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	] ''Eagle'']]		] ''Eagle'']]
	A '''~~Lunar~~ lander''' or '''Moon lander''' is a kind of ] designed to conduct a ], the most well known example being the ~~]'s~~ ].		A '''lunar lander''' or '''Moon lander''' is a kind of ] designed to conduct a ], the most well known example being the ].

	The design requirements for these landers depend on factors imposed by the payload characteristics and purpose, flight rate, propulsive requirements, and configuration constraints.<ref>. (PDF). John A. Mulqueen. NASA Marshall Space Flight Center. 1993.</ref> Other important design factors include overall energy requirements, mission duration, the type of mission operations on the lunar surface, and ] if crewed. The relatively high gravity and lack of lunar atmosphere negates the use of ], so a lander must use propulsion to decelerate and achieve a ].		The design requirements for these landers depend on factors imposed by the payload characteristics and purpose, flight rate, propulsive requirements, and configuration constraints.<ref> (PDF). John A. Mulqueen. NASA Marshall Space Flight Center. 1993.</ref> Other important design factors include overall energy requirements, mission duration, the type of mission operations on the lunar surface, and ] if crewed. The relatively high ] and lack of ] negates the use of ], so a lander must use propulsion to decelerate and achieve a ].

	Several studies indicate the potential for both scientific and technological benefits from sustained lunar surface exploration that would culminate in the utilization of lunar resources, or in the development of the necessary technology to land payloads on other planets in the ].<ref name='Hopkins 2006'>. (PDF) Bonnie M. Birckenstaedt, Josh Hopkins, Bernard F. Kutter, Frank Zegler, Todd Mosher. ''Lockheed Martin Space Systems Company''. 20006.</ref>		Several studies indicate the potential for both scientific and technological benefits from sustained lunar surface exploration that would culminate in the utilization of lunar resources, or in the development of the necessary technology to land payloads on other planets in the ].<ref name='Hopkins 2006'> (PDF). Bonnie M. Birckenstaedt, Josh Hopkins, Bernard F. Kutter, Frank Zegler, Todd Mosher. ''Lockheed Martin Space Systems Company''. 20006.</ref>

	==Challenges unique to lunar landing==		==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 ]—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 ].<ref name="smad">{{cite book \|last1=Wertz \|first1=James \|last2=Larson \|first2=Wiley \|title=Space Mission Analysis and Design \|date=2003 \|publisher=Microcosm Press \|location=California \|isbn=1-881883-10-8 \|edition=3rd}}</ref> In addition, the Moon has a long ]. 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.<ref name=Okishio>{{cite journal \|last1=Okishio \|first1=Shogo \|last2=Nagano \|first2=Hosei \|last3=Ogawa \|first3=Hiroyuki \|title=A proposal and verification of the lunar overnight method by promoting the heat exchange with regolith \|journal=Applied Thermal Engineering \|date=December 2015 \|volume=91 \|issue=5 \|pages=1176–1186 \|doi=10.1016/j.applthermaleng.2015.08.071 }}</ref>
	As of 2019, landings have been achieved on several Solar System bodies. These can be broadly broken into two categories – landings on bodies large enough for gravity to be a significant factor, and landings on asteroids.

⚫	Landing on any Solar System body comes with challenges unique to that body. The Moon has relatively high gravity compared to that of asteroids, ~~and~~ no atmosphere. Practically, this means that the only method of descent and landing that can provide sufficient thrust with current technology is chemical ~~rocket-based~~.<ref name="smad">{{cite book \|last1=Wertz \|first1=James \|last2=Larson \|first2=Wiley \|title=Space Mission Analysis and Design \|date=2003 \|publisher=Microcosm Press \|location=California \|isbn=1-881883-10-8 \|edition=3rd}}</ref> 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.<ref name=Okishio>{{cite journal \|last1=Okishio \|first1=Shogo \|last2=Nagano \|first2=Hosei \|last3=Ogawa \|first3=Hiroyuki \|title=A proposal and verification of the lunar overnight method by promoting the heat exchange with regolith \|journal=Applied Thermal Engineering \|date=December 2015 \|volume=91 \|issue=5 \|pages=1176–1186 \|doi=10.1016/j.applthermaleng.2015.08.071 }}</ref>

