The Moon is a very slightly scalene
ellipsoid due to tidal stretching, with its long axis displaced 30° from facing the Earth, due to gravitational anomalies from impact basins. Its shape is more elongated than current tidal forces can account for. This 'fossil bulge' indicates that the Moon solidified when it orbited at half its current distance to the Earth, and that it is now too cold for its shape to restore
hydrostatic equilibrium at its current orbital distance. Today tidal crust deformation is limited to lobate thrust fault scarps formation.
Size and mass , several having
subsurface oceans and one,
Titan, having a considerable atmosphere. The Moon is the fifth largest (by size and mass) natural satellite of the Solar System. It is categorizable as a
planetary-mass moon, making it a satellite planet under the
geophysical definitions of the term. It is smaller than
Mercury but considerably larger than the largest
dwarf planet of the Solar System,
Pluto. The Moon is the largest natural satellite in the Solar System relative to its
primary planet. The Moon's diameter is about 3,500 km, more than one-quarter of Earth's, with the face of the Moon comparable to the width of
mainland Australia, Europe or the
contiguous United States. The whole surface area of the Moon is about 38 million square kilometers, comparable to that of the whole
Americas, the areas of the lunar hemispheres being comparable to the areas of
North America and
South America. The Moon's mass is of Earth's, It has a
geochemically distinct
crust,
mantle, and
core. The Moon has a solid iron-rich inner core with a radius possibly as small as and a fluid outer core primarily made of liquid iron with a radius of roughly . Around the core is a partially molten boundary layer with a radius of about . This structure is thought to have developed through the
fractional crystallization of a global magma ocean shortly after the Moon's formation 4.5 billion years ago. Crystallization of this magma ocean would have created a
mafic mantle from the
precipitation and sinking of the minerals
olivine,
clinopyroxene, and
orthopyroxene; after about three-quarters of the magma ocean had crystallized, lower-density
plagioclase minerals could form and float into a crust atop. The pressure at the lunar core is estimated to be .
Gravitational field jumping on the Moon, illustrating that the
gravitational pull of the Moon is approximately 1/6 of Earth's. The jumping height is limited by the EVA space suit's weight on the Moon of about and by the suit's pressurization resisting the bending of the suit, as needed for jumping. On average the Moon's
surface gravity is The anomalies greatly influence the
orbit of spacecraft about the Moon. There are some puzzles: lava flows by themselves cannot explain all of the gravitational signature, and some mascons exist that are not linked to mare volcanism. The
sphere of influence, of the Moon's gravity field, in which it dominates over Earth's has a
Hill radius of 60,000 km (i.e., extending less than one-sixth the distance of the 378,000 km between the Moon and the Earth), extending to the Earth-Moon
lagrange points. This space is called
cislunar space.
Magnetic field The Moon has
an external magnetic field of less than 0.2
nanoteslas, or less than one hundred thousandth
that of Earth. The Moon does not have a global
dipolar magnetic field and only has crustal magnetization likely acquired early in its history when a dynamo was still operating. Early in its history, 4 billion years ago, its magnetic field strength was likely close to that of Earth today. Additionally the Moon moves ~27% of the time, or 5–6 days per lunar month in Earth's
magnetotail, replacing
solar wind with
Earth wind.
Atmosphere observes levitating dust, a phenomenon named
Lunar horizon glow can be seen and "spot". The Moon has an
atmosphere consisting of only an
exosphere, which is so tenuous as to be nearly
vacuum, with a total mass of less than . The surface pressure of this small mass is around 3 × 10−15
atm (0.3
nPa); it varies with the lunar day. Its sources include
outgassing and
sputtering, a product of the bombardment of lunar soil by solar wind ions. Elements that have been detected include
sodium and
potassium, produced by sputtering (also found in the atmospheres of Mercury and
Io);
helium-4 and
neon from the solar wind; and
argon-40,
radon-222, and
polonium-210, outgassed after their creation by
radioactive decay within the crust and mantle. The absence of such neutral species (atoms or molecules) as
oxygen,
nitrogen,
carbon,
hydrogen and
magnesium, which are present in the
regolith, is not understood. Studies of Moon magma samples retrieved by the
Apollo missions demonstrate that the Moon had once possessed a relatively thick atmosphere for a period of 70 million years between 3 and 4 billion years ago. This atmosphere, sourced from gases ejected from lunar volcanic eruptions, was twice the thickness of that of present-day
Mars. The ancient lunar atmosphere was eventually stripped away by solar winds and dissipated into space.
