Planetary science studies observational and theoretical astronomy,
geology (
astrogeology),
atmospheric science, and an emerging subspecialty in
planetary oceans, called
planetary oceanography.
Planetary astronomy This is both an observational and a theoretical science. Observational researchers are predominantly concerned with the study of the small bodies of the Solar System: those that are observed by telescopes, both optical and radio, so that characteristics of these bodies such as shape, spin, surface materials and
weathering are determined, and the history of their formation and evolution can be understood. Theoretical planetary astronomy is concerned with
dynamics: the application of the principles of
celestial mechanics to the Solar System and
extrasolar planetary systems. Observing
exoplanets and determining their physical properties,
exoplanetology, is a major area of research besides Solar System studies. Every planet has its own branch.
Planetary geology In planetary science, the term geology is used in its broadest sense, to mean the study of the surface and interior parts of planets and moons, from their core to their magnetosphere. The best-known research topics of planetary geology deal with the planetary bodies in the near vicinity of the Earth: the
Moon, and the two neighboring planets:
Venus and
Mars. Of these, the Moon was studied first, using methods developed earlier on the Earth. Planetary geology focuses on celestial objects that exhibit a solid surface or have significant solid physical states as part of their structure. Planetary geology applies
geology,
geophysics and
geochemistry to planetary bodies.
Planetary geomorphology Geomorphology studies the features on planetary surfaces and reconstructs the history of their formation, inferring the physical processes that acted on the surface. Planetary geomorphology includes the study of several classes of surface features: • Impact features (
multi-ringed basins, craters) • Volcanic and tectonic features (lava flows, fissures,
rilles) • Glacial features The history of a planetary surface can be deciphered by mapping features from top to bottom according to their
deposition sequence, as first determined on terrestrial
strata by
Nicolas Steno. For example,
stratigraphic mapping prepared the
Apollo astronauts for the field geology they would encounter on their lunar missions. Overlapping sequences were identified on images taken by the
Lunar Orbiter program, and these were used to prepare a lunar
stratigraphic column and
geological map of the Moon.
Cosmochemistry, geochemistry and petrology One of the main problems when generating hypotheses on the formation and evolution of objects in the Solar System is the lack of samples that can be analyzed in the laboratory, where a large suite of tools are available, and the full body of knowledge derived from terrestrial geology can be brought to bear. Direct samples from the Moon,
asteroids and
Mars are present on Earth, removed from their parent bodies, and delivered as
meteorites. Some of these have suffered contamination from the
oxidising effect of Earth's atmosphere and the infiltration of the
biosphere, but those meteorites collected in the last few decades from
Antarctica are almost entirely pristine. The different types of meteorites that originate from the
asteroid belt cover almost all parts of the structure of
differentiated bodies: meteorites even exist that come from the core-mantle boundary (
pallasites). The combination of geochemistry and observational astronomy has also made it possible to trace the
HED meteorites back to a specific asteroid in the main belt,
4 Vesta. The comparatively few known
Martian meteorites have provided insight into the geochemical composition of the Martian crust, although the unavoidable lack of information about their points of origin on the diverse Martian surface has meant that they do not provide more detailed constraints on theories of the evolution of the Martian
lithosphere. As of July 24, 2013, 65 samples of Martian meteorites have been discovered on Earth. Many were found in either Antarctica or the Sahara Desert. During the Apollo era, in the
Apollo program, 384 kilograms of
lunar samples were collected and transported to the Earth, and three Soviet
Luna robots also delivered
regolith samples from the Moon. These samples provide the most comprehensive record of the composition of any Solar System body besides the Earth. The numbers of lunar meteorites are growing quickly in the last few years – as of April 2008 there are 54 meteorites that have been officially classified as lunar. Eleven of these are from the US Antarctic meteorite collection, 6 are from the Japanese Antarctic meteorite collection and the other 37 are from hot desert localities in Africa, Australia, and the Middle East. The total mass of recognized lunar meteorites is close to .
Planetary geophysics and space physics Space probes made it possible to collect data in not only the visible light region but in other areas of the electromagnetic spectrum. The planets can be characterized by their force fields: gravity and their magnetic fields, which are studied through geophysics and space physics. Measuring the changes in acceleration experienced by spacecraft as they orbit has allowed fine details of the
gravity fields of the planets to be mapped. For example, in the 1970s, the gravity field disturbances above
lunar maria were measured through lunar orbiters, which led to the discovery of concentrations of mass,
mascons, beneath the Imbrium, Serenitatis, Crisium, Nectaris and Humorum basins. is deflected by the magnetosphere (not to scale). If a planet's
magnetic field is sufficiently strong, its interaction with the solar wind forms a
magnetosphere around a planet. Early space probes discovered the gross dimensions of the terrestrial magnetic field, which extends about 10 Earth radii towards the Sun. The
solar wind, a stream of charged particles, streams out and around the terrestrial magnetic field, and continues behind the magnetic tail, hundreds of Earth radii downstream. Inside the magnetosphere, there are relatively dense regions of solar wind particles, the
Van Allen radiation belts. Planetary
geophysics includes, but is not limited to,
seismology and
tectonophysics,
geophysical fluid dynamics,
mineral physics,
geodynamics,
mathematical geophysics, and
geophysical surveying.
Planetary geodesy Planetary geodesy (also known as planetary geodetics) deals with the measurement and representation of the planets of the Solar System, their
gravitational fields and geodynamic phenomena (
polar motion in three-dimensional, time-varying space). The science of
geodesy has elements of both astrophysics and planetary sciences. The
shape of the Earth is to a large extent the result of its rotation, which causes its
equatorial bulge, and the competition of geologic processes such as the collision of plates and of
vulcanism, resisted by the
Earth's gravity field. These principles can be applied to the
solid surface of Earth (
orogeny; Few mountains are higher than , few deep sea trenches deeper than that because quite simply, a mountain as tall as, for example, , would develop so much
pressure at its base, due to gravity, that the rock there would become
plastic, and the mountain would slump back to a height of roughly in a geologically insignificant time. Some or all of these geologic principles can be applied to other planets besides Earth. For instance on Mars, whose surface gravity is much less, the largest volcano,
Olympus Mons, is high at its peak, a height that could not be maintained on Earth. The Earth
geoid is essentially the figure of the Earth abstracted from its topographic features. Therefore, the Mars geoid (
areoid) is essentially the figure of Mars abstracted from its topographic features.
Surveying and
mapping are two important fields of application of geodesy.
Planetary atmospheric science An
atmosphere is an important transitional zone between the solid planetary surface and the higher rarefied
ionizing and radiation belts. Not all planets have atmospheres: their existence depends on the mass of the planet, and the planet's distance from the Sun – too distant and frozen atmospheres occur. Besides the four
giant planets, three of the four
terrestrial planets (
Earth,
Venus, and
Mars) have significant atmospheres. Two moons have significant atmospheres:
Saturn's moon
Titan and
Neptune's moon
Triton. A tenuous atmosphere exists around
Mercury. The effects of the
rotation rate of a planet about its axis can be seen in atmospheric streams and currents. Seen from space, these features show as bands and eddies in the cloud system and are particularly visible on Jupiter and Saturn.
Planetary oceanography Exoplanetology Exoplanetology studies
exoplanets, the planets existing outside of the
Solar System. Until recently, the means of studying exoplanets have been extremely limited, but with the current rate of innovation in
research technology, exoplanetology has become a rapidly developing
subfield of astronomy. ==Comparative planetary science==