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[[File:Fomalhaut Dusty Debris Disk (MIRI Compass Image).png|thumb|right|275px|<div align="center">Exoasteroid belts around star [[Fomalhaut]]<br />([[James Webb Space Telescope]]; 8 May 2023)</div>]] |
[[File:Fomalhaut Dusty Debris Disk (MIRI Compass Image).png|thumb|right|275px|<div align="center">Exoasteroid belts around star [[Fomalhaut]]<br />([[James Webb Space Telescope]]; 8 May 2023)</div>]] |
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An '''exoasteroid''', '''exo-asteroid''' or '''extrasolar asteroid''' |
An '''exoasteroid''', '''exo-asteroid''' or '''extrasolar asteroid''' is an [[asteroid]] located outside the [[Solar System]]. While exoasteroids and exoasteroid belts were once considered hypothetical, recent scientific studies and thorough analyses have provided evidence for their existence.<ref name="SM-20230511">{{cite news |last=Enking |first=Molly |title=James Webb Telescope Reveals Asteroid Belts Around Nearby Young Star - The findings suggest the star Fomalhaut may have orbiting planets hidden among its rings of debris |url=https://www.smithsonianmag.com/smart-news/james-webb-telescope-reveals-asteroid-belts-around-nearby-young-star-180982148 |date=11 May 2023 |work=[[Smithsonian (magazine)|Smitjhsonian]] |url-status=live |archiveurl=https://archive.today/20231231121148/https://www.smithsonianmag.com/smart-news/james-webb-telescope-reveals-asteroid-belts-around-nearby-young-star-180982148/ |archivedate=31 December 2023 |accessdate=31 December 2023 }}</ref> |
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==Evidence== |
==Evidence== |
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Scientists propose that the formation of exoasteroids often results from the fragmentation of |
Scientists propose that the formation of exoasteroids often results from the fragmentation of [[exoplanet]]s by [[gas giant]]s. These exoasteroids are presumed to be the remnants of smaller celestial bodies that endured the demise of their parent exoplanet. Analogous processes are hypothesized to have occurred during the [[Formation and evolution of the Solar System|formation of our Solar System]].<ref>{{cite web |title=Asteroids: Facts |url=https://science.nasa.gov/solar-system/asteroids/facts/ |website=nasa.gov |access-date=31 December 2023}}</ref><ref name="NASA-20230126">{{cite news |last=Gronstal |first=Aaron |title=Exo-Asteroids and Habitability around M-Dwarfs |url=https://astrobiology.nasa.gov/news/exo-asteroids-and-habitability-around-m-dwarfs/ |date=26 January 2023 |work=[[NASA]] |url-status=live |archiveurl=https://archive.today/20231231122011/https://astrobiology.nasa.gov/news/exo-asteroids-and-habitability-around-m-dwarfs/ |archivedate=31 December 2023 |accessdate=31 December 2023 }}</ref> |
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[[NASA]] has conducted studies affirming that the presence of [[ |
[[NASA]] has conducted studies affirming that the presence of [[asteroid belt|asteroid belts]] around stars is a common phenomenon in nearly any solar system hosting planets comparable in size to the [[outer planet|outer]] and [[inner planet]]s of our [[Solar System]].<ref name="NASA-20230126" /> |
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=== History === |
=== History === |
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In December 1988, |
In December 1988, American [[astrophysicist]]s [[Benjamin Zuckerman]] and [[Eric Becklin]] detected a substantial [[circumstellar disc]] encircling the [[white dwarf]] star [[G 29-38]], stemming from a near-infrared survey of 200 white dwarfs.<ref name="BZ1">[http://adsabs.harvard.edu/abs/1988Natur.336..656B A low-temperature companion to a white dwarf star], E. E. Becklin & B. Zuckerman, ''Nature'' '''336''' (Dec. 15, 1988), pp. 656-658</ref> Zuckerman and Becklin conducted further investigations on the white dwarf star, uncovering that the circumstellar disc emits notable radiation within the 2 to 5 [[Micrometre|micrometer]] range. This discovery suggests potential interactions between exoasteroids and [[Radiation|radiant matter]], possibly leading to their ejection into space.<ref>[http://adsabs.harvard.edu/abs/1987Natur.330..138Z Excess infrared radiation from a white dwarf - an orbiting brown dwarf?] B. Zuckerman & E. E. Becklin, ''Nature'' '''330''', (Nov. 12, 1987), pp. 138-140</ref> Subsequent observations in 2004 by the [[Spitzer Space Telescope]] revealed the presence of a dust cloud surrounding G 29-38. This phenomenon is believed to have originated from the disintegration of an [[exocomet]] or exoasteroid as it interacted with the white dwarf over time.<ref>[http://adsabs.harvard.edu/abs/2005ApJ...635L.161R The Dust Cloud around the White Dwarf G29-38], William T. Reach, Marc J. Kuchner, Ted von Hippel, Adam Burrows, Fergal Mullally, Mukremin Kilic, and D. E. Winget, ''Astrophysical Journal'' '''635''', #2 (December 2005), pp. L161–L164.</ref> Spitzers observations further proved that exoasteroids could exist. |
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In May 2023, the [[James Webb Space Telescope]] |
In May 2023, the [[James Webb Space Telescope]] provided images of [[Fomalhaut]],<ref name=":0">{{cite web |date=8 May 2023 |title=Webb Looks for Fomalhaut's Asteroid Belt and Finds Much More |url=https://www.nasa.gov/missions/webb/webb-looks-for-fomalhauts-asteroid-belt-and-finds-much-more/ |access-date=30 December 2023 |website=nasa.gov}}</ref> a young star positioned 25 [[light-year]]s (ly) away from Earth. Scientists analyzed these images and conducted simulations and tests on Fomalhaut's asteroid belt, proposing that it likely formed due to collisions involving larger celestial bodies.<ref name=":0" />{{clarify|date=December 2023}} |
