In
differentiated bodies, the surface is where the crust meets the
planetary boundary layer. Anything below this is regarded as being sub-surface or sub-marine. Most bodies more massive than
super-Earths, including
stars and
gas giants, as well as smaller
gas dwarfs, transition contiguously between phases, including gas, liquid, and solid. As such, they are generally regarded as lacking surfaces.
Planetary surfaces and surface life are of particular interest to
humans as it is the primary
habitat of the species, which has
evolvedto move over land and
breatheair. Human
space exploration and
space colonization therefore focuses heavily on them. Humans have only directly explored the surface of Earth and the Moon. The vast distances and complexities of space makes direct exploration of even
near-Earth objects dangerous and expensive. As such, all other exploration has been indirect via
space probes.
Indirect observations by flyby or orbit currently provide insufficient information to confirm the composition and properties of planetary surfaces. Much of what is known is from the use of techniques such as
astronomical spectroscopy and
sample return.
Lander spacecraft have explored the surfaces of planets
Mars and
Venus. Mars is the only other planet to have had its surface explored by a mobile surface probe (rover).
Titan is the only non-planetary object of
planetary mass to have been explored by lander. Landers have explored several smaller bodies including
433 Eros (2001),
25143 Itokawa (2005),
Tempel 1 (2005),
67P/Churyumov–Gerasimenko (2014),
162173 Ryugu (2018) and
101955 Bennu (2020). Surface samples have been collected from the Moon (returned 1969), 25143 Itokawa (returned 2010), 162173 Ryugu and 101955 Bennu.
Distance, gravity, atmospheric conditions (extremely low or extremely high
atmospheric pressure) and unknown factors make exploration both costly and risky. This necessitates the space probes for early exploration of planetary surfaces. Many probes are stationary have a limited study range and generally survive on extraterrestrial surfaces for a short period, however mobile probes (rovers) have surveyed larger surface areas.
Sample return missions allow scientist to study extraterrestrial surface materials on Earth without having to send a crewed mission, however is generally only feasible for objects with low gravity and atmosphere.
The first extraterrestrial planetary surface to be explored was the
lunar surface by
Luna 2 in 1959. The first and only human exploration of an extraterrestrial surface was the Moon, the
Apollo program included the first moonwalk on July 20, 1969, and successful return of extraterrestrial surface samples to Earth.
Venera 7 was the first landing of a probe on another planet on December 15, 1970.
Mars 3 "soft landed" and returned data from Mars on August 22, 1972, the first rover on Mars was
Mars Pathfinder in 1997, the
Mars Exploration Rover has been studying the surface of the red planet since 2004.
NEAR Shoemaker was the first to soft land on an asteroid –
433 Eros in February 2001 while
Hayabusa was the first to return samples from
25143 Itokawa on 13 June 2010. Huygens soft landed and returned data from
Titan on January 14, 2005.
There have been many failed attempts, more recently
Fobos-Grunt, a sample return mission aimed at exploring the surface of
Phobos.
Venera 9 returned the first view and this first clear image from the surface of another planet in 1975 (
Venus).[4]
Forms
The surfaces of Solar System objects, other than the four
Outer Solar Systemgas planets, are mostly solid, with few having liquid surfaces.
The only Solar System object having a mostly liquid surface is Earth, with its global
ocean surface comprising 70.8 % of
Earth's surface, filling its
oceanic basins and covering Earth's
oceanic crust, making Earth an
ocean world. The remaining part of its surface consists of rocky or organic carbon and silicon rich
compounds.
Volcanism can cause flows such as
lava on the surface of geologically active bodies (the largest being the
Amirani (volcano) flow on Io). Many of Earth's
Igneous rocks are formed through processes rare elsewhere, such as the presence of volcanic magma and water. Surface mineral deposits such as
olivine and
hematite discovered on Mars by lunar rovers provide direct evidence of past stable
water on the surface of Mars.
Increasingly organic compounds are being found on objects throughout the Solar System. While unlikely to indicate the presence of extraterrestrial life, all known life is based on these compounds. Complex carbon molecules may form through various complex chemical interactions or delivered through impacts with small solar system objects and can combine to form the "building blocks" of
Carbon-based life. As organic compounds are often
volatile, their persistence as a solid or liquid on a planetary surface is of scientific interest as it would indicate an intrinsic source (such as from the object's interior) or residue from larger quantities of organic material preserved through special circumstances over geological timescales, or an extrinsic source (such as from past or recent collision with other objects).[6] Radiation makes the detection of organic matter difficult, making its detection on atmosphereless objects closer to the Sun extremely difficult.[7]
Martian exploration including samples taken by on the ground rovers and spectroscopy from orbiting satellites have revealed the presence of a number of complex organic molecules, some of which could be biosignatures in the search for life.
The following is a non-exhaustive list of surface materials that occur on more than one planetary surface along with their locations in order of distance from the Sun. Some have been detected by spectroscopy or direct imaging from orbit or flyby.
Lava tubes, found on Venus, Earth, The Moon and Mars
Surface of gas giants
Normally,
gas giants are considered to not have a surface, although they might have a solid core of rock or various types of ice, or a liquid core of
metallic hydrogen. However, the core, if it exists, does not include enough of the planet's mass to be actually considered a surface. Some scientists consider the point at which the atmospheric pressure is equal to 1
bar, equivalent to the atmospheric pressure at Earth's surface, to be the surface of the planet,
[1] if the planet has no clear rigid terrain. Therefore the location of the surface of terrestrial planets do not depend on an atmospheric pressure of 1 Bar, even if for example
Venus has a thick atmosphere with pressures at Venus's surface increasing well above Earth's atmospheric pressure.
Planetary surfaces are investigated for the presence of past or present
extraterrestrial life.
Thomas Gold expanded the field by advancing the possibility of life and a so-called
deep biosphere below the surface of a celestial body, and not only on the surface.[53]
Some planetary surfaces of the Solar System and their compositions
The dry, rocky and icy surface of planet Mars (photographed by
Viking Lander 2, May 1979) is composed of iron-oxide rich regolith
Pebbled plains of Saturn's moon
Titan (photographed by
Huygens probe, January 14, 2005) composed of heavily compressed states of water ice. This is the only ground-based photograph of an outer Solar System planetary surface
Surface of comet
Tempel 1 (photographed by the
Deep Impact probe), consists of a fine powder of contains water and carbon dioxide rich clays, carbonates, sodium, and crystalline silicates.
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