	===Lack of atmosphere===		===Lack of atmosphere===
	To ~~date~~, space probes have landed on all three bodies other than Earth that have solid surfaces and thick enough ~~atmospheres~~ to make aerobraking possible - ], ], and ]. These probes were able to leverage the atmospheres of the bodies on which they landed, ~~and~~ ~~could~~ ~~descend~~ using parachutes ~~and~~ ~~much~~ ~~less~~ fuel. ~~The~~ ~~upshot~~ is ~~that~~ larger ~~payload~~ ~~could~~ be landed on these bodies for a given amount of fuel. For example, the ~~Mars~~ ~~Science~~ ~~Laboratory~~ ~~landed~~ ~~the~~ ~~Curiosity~~ ~~rover,~~ ~~which~~ ~~weighed~~ ~~approximately~~ ~~900 kg,~~ ~~and~~ ~~had~~ a mass (at the time of Mars atmospheric entry) of 2400 kg,<ref>{{cite web \|url=http://spaceflight101.com/msl/msl-landing-special/\|title=MSL Landing Special – MSL – Mars Science Laboratory}}</ref> of which only 390 kg was fuel. In comparison, the much lighter (292 kg) Surveyor 3 landed on the ~~moon~~ using nearly 700 kg of fuel.<ref>{{cite web \|url=https://nssdc.gsfc.nasa.gov/nmc/spacecraft/display.action?id=1967-035A\|title = NASA - NSSDCA - Spacecraft - Details}}</ref> The lack of an atmosphere, however, ~~also~~ removes the need for a ~~moon~~ lander to have a heat shield and aerodynamics ~~are~~ ~~not~~ a ~~factor~~ in ~~its~~ ~~design~~.		{{As of\|2019\|post=,}} space probes have landed on all three bodies other than Earth that have solid surfaces and atmospheres thick enough to make aerobraking possible: ], ], and ]. 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 ] was landed on Mars by ] having a mass (at the time of Mars atmospheric entry) of 2400 kg,<ref>{{cite web \|url=http://spaceflight101.com/msl/msl-landing-special/\|title=MSL Landing Special – MSL – Mars Science Laboratory}}</ref> of which only 390 kg was fuel. In comparison, the much lighter (292 kg) ] landed on the Moon in 1967 using nearly 700 kg of fuel.<ref>{{cite web \|url=https://nssdc.gsfc.nasa.gov/nmc/spacecraft/display.action?id=1967-035A\|title = NASA - NSSDCA - Spacecraft - Details}}</ref> The lack of an atmosphere, however, removes the need for a Moon lander to have a heat shield and also allows ] to be disregarded when designing the craft.

	===High gravity===		===High gravity===
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	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.<ref>{{cite journal \|last1=Cole \|first1=E.G. \|title=Design and Development of the Apollo Three‐Man Spacecraft With Two‐Man Lunar Excursion Module (LEM) \|journal=Annals of the New York Academy of Sciences \|volume=134 \|issue=1 \|date=November 1965 \|pages=39–57 \|doi=10.1111/j.1749-6632.1965.tb56141.x }}</ref>		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.<ref>{{cite journal \|last1=Cole \|first1=E.G. \|title=Design and Development of the Apollo Three‐Man Spacecraft With Two‐Man Lunar Excursion Module (LEM) \|journal=Annals of the New York Academy of Sciences \|volume=134 \|issue=1 \|date=November 1965 \|pages=39–57 \|doi=10.1111/j.1749-6632.1965.tb56141.x }}</ref>

	===Thermal ~~Environment~~===		===Thermal environment===
	The ~~Lunar~~ thermal environment is influenced by the length of the ~~Lunar~~ day. Temperatures can swing between 25K (during the ~~Lunar~~ night) to 390K (during the ~~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.<ref>{{cite journal \|last1=Hager \|first1=P \|last2=Klaus \|first2=D \|last3=Walter \|first3=U \|title=Characterizing transient thermal interactions between lunar regolith and surface spacecraft \|journal=Planetary and Space Science \|date=March 2014 \|volume=92 \|pages=101–116 \|doi=10.1016/j.pss.2014.01.011 }}</ref> In contrast, most spacecraft instruments must be kept within a much stricter range of between 233K and 323K.<ref>{{cite book \|last1=Gilmore \|first1=D. G. \|title=Spacecraft Thermal Control Handbook \|date=2003 \|publisher=Aerospace Press \|location=Segundo, California \|isbn=1-884989-11-X \|edition=2nd}}</ref> This means that the lander must cool and heat its instruments.		The lunar thermal environment is influenced by the length of the lunar day. Temperatures can swing between 25K (during the lunar night) to 390K (during the 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.<ref>{{cite journal \|last1=Hager \|first1=P \|last2=Klaus \|first2=D \|last3=Walter \|first3=U \|title=Characterizing transient thermal interactions between lunar regolith and surface spacecraft \|journal=Planetary and Space Science \|date=March 2014 \|volume=92 \|pages=101–116 \|doi=10.1016/j.pss.2014.01.011 }}</ref> In contrast, most spacecraft instruments must be kept within a much stricter range of between 233K and 323K.<ref>{{cite book \|last1=Gilmore \|first1=D. G. \|title=Spacecraft Thermal Control Handbook \|date=2003 \|publisher=Aerospace Press \|location=Segundo, California \|isbn=1-884989-11-X \|edition=2nd}}</ref> This means that the lander must cool and heat its instruments.