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Another notable star hosting an asteroid belt is the white dwarf star [[WD 0145+234]]. It is hypothesized that WD 0145+234 once hosted an exoasteroid or exoplanet in orbit around it, which was subsequently |
Another notable star hosting an asteroid belt is the white dwarf star [[WD 0145+234]]. It is hypothesized that WD 0145+234 once hosted an exoasteroid or exoplanet in orbit around it, which was subsequently disrupted, leading to the formation of a substantial exoasteroid belt. Due to the star's dimensions, scientists infer that the [[accretion disk]] surrounding WD 0145+234 is highly active, resulting in the regular disruption of exoasteroids by the star's gravitational pull. In 2018, astronomers observed a 10% increase in the star's [[mid-infrared]] light, indicative of the recent destruction of an exoasteroid, which led to the formation of a cloud of metallic dust partially obscuring WD 0145+234 from Earth's view.<ref>{{cite web |last1=Letzter |first1=Rafi |date=17 October 2019 |title=An Asteroid-Smashing Star Ground a Giant Rock to Bits and Covered Itself in the Remains |url=https://www.livescience.com/white-dwarf-asteroid-smasher.html |access-date=31 December 2023 |website=livescience.com}}</ref> |
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==Detection== |
==Detection== |
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[[File:JPL-AsteroidDisruptedByStar-ArtistConcept.jpg|thumb| |
[[File:JPL-AsteroidDisruptedByStar-ArtistConcept.jpg|thumb|left|Artist's concept of an exoasteroid being ripped apart by its star]] |
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In 2013, astronomers |
In 2013, astronomers discovered fragmented remnants of an exoasteroid orbiting the star [[GD 61]]. Upon detailed examination, scientists determined that the asteroid possessed a [[surface water|surface rich in water]], comprising approximately 26% water by mass, a composition akin to the surface water, primarily in the form of [[ice]], found on the [[dwarf planet]] [[Ceres (dwarf planet)|Ceres]]. It suggests the potential existence of an exoplanet with [[liquid water]] around the star at some point in its history. It is postulated that the asteroid met its demise due to interactions with its star, leading to its fragmentation and subsequent formation of an asteroid belt around the star. |
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Following this discovery, scientists |
Following this discovery, scientists used the [[Cosmic Origins Spectrograph]] aboard the [[Hubble Space Telescope]] to analyze the chemical composition of the asteroid; it showed the presence of [[magnesium]], [[silicon]], [[iron]], and [[oxygen]] within the asteroid's water.<ref>{{cite web |date=10 October 2013 |title=Watery asteroid discovered in dying star points to habitable exoplanets |url=https://phys.org/news/2013-10-watery-asteroid-dying-star-habitable.html |access-date=31 December 2023 |website=phys.org}}</ref> |
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===Proposed observational methods=== |
===Proposed observational methods=== |
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Exoasteroids can be detected through various methodical processes. The [[transit method]] is a common technique used |
Exoasteroids can be detected through various methodical processes. The [[transit method]] is a common technique used to discover extrasolar objects as they pass in front of their host star, providing scientists with the opportunity to observe their shape. [[Spectroscopy]] can be used to identify distinctive characteristics of exoasteroids, and allows to detect surface features. Other techniques include [[remote sensing]] and [[List of missions to minor planets|data from past missions to minor planets]]. |
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== See also == |
== See also == |
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Latest revision as of 18:50, 12 September 2024
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An exoasteroid, exo-asteroid or extrasolar asteroid is an asteroid located outside the Solar System. While exoasteroids and exoasteroid belts were once considered hypothetical, recent scientific studies and thorough analyses have provided evidence for their existence.[1]
Evidence
[edit]Scientists propose that the formation of exoasteroids often results from the fragmentation of exoplanets by gas giants. These exoasteroids are presumed to be the remnants of smaller celestial bodies that endured the demise of their parent exoplanet. Analogous processes are hypothesized to have occurred during the formation of our Solar System.[2][3]
NASA has conducted studies affirming that the presence of asteroid belts around stars is a common phenomenon in nearly any solar system hosting planets comparable in size to the outer and inner planets of our Solar System.[3]
History
[edit]In December 1988, American astrophysicists Benjamin Zuckerman and Eric Becklin detected a substantial circumstellar disc encircling the white dwarf star G 29-38, stemming from a near-infrared survey of 200 white dwarfs.[4] Zuckerman and Becklin conducted further investigations on the white dwarf star, uncovering that the circumstellar disc emits notable radiation within the 2 to 5 micrometer range. This discovery suggests potential interactions between exoasteroids and radiant matter, possibly leading to their ejection into space.[5] Subsequent observations in 2004 by the Spitzer Space Telescope revealed the presence of a dust cloud surrounding G 29-38. This phenomenon is believed to have originated from the disintegration of an exocomet or exoasteroid as it interacted with the white dwarf over time.[6] Spitzers observations further proved that exoasteroids could exist.