Ionizing radiation from
cosmic rays, their resulting
neutron radiation, and the Sun results in an average radiation level of 1.369
millisieverts per day during lunar
daytime, For further comparison, radiation levels average about 1.84 millisieverts per day on a
flight to Mars and about 0.64 millisieverts per day on Mars itself, with some locations on Mars possibly having levels as low as 0.342 millisieverts per day. Solar radiation also
electrically charges the highly abrasive
lunar dust and makes it levitate. This effect contributes to the easy spread of the sticky, lung- and gear-damaging lunar dust. The Moon's
axial tilt with respect to the
ecliptic is only 1.5427°, much less than the 23.44° of Earth. This small axial tilt means that the Moon's solar illumination varies much less with
season than Earth's, and it also allows for the existence of some
peaks of eternal light at the
Moon's north pole, at the rim of the crater
Peary. The lunar surface is exposed to temperature differences ranging from to depending on the
solar irradiance. Because of the lack of atmosphere, temperatures of different areas vary particularly upon whether they are in sunlight or shadow, making topographical details play a decisive role on local
surface temperatures. and just close to the winter solstice in the north polar crater
Hermite. This is the coldest temperature in the Solar System ever measured by a spacecraft, colder even than the surface of
Pluto. The regolith of older surfaces is generally thicker than for younger surfaces: it varies in thickness from in the highlands and in the maria. Beneath the finely comminuted regolith layer is the megaregolith, a layer of highly fractured bedrock many kilometers thick. These extreme conditions are considered to make it unlikely for spacecraft to harbor bacterial spores at the Moon for longer than just one lunar orbit.
Surface features rich magma terrane (hatched), with its most prominent part labeled on the near side (left), the
Mare Procellarum KREEP Terrane (PKT).The
South Pole–Aitken Terrane (SPAT) is marked on the far side (right, largest circle).The 24 crater basins with crustal thinning greater than are marked (black circles) across both hemispheres.The rest is the high-thickness
Felspathic Highlands Terrane (FHT; red and white). The
topography of the Moon has been measured with
laser altimetry and
stereo image analysis. Its most extensive
topographic feature is the giant far-side
South Pole–Aitken basin, some in diameter, the largest crater on the Moon and the second-largest confirmed impact
crater in the Solar System. At deep, its floor is the lowest point on the surface of the Moon, reaching at in a crater within
Antoniadi crater. The
highest elevations of the Moon's surface, with the so-called
Selenean summit at , are located directly to the northeast (), Other large impact basins such as
Imbrium,
Serenitatis,
Crisium,
Smythii, and
Orientale possess regionally low elevations and elevated rims. Similar shrinkage features exist on
Mercury. Mare Frigoris, a basin near the north pole long assumed to be geologically dead, has cracked and shifted. Since the Moon does not have tectonic plates, its tectonic activity is slow, and cracks develop as it loses heat. Scientists have confirmed the presence of a cave on the Moon near the
Sea of Tranquility, not far from the 1969
Apollo 11 landing site. The cave, identified as an entry point to a collapsed
lava tube, is roughly 45 meters wide and up to 80 m long. This discovery marks the first confirmed entry point to a lunar cave. The analysis was based on photos taken in 2010 by NASA's
Lunar Reconnaissance Orbiter. The cave's stable temperature of around could provide a hospitable environment for future astronauts, protecting them from extreme temperatures, solar radiation, and micrometeorites. However, challenges include accessibility and risks of avalanches and cave-ins. This discovery offers potential for future lunar bases or emergency shelters.
