using a corer sampling mechanism, the spacecraft aims to retrieve a minimum of 10 g of samples. MMX will return to Earth in 2029.[10]

Russia plans to repeat its Fobos-Grunt mission around 2024.

TitanEdit

 
Surface of Saturn's moon Titan as seen by the Huygens probe after landing in 2005

The Huygens probe, carried to Saturn's moon Titan by Cassini, was specifically designed to survive landing on land or on liquid. It was thoroughly drop-tested to make sure it could withstand impact and continue functioning for at least three minutes. However, due to the low-speed impact, it continued providing data for more than two hours after it landed. The landing on Titan in 2005 was the first landing on the planet's satellites outside the Moon.

The proposed U.S. Titan Mare Explorer (TiME) mission considered a lander that would splash down in a lake in Titan's northern hemisphere and float on the surface of the lake for few months. Spain's proposed Titan Lake In-situ Sampling Propelled Explorer (TALISE) mission is similar to the TiME lander but has its own propulsion system for controlling shipping.

Comets and asteroidsEdit

Vesta, the multi-aimed Soviet mission, was developed in cooperation with European countries for realization in 1991–1994 but canceled due to the Soviet Union disbanding. It included a flyby of Mars, where Vesta would deliver an aerostat (balloon or airship) and small landers or penetrators, followed by flybys of Ceres or 4 Vesta and some other asteroids with the impact of a large penetrator on one of them.[clarification needed]

NASA's canceled Comet Rendezvous Asteroid Flyby mission considered the launch in 1995 and landing of penetrators on a comet's nucleus in 2001.

The first landing on a small Solar System body (an object in the Solar System that is not a moon, planet, or dwarf planet) was performed in 2001 by the probe NEAR Shoemaker at asteroid 433 Eros despite the fact that NEAR was not originally designed to be capable of landing.

The Hayabusa probe made several attempts to land on 25143 Itokawa in 2005 with mixed success, including a failed attempt to deploy a rover. Designed to rendezvous and land on a low-gravity body, Hayabusa became the second spacecraft to land on an asteroid, and in 2010 the first sample return mission from an asteroid.

The Rosetta probe, launched 2 March 2004, was the first robotic lander Philae on the comet Churyumov–Gerasimenko on 12 November 2014. Due to the extremely low gravity of such bodies, the landing system included a harpoon launcher intended to anchor a cable in the comet's surface and pull the lander down.

Japan (JAXA) launched the Hayabusa 2 asteroid space probe in 2014 to deliver several landing parts (including Minerva II and German Mobile Asteroid Surface Scout (MASCOT) landers and a Small Carry-on Impactor (SCI) penetrator) in 2018–2019 to return samples to Earth by 2020.

NASA launched the OSIRIS-REx sample return mission to asteroid 101955 Bennu in 2016.

The ESA's AIDA mission concept would investigate the effects of impact crashing a spacecraft into an asteroid.

The Chinese Space Agency is designing a sample retrieval mission from Ceres that would take place during the 2020s.[11]

MercuryEdit

Launched in October 2018 and expected to reach Mercury in December 2025, ESA's BepiColombo mission to Mercury was originally designed to include the Mercury Surface Element (MSE). The lander would have carried a 7 kg payload consisting of an imaging system (a descent camera and a surface camera), a heat flow and physical properties package, an alpha particle X-ray spectrometer, a magnetometer, a seismometer, a soil penetrating device (mole), and a micro-rover. The MSE aspect of the mission was cancelled in 2003 due to budgetary constraints.[12]

Moons of JupiterEdit

 
Concept for a Europa lander

A few Jupiter probes provide many images and other data about its moons. Some proposed missions with landing on Jupiter's moons were canceled or not adopted. The small nuclear-powered Europa lander was proposed as part of NASA's Jupiter Icy Moons Orbiter (JIMO) mission that was canceled in 2006.

Currently, the ESA is planning to launch the Jupiter Icy Moon Explorer (JUICE) mission in 2022, which includes the Russian Ganymede Lander making a soft landing on Ganymede around 2033. In addition, NASA offered the ESA the opportunity to design a lander or impactor to fly alongside NASA's proposed orbiter in the Europa Clipper mission planned for 2025. As Europa is hypothesized to have water beneath its icy surface, missions are sent to investigate its habitability and assess its astrobiological potential by confirming the existence of water on the moon and determining the water's characteristics. Despite the high radiation environment around Europa and Jupiter, which would cause issues for robotic surface missions, NASA's Europa Lander mission is still under consideration and there is steady lobbying for future missions. Russia's Laplace-P was proposed to be included as a part of the now-canceled joint NASA/ESA Europa Jupiter System Mission (EJSM)/Laplace mission but remains an option for future missions. Another proposal calls for a large nuclear-powered "melt probe" (cryobot) that would melt through the ice until it reached an ocean below where it would deploy an autonomous underwater vehicle (AUV or "hydrobot") that would gather information.

ImpactorsEdit

 
The collision of comet 9P/Tempel and the Deep Impact probe

Deep Space 2Edit

The Deep Space 2 impactor probe was to be the first spacecraft to penetrate below the surface of another planet. However, the mission failed with the loss of its mother ship, Mars Polar Lander, which lost communication with Earth during entry into Mars' atmosphere on 3 December 1999.

Deep ImpactEdit

Comet Tempel 1 was visited by NASA's Deep Impact probe on 4 July 2005. The impact crater formed was approximately 200 m wide and 30–50 m deep, and scientists detected the presence of silicates, carbonates, smectite, amorphous carbon and polycyclic aromatic hydrocarbons.