In May 2023, the James Webb Space Telescope provided images of Fomalhaut,[7] a young star positioned 25 light-years (ly) away from Earth. Scientists analyzed these images and conducted simulations and tests on Fomalhaut's asteroid belt, proposing that it likely formed due to collisions involving larger celestial bodies.[7][clarification needed]
Another notable star hosting an asteroid belt is the white dwarf star WD 0145+234. It is hypothesized that WD 0145+234 once hosted an exoasteroid or exoplanet in orbit around it, which was subsequently disrupted, leading to the formation of a substantial exoasteroid belt. Due to the star's dimensions, scientists infer that the accretion disk surrounding WD 0145+234 is highly active, resulting in the regular disruption of exoasteroids by the star's gravitational pull. In 2018, astronomers observed a 10% increase in the star's mid-infrared light, indicative of the recent destruction of an exoasteroid, which led to the formation of a cloud of metallic dust partially obscuring WD 0145+234 from Earth's view.[8]
Detection
[edit]
In 2013, astronomers discovered fragmented remnants of an exoasteroid orbiting the star GD 61. Upon detailed examination, scientists determined that the asteroid possessed a surface rich in water, comprising approximately 26% water by mass, a composition akin to the surface water, primarily in the form of ice, found on the dwarf planet Ceres. It suggests the potential existence of an exoplanet with liquid water around the star at some point in its history. It is postulated that the asteroid met its demise due to interactions with its star, leading to its fragmentation and subsequent formation of an asteroid belt around the star.
Following this discovery, scientists used the Cosmic Origins Spectrograph aboard the Hubble Space Telescope to analyze the chemical composition of the asteroid; it showed the presence of magnesium, silicon, iron, and oxygen within the asteroid's water.[9]
Proposed observational methods
[edit]Exoasteroids can be detected through various methodical processes. The transit method is a common technique used to discover extrasolar objects as they pass in front of their host star, providing scientists with the opportunity to observe their shape. Spectroscopy can be used to identify distinctive characteristics of exoasteroids, and allows to detect surface features. Other techniques include remote sensing and data from past missions to minor planets.
See also
[edit]References
[edit]- ^ Enking, Molly (11 May 2023). "James Webb Telescope Reveals Asteroid Belts Around Nearby Young Star - The findings suggest the star Fomalhaut may have orbiting planets hidden among its rings of debris". Smitjhsonian. Archived from the original on 31 December 2023. Retrieved 31 December 2023.
- ^ "Asteroids: Facts". nasa.gov. Retrieved 31 December 2023.
- ^ a b Gronstal, Aaron (26 January 2023). "Exo-Asteroids and Habitability around M-Dwarfs". NASA. Archived from the original on 31 December 2023. Retrieved 31 December 2023.
- ^ A low-temperature companion to a white dwarf star, E. E. Becklin & B. Zuckerman, Nature 336 (Dec. 15, 1988), pp. 656-658
- ^ Excess infrared radiation from a white dwarf - an orbiting brown dwarf? B. Zuckerman & E. E. Becklin, Nature 330, (Nov. 12, 1987), pp. 138-140
- ^ The Dust Cloud around the White Dwarf G29-38, William T. Reach, Marc J. Kuchner, Ted von Hippel, Adam Burrows, Fergal Mullally, Mukremin Kilic, and D. E. Winget, Astrophysical Journal 635, #2 (December 2005), pp. L161–L164.
- ^ a b "Webb Looks for Fomalhaut's Asteroid Belt and Finds Much More". nasa.gov. 8 May 2023. Retrieved 30 December 2023.
- ^ Letzter, Rafi (17 October 2019). "An Asteroid-Smashing Star Ground a Giant Rock to Bits and Covered Itself in the Remains". livescience.com. Retrieved 31 December 2023.
- ^ "Watery asteroid discovered in dying star points to habitable exoplanets". phys.org. 10 October 2013. Retrieved 31 December 2023.
External links
[edit]
Look up exoasteroid in Wiktionary, the free dictionary.
- "Alphabetical list of minor planet names". Minor Planet Center. International Astronomical Union.
- "Asteroid articles in Planetary Science Research Discoveries". Planetary Science. University of Hawaii.
- "JPL Asteroid Watch site". Jet Propulsion Laboratory.
- NASA Asteroid and Comet Watch site
- Asteroid size comparisons (video; 2:40) on YouTube
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