Planetary geology

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Planetary geology, alternatively known as astrogeology or exogeology, is a planetary science discipline concerned with the geology of celestial bodies such as planets and their moons, asteroids, comets, and meteorites.^[1][2] Although the geo- prefix typically indicates topics of or relating to Earth, planetary geology is named as such for historical and convenience reasons; due to the subject matter, it is closely linked with more traditional Earth-based geology.^[3]

Planetary geology includes such topics as determining the properties and processes of the internal structure of the terrestrial planets, surface processes such as volcanism, impact craters, even fluvial and aeolian action where applicable. Despite their outermost layers being dominated by gases, the giant planets are also included in the field of planetary geology, especially when it comes to their interiors. Fields within Planetary geology are largely derived from fields in the traditional geological sciences, such as geophysics, geomorphology, and geochemistry.

The examples and perspective in this section deal primarily with the United States and do not represent a worldwide view of the subject. You may improve this section , discuss the issue on the talk page, or create a new section, as appropriate. (January 2014) (Learn how and when to remove this message)

Eugene Merle Shoemaker is credited with bringing geologic principles to planetary mapping and creating the branch of planetary science in the early 1960s, the Astrogeology Research Program, within the United States Geological Survey. He made important contributions to the field and the study of impact craters, selenography (study of the Moon), asteroids, and comets.^[4]

Major centers for planetary science research include the Lunar and Planetary Institute, Applied Physics Laboratory, Planetary Science Institute, Jet Propulsion Laboratory, Southwest Research Institute, and Johnson Space Center. Additionally, several universities conduct extensive planetary science research, including Montana State University, Brown University, the University of Arizona, California Institute of Technology, University of Colorado, Western Michigan University, Massachusetts Institute of Technology, and Washington University in St. Louis. Planetary geologists usually study either geology, astronomy, planetary science, geophysics, or one of the earth sciences at the graduate level.^{[citation needed]}

Simulated interplanetary missions performed on Earth have studied procedures and tools for planetary geology. Various tools, including common archaeological tools such as hammers, shovels, brushes, were evaluated for use by planetary geologists.^[5] Along with these common tools, new advanced technologies have become available. These include spectroscopic databases, and data (such as mission logs, images and mapping) from previous unmanned interplanetary missions.^[6] Scientists use maps, images, telescopes on Earth, and orbiting telescopes (such as the Hubble Space Telescope).^[7] The maps and images are stored in the NASA Planetary Data System where tools such as the Planetary Image Atlas help to search for certain items such as geological features including mountains, ravines, and craters.^[8]

Planetary geology uses a wide variety of standardized terms for features.^[9] All planetary feature names recognized by the International Astronomical Union (IAU) combine one of these terms with a possibly unique identifying name. The conventions which decide the more precise name are dependent on which planetary body the feature is on, but there are standard descriptors common to all astronomical planetary bodies. New terms must be recognized by the IAU Working Group for Planetary System Nomenclature, and are commonly added as features are mapped and described by new planetary missions.^[10] This means that in some cases, names may change as improved imagery becomes available,^[10] or in other cases widely adopted informal names are changed to be in line with the rules.^[11] The standard names are chosen to consciously avoid interpreting the underlying cause of the feature, but rather to describe only its appearance.^[9]

• Astrobiology – Science concerned with life in the universe
• Exoplanet – Planet outside the Solar System
• Exoplanetology
• Planetary habitability – Known extent to which a planet is suitable for life

• J. F. Bell III; B. A. Campbell; M. S. Robinson (2004). Remote Sensing for the Earth Sciences: Manual of Remote Sensing (3rd ed.). John Wiley & Sons. Archived from the original on Sep 16, 2016. Retrieved 2006-08-23.
• Roberge, Aki (1998-04-21). "The Planets After Formation". Department of Terrestrial Magnetism. Archived from the original on 2006-08-13. Retrieved 2006-08-23.
• Hauber E et al. (2019) Planetary geologic mapping. In: Hargitai H (ed ) Planetary Cartography and GIS. Springer.
• Hargitai H et al. (2015) Classification and Characterization of Planetary Landforms. In: Hargitai H, Kerszturi Á (eds) Encyclopedia of Planetary Landforms. Springer.
• Rossi, Angelo Pio; Gasselt, Stephan van, eds. (2018). Planetary Geology. Astronomy and Planetary Sciences. Springer International Publishing. ISBN 978-3-319-65177-4.