Moon Impact ProbeEdit

The Moon Impact Probe (MIP) developed by the Indian Space Research Organisation (ISRO), India's national space agency, was a lunar probe that was released on 14 November 2008 by ISRO's Chandrayaan-1 lunar remote sensing orbiter. Chandrayaan-1 was launched on 22 October 2008. It led to the discovery of the presence of water on the Moon.[13][14]

LCROSSEdit

The Lunar Crater Observation and Sensing Satellite (LCROSS) was a robotic spacecraft operated by NASA to perform a lower-cost means of determining the nature of hydrogen detected at the polar regions of the Moon.[15] The main LCROSS mission objective was to explore the presence of water ice in a permanently shadowed crater near a lunar polar region.[16] LCROSS was launched together with the Lunar Reconnaissance Orbiter (LRO) on 18 June 2009, as part of the shared Lunar Precursor Robotic Program. LCROSS was designed to collect and relay data from the impact and debris plume resulting from the launch vehicle's spent Centaur upper rocket stage striking the crater Cabeus near the south pole of the Moon. Centaur impacted successfully on 9 October 2009, at 11:31 UTC. The "shepherding spacecraft" (carrying the LCROSS mission payload)[17] descended through Centaur's plume of debris, and collected and relayed data before impacting six minutes later at 11:37 UTC. The project was successful in discovering water in Cabeus.[18]

MESSENGEREdit

The NASA MESSENGER (Mercury Surface, Space Environment, Geochemistry, and Ranging) mission to Mercury launched on 3 August 2004 and entered orbit around the planet on 18 March 2011. Following a mapping mission, MESSENGER was directed to impact Mercury's surface on 30 April 2015. The spacecraft's impact with Mercury occurred near 3:26 pm EDT on 30 April 2015, leaving a crater estimated to be 16 m in diameter.

See alsoEdit

ReferencesEdit

  1. ^ Ball, Andrew; Garry, James; Lorenz, Ralph; Kerzhanovich, Viktor (May 2007). Planetary Landers and Entry Probes. Cambridge University Press. ISBN 9780521820028.
  2. ^ Davis, Phil; Munsell, Kirk (23 January 2009). "Technology – Impactor – The Plan". Deep Impact Legacy Site (archive). NASA/JPL. Archived from the original on 26 April 2009. Retrieved 22 April 2009.
  3. ^ Barbosa, Rui C. (3 January 2019). "China lands Chang'e-4 mission on the far side of the Moon". Archived from the original on 18 August 2020. Retrieved 18 August 2020.
  4. ^ a b Williams, David R. (12 December 2019). "Future Chinese Lunar Missions". NASA Goddard Space Flight Center. Archived from the original on 1 April 2020.
  5. ^ Pascale, Bresson; Sart, Raphaël. "State visit of President Macron to China – In 2023, Chang'e 6 will deploy the French DORN instrument on the Moon to study the lunar exosphere" (PDF) (Press release). CNES. Archived (PDF) from the original on 19 August 2020. Retrieved 18 August 2020.
  6. ^ "Meteorite Found on Mars Yields Clues About Planet's Past". NASA. 10 August 2009. Retrieved 8 September 2009.
  7. ^ "Opportunity Status". NASA. Retrieved 19 August 2014.
  8. ^ Clark, Stephen (20 November 2017). "NASA confirms contribution to Japanese-led Mars mission". Spaceflight Now.
  9. ^ Yamakawa, Hiroshi; Le Gall, Jean-Yves; Ehrenfreund, Pascale; Dittus, Hansjörg (3 October 2018). "Joint Statement with Centre National d'Etudes Spatiales (CNES) and German Aerospace Center (DLR) regarding Martian Moons eXploration" (PDF) (Press release). JAXA. Retrieved 30 October 2018.
  10. ^ Fujimoto, Masaki (11 January 2017). "JAXA's exploration of the two moons of Mars, with sample return from Phobos" (PDF). Lunar and Planetary Institute. Retrieved 23 March 2017.
  11. ^ Zou Yongliao; Li Wei; Ouyang Ziyuan. "China's Deep-space Exploration to 2030" (PDF). Chinese Academy of Sciences. pp. 12–13.
  12. ^ "N° 75–2003: Critical decisions on Cosmic Vision". European Space Agency. 7 November 2003.
  13. ^ "MIP detected water on Moon way back in June: ISRO Chairman". The Hindu. Bangalore. 25 September 2009. Retrieved 9 June 2013.
  14. ^ "Chandrayaan first discovered water on moon, but..." Daily News and Analysis. Bangalore. 25 September 2009. Retrieved 9 June 2013.
  15. ^ Tompkins, Paul D.; Hunt, Rusty; D'Ortenzio, Matt D.; Strong, James; Galal, Ken; Bresina, John L.; Foreman, Darin; Barber, Robert; Shirley, Mark; Munger, James; Drucker, Eric. "Flight Operations for the LCROSS Lunar Impactor Mission". NASA. Ames Research Center. hdl:2060/20100026403.
  16. ^ "NASA – LCROSS: Mission Overview". NASA. Archived from the original on 5 May 2010. Retrieved 14 November 2009.
  17. ^ LRO/LCROSS Press Kit v2 (PDF) (Report). NASA. June 2009. Archived (PDF) from the original on 27 October 2009.
  18. ^ Dino, Jonas; Lunar CRater Observation and Sensing Satellite Team (13 November 2009). "LCROSS Impact Data Indicates Water on Moon". NASA. Archived from the original on 6 January 2010. Retrieved 14 November 2009.

External linksEdit

  Media related to Landers (spacecraft) at Wikimedia Commons