Volcanic features , the most prominent volcanic features of the Moon, labeled in blue (brown labels are prominent
lunar craters) The main features visible from Earth by the naked eye are dark and relatively featureless lunar plains called
maria (
mare; from Latin meaning 'seas', as they were once believed to be filled with water) which are vast solidified pools of ancient
basaltic lava. Although similar to terrestrial basalts, lunar basalts have more iron and no minerals altered by water. The majority of these lava deposits erupted or flowed into the depressions associated with
impact basins, though the Moon's largest expanse of basalt flooding,
Oceanus Procellarum, does not correspond to an obvious impact basin. Different episodes of lava flow in maria can often be recognized by variations in surface albedo and distinct flow margins. lava flows of
Mare Imbrium forming
wrinkle ridges As the maria formed, cooling and contraction of the basaltic lava created
wrinkle ridges in some areas. These low, sinuous ridges can extend for hundreds of kilometers and often outline buried structures within the mare. Another result of maria formation is the creation of concentric depressions along the edges, known as
arcuate rilles. These features occur as the mare basalts sink inward under their own weight, causing the edges to fracture and separate. In addition to the visible maria, the Moon has mare deposits covered by ejecta from impacts. Called cryptomares, these hidden mares are likely older than the exposed ones. Conversely, mare lava has obscured many impact melt sheets and pools. Impact melts are formed when intense shock pressures from collisions vaporize and melt zones around the impact site. Where still exposed, impact melt can be distinguished from mare lava by its distribution, albedo, and texture.
Sinuous rilles, found in and around maria, are likely extinct
lava channels or collapsed
lava tubes. They typically originate from volcanic
vents, meandering and sometimes branching as they progress. The largest examples, such as
Schroter's Valley and
Rima Hadley, are significantly longer, wider, and deeper than terrestrial lava channels, sometimes featuring bends and sharp turns that again, are uncommon on Earth. features and
lunar lava tube cave
Marius Hills pit as observed under different solar illumination conditions. Mare volcanism has altered impact craters in various ways, including filling them to varying degrees, and raising and fracturing their floors from uplift of mare material beneath their interiors. Examples of such craters include
Taruntius and
Gassendi. Some craters, such as
Hyginus, are of wholly volcanic origin, forming as
calderas or
collapse pits. Such craters are relatively rare and tend to be smaller (typically a few kilometers wide), shallower, and more irregularly shaped than impact craters. They also lack the upturned rims characteristic of impact craters. Several
geologic provinces containing
shield volcanoes and volcanic
domes are found within the near side maria. There are also some regions of
pyroclastic deposits,
scoria cones and
non-basaltic domes made of particularly high viscosity lava. Almost all maria are on the near side of the Moon, and cover 31% of the surface of the near side This is likely due to a
concentration of heat-producing elements under the crust on the near side, which would have caused the underlying mantle to heat up, partially melt, rise to the surface and erupt. Most of the Moon's
mare basalts erupted during the
Imbrian period, 3.3–3.7 billion years ago, though some are as young as 1.2 billion years
Moonquakes and releases of gas indicate continued lunar activity. Evidence has been found for 2–10 million years old basaltic volcanism within the crater Lowell, inside the Orientale basin. Some combination of an initially hotter mantle and local enrichment of heat-producing elements in the mantle could be responsible for prolonged activities on the far side in the Orientale basin. The lighter-colored regions of the Moon are called
terrae, or more commonly
highlands, because they are higher than most maria. They have been radiometrically dated to having formed 4.4 billion years ago and may represent
plagioclase cumulates of the lunar magma ocean. The concentration of maria on the near side likely reflects the substantially thicker crust of the highlands of the Far Side, which may have formed in a slow-velocity impact of a second moon of Earth a few tens of millions of years after the Moon's formation. Alternatively, it may be a consequence of asymmetrical
tidal heating when the Moon was much closer to the Earth.