	The length of the ~~Lunar~~ night makes it difficult to use solar electric power to heat the instruments, and nuclear heaters are often used.<ref name=Okishio/>		The length of the lunar night makes it difficult to use solar electric power to heat the instruments, and nuclear heaters are often used.<ref name=Okishio/>

	==Landing stages==		==Landing stages==
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	The stages of landing can include:<ref>{{cite web \|url=https://www.nasa.gov/mission_pages/apollo/missions/apollo11.html\|title=Apollo 11 Mission Overview\|date=2015-04-17}}</ref><ref>{{cite web \|url=http://spaceflight101.com/change/change-3/\|title=Chang'e 3 – Change}}</ref>		The stages of landing can include:<ref>{{cite web \|url=https://www.nasa.gov/mission_pages/apollo/missions/apollo11.html\|title=Apollo 11 Mission Overview\|date=2015-04-17}}</ref><ref>{{cite web \|url=http://spaceflight101.com/change/change-3/\|title=Chang'e 3 – Change}}</ref>

	# 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.<ref name="nssdc.gsfc.nasa.gov"/>		# 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.<ref name="nssdc.gsfc.nasa.gov"/>
	# 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		# 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
	# Final approach – The spacecraft is nearly at the landing site, and final adjustments for the exact location of touchdown can be made		# Final approach – The spacecraft is nearly at the landing site, and final adjustments for the exact location of touchdown can be made
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	===Touchdown===		===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.		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 ] 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 ] 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.<ref>{{cite web \|title=Nasa: Luna 9 \|url=https://nssdc.gsfc.nasa.gov/nmc/spacecraft/display.action?id=1966-006A}}</ref> ] used a similar method.<ref>{{cite web \|url=https://www.drewexmachina.com/2016/12/24/the-mission-of-luna-13-christmas-1966-on-the-moon/\|title=The Mission of Luna 13: Christmas 1966 on the Moon\|date=2016-12-24}}</ref>		The first soft lunar landing, performed by the Soviet ] 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.<ref>{{cite web \|title=Nasa: Luna 9 \|url=https://nssdc.gsfc.nasa.gov/nmc/spacecraft/display.action?id=1966-006A}}</ref> ] used a similar method.<ref>{{cite web \|url=https://www.drewexmachina.com/2016/12/24/the-mission-of-luna-13-christmas-1966-on-the-moon/\|title=The Mission of Luna 13: Christmas 1966 on the Moon\|date=2016-12-24}}</ref>

	Airbag methods are not typical. For example, NASA's ] 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.<ref name="nssdc.gsfc.nasa.gov"/> More recently, the Chinese ] lander used a similar technique, falling 4m after its engine shut down.<ref>{{cite news \|url=https://www.bbc.com/news/science-environment-25356603\|title=China puts Jade Rabbit rover on Moon\|work=BBC News\|date=2013-12-14\|last1=Rincon\|first1=Paul}}</ref> Perhaps the most famous lunar landers, those of the ], were robust enough to handle the drop once their contact probes detected that landing was imminent. ]'s lunar lander, for example, contacted the surface with its probe at 1.6m above the ~~Lunar~~ surface, at which point the engine was shut down and the spacecraft fell the remaining distance.<ref>{{cite web \|url=http://heroicrelics.org/info/lm/lunar-surface-probe.html\|title=Lunar Surface Sensing Probes}}</ref>		Airbag methods are not typical. For example, NASA's ] 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.<ref name="nssdc.gsfc.nasa.gov"/> More recently, the Chinese ] lander used a similar technique, falling 4m after its engine shut down.<ref>{{cite news \|url=https://www.bbc.com/news/science-environment-25356603\|title=China puts Jade Rabbit rover on Moon\|work=BBC News\|date=2013-12-14\|last1=Rincon\|first1=Paul}}</ref> Perhaps the most famous lunar landers, those of the ], were robust enough to handle the drop once their contact probes detected that landing was imminent. ]'s lunar lander, for example, contacted the surface with its probe at 1.6m above the lunar surface, at which point the engine was shut down and the spacecraft fell the remaining distance.<ref>{{cite web \|url=http://heroicrelics.org/info/lm/lunar-surface-probe.html\|title=Lunar Surface Sensing Probes}}</ref>

	==Examples==		==Examples==

	Examples of lunar landers or programs to design lunar landers include:		Examples of lunar landers or programs to design lunar landers include:
	* ], an ] mission to send an autonomous lander to the ~~moon~~		* ], an ] mission to send an autonomous lander to the Moon
	* ], a competition to produce VTVL vehicles with sufficient delta-v to fly from the Moon to orbit		* ], a competition to produce VTVL vehicles with sufficient delta-v to fly from the Moon to orbit
	* ], used for the 1969–1972 human spaceflight program of the United States		* ], used for the 1969–1972 human spaceflight program of the United States

Revision as of 17:34, 26 November 2019

For other uses, see Lunar lander (disambiguation).