Impact craters and the two most prominent craters on the near side,
Tycho (left) and
Copernicus (top) visible, featuring long bright impact-streaks. on the
Moon's far side astronaut
Harrison H. Schmitt next to the large Moon boulder nicknamed "
Tracy's Rock" in the
Taurus–Littrow of the
Mare Serenitatis on the near side of the Moon A major geologic process that has affected the Moon's surface is
impact cratering, with craters formed when asteroids and comets collide with the lunar surface. There are estimated to be roughly 300,000 craters wider than on the Moon's near side. Lunar craters exhibit a variety of forms, depending on their size. In order of increasing diameter, the basic types are simple craters with smooth bowl shaped interiors and upturned rims,
complex craters with flat floors, terraced walls and central peaks,
peak ring basins, and
multi-ring basins with two or more concentric rings of peaks. The vast majority of impact craters are circular, but some, like
Cantor and
Janssen, have more polygonal outlines, possibly guided by underlying faults and joints. Others, such as the
Messier pair,
Schiller, and
Daniell, are elongated. Such elongation can result from highly oblique impacts,
binary asteroid impacts, fragmentation of impactors before surface strike, or closely spaced
secondary impacts. The
lunar geologic timescale is based on the most prominent impact events, such as multi-ring formations like
Nectaris,
Imbrium, and
Orientale that are between hundreds and thousands of kilometers in diameter and associated with a broad apron of ejecta deposits that form a regional
stratigraphic horizon. The radiometric ages of impact-melted rocks collected during the
Apollo missions cluster between 3.8 and 4.1 billion years old: this has been used to propose a
Late Heavy Bombardment period of increased impacts. High-resolution images from the Lunar Reconnaissance Orbiter in the 2010s show a contemporary crater-production rate significantly higher than was previously estimated. A secondary cratering process caused by
distal ejecta is thought to churn the top two centimeters of regolith on a timescale of 81,000 years. This rate is 100 times faster than the rate computed from models based solely on direct micrometeorite impacts.
Lunar swirls Lunar swirls are enigmatic features found across the Moon's surface. They are characterized by a high albedo, appear optically immature (i.e. have the optical characteristics of a relatively young
regolith), and often have a sinuous shape. Their shape is often accentuated by low
albedo regions that wind between the bright swirls. They are located in places with enhanced surface
magnetic fields and many are located at the
antipodal point of major impacts. Well known swirls include the
Reiner Gamma feature and
Mare Ingenii. They are hypothesized to be areas that have been partially shielded from the
solar wind, resulting in slower
space weathering.
Presence of water (M3) spectrometer onboard India's
Chandrayaan-1 orbiter Liquid water cannot persist on the lunar surface. When exposed to solar radiation, water quickly decomposes through a process known as
photodissociation and is lost to space. However, since the 1960s, scientists have hypothesized that water ice may be deposited by impacting
comets or possibly produced by the reaction of oxygen-rich lunar rocks, and hydrogen from
solar wind, leaving traces of water which could possibly persist in cold, permanently shadowed craters at either pole on the Moon. Computer simulations suggest that up to of the surface may be in permanent shadow. In 1998, the
neutron spectrometer on the
Lunar Prospector spacecraft showed that high concentrations of hydrogen are present in the first meter of depth in the regolith near the polar regions. In 2009,
LCROSS sent a impactor into a
permanently shadowed polar crater, and detected at least of water in a plume of ejected material. The data revealed the distinct reflective signatures of water-ice, as opposed to dust and other reflective substances. The ice deposits were found on the North and South poles, although it is more abundant in the South, where water is trapped in permanently shadowed craters and crevices, allowing it to persist as ice on the surface since they are shielded from the sun. == Earth–Moon system ==