This article is missing information about the science and engineering required to land a spacecraft on the Moon, along with examples of how they are approached in various lander projects. Please expand the article to include this information. Further details may exist on the talk page. (September 2018)

A lunar lander or Moon lander is a kind of lander designed to conduct a Moon landing, the most well known example being the Apollo Lunar Module.

The design requirements for these landers depend on factors imposed by the payload characteristics and purpose, flight rate, propulsive requirements, and configuration constraints. 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 and lack of lunar atmosphere negates the use of aerobraking, so a lander must use propulsion to decelerate and achieve a soft landing.

Several studies indicate the potential for both scientific and technological benefits from sustained lunar surface exploration that would culminate in the utilization of lunar resources, or in the development of the necessary technology to land payloads on other planets in the Solar System.

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. 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.

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, 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. 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 an 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.

Thermal environment

The lunar thermal environment is influenced by the length of the lunar day. Temperatures can swing between 25K (during the lunar night) to 390K (during the 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. In contrast, most spacecraft instruments must be kept within a much stricter range of between 233K and 323K. This means that the lander must cool and heat its instruments.

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

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. In the vacuum the only way to slow down from that speed is to use a rocket engine.

The stages of landing can include:

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.
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
Final approach – The spacecraft is nearly at the landing site, and final adjustments for the exact location of touchdown can be made
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. Luna 13 used a similar method.

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. More recently, the Chinese Chang'e 3 lander used a similar technique, falling 4m after its engine shut down. 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. Apollo 11's lunar lander, for example, contacted the surface with its probe at 1.6m above the lunar surface, at which point the engine was shut down and the spacecraft fell the remaining distance.

Examples

Examples of lunar landers or programs to design lunar landers include:

Lunar Lander (space mission), an ESA mission to send an autonomous lander to the Moon
Lunar Lander Challenge, a competition to produce VTVL vehicles with sufficient delta-v to fly from the Moon to orbit
Apollo Lunar Module, used for the 1969–1972 human spaceflight program of the United States
LK Lander, designed for the human spaceflight program of the Soviet Union
Altair (spacecraft), a proposed spacecraft for the Constellation program previously known as the Lunar Surface Access Module
Luna programme, lander spacecraft used by the Soviet Union for robotic exploration of the Moon
Luna-Glob, a lunar exploration program by the Russian Federal Space Agency
Lockheed Martin Lunar Lander, proposed lunar lander for Moon Missions under Project Artemis.
Mighty Eagle lander (previously called NASA Robotic Lunar Lander) current NASA program for developing a new generation of small, autonomous lunar landers
Surveyor Program, lander spacecraft used by the United States for robotic exploration of the Moon
Project Morpheus, a NASA research and development program test bed
XEUS A human rated lunar lander being developed by United Launch Alliance and Masten Space Systems
Boeing Lunar Lander is a proposal for a human landing system for NASA's Artemis program
Blue Origin, Lockheed Martin, Northrop Grumman and Draper Laboratory proposed a human landing system for NASA's Artemis program

References

Lunar Lander Stage Requirements Based on the Civil Needs Data Base (PDF). John A. Mulqueen. NASA Marshall Space Flight Center. 1993.
Lunar Lander Configurations Incorporating Accessibility, Mobility, and Centaur Cryogenic Propulsion Experience (PDF). Bonnie M. Birckenstaedt, Josh Hopkins, Bernard F. Kutter, Frank Zegler, Todd Mosher. Lockheed Martin Space Systems Company. 20006.
Wertz, James; Larson, Wiley (2003). Space Mission Analysis and Design (3rd ed.). California: Microcosm Press. ISBN 1-881883-10-8.
^ 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.
"MSL Landing Special – MSL – Mars Science Laboratory".
"NASA - NSSDCA - Spacecraft - Details".
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.
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.
Gilmore, D. G. (2003). Spacecraft Thermal Control Handbook (2nd ed.). Segundo, California: Aerospace Press. ISBN 1-884989-11-X.
^ "NASA - NSSDCA - Spacecraft - Details".
"Apollo 11 Mission Overview". 2015-04-17.
"Chang'e 3 – Change".
"Nasa: Luna 9".
"The Mission of Luna 13: Christmas 1966 on the Moon". 2016-12-24.
Rincon, Paul (2013-12-14). "China puts Jade Rabbit rover on Moon". BBC News.
"Lunar Surface Sensing Probes".
Robotic Lunar Lander, NASA, 2010, accessed 2011-01-10.

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