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			{{Short description\|Geologic eon, 4567–4031 million years ago}}
	{{Hadean Infobox}}
			{{for\|the Romanian chef\|Adrian Hădean}}
	The '''Hadean''' (]: {{IPA\|/ˈheɪdiən/}}) is the ] before the ]. It extends back to the Earth's formation, and ended roughly 3.8 billion years ago (3800 ]), though the date varies according to different sources. The name "Hadean" derives from ], Greek for "unseen" or "]" and suggesting the ] or referring to the conditions on Earth at the time. The ] ] coined the term in ], originally to label the period before the earliest-known ]s. W. B. Harland later coined an almost synonymous term: the "'''Priscoan period'''". Other older texts simply refer to the eon as the '''Pre-Archaean''', while during much of the 19th and 20th centuries, the term "]" (meaning without or before life) was commonly used.
			{{Infobox geologic timespan
			\| name = {{Color\|White\|Hadean}}
			\| color = Hadean
			\| top_bar = all time
			\| time_start = {{Period start\|hadean}}
			\| time_start_uncertainty = 0.16
			\| time_end = 4031
			\| time_end_uncertainty = 3
			\| image_outcrop =
			\| caption_outcrop =
			\| timeline = Eons
			\| former_subdivisions =
			\| formerly_part_of =
			\| partially_contained_in =
			\| partially_contains =
			<!--Etymology-->
			\| chrono_name =
			\| strat_name =
			\| name_formality =
			\| name_accept_date =
			\| alternate_spellings =
			\| synonym1 = Priscoan Period
			\| synonym1_coined = ] ''et al.'', 1989
			\| synonym2 =
			\| synonym2_coined =
			\| synonym3 =
			\| synonym3_coined =
			\| former_names =
			\| proposed_names =
			<!--Usage Information-->
			\| celestial_body = earth
			\| usage = Global (])
			<!--Definition-->
			\| chrono_unit = Eon
			\| strat_unit = Eonothem
			\| proposed_by = ], 1972
			\| timespan_formality = Formal
			\| lower_boundary_def = Age of the oldest solid material in the ]'s ] (4567.30 ± 0.16) ]<ref name="Episodes2024">{{cite journal \| title=Ratification of the base of the ICS Geological Time Scale: the Global Standard Stratigraphic Age (GSSA) for the Hadean lower boundary \| last1=Halla \| first1=J. \| display-authors=etal \| journal=] \| year=2024 \| volume=47 \| issue=2 \| pages=381–389 \| doi=10.18814/epiiugs/2024/024002\| doi-access=free \| hdl=2164/23819 \| hdl-access=free }}</ref>
			\| lower_gssa_accept_date = October 5th, 2022<ref name=Cohen2022>{{cite web \|last=Cohen \|first=Kim \|date=October 2022 \|title=New edition of the Chart - 2022-10 \|website=International Commission on Stratigraphy \|url=https://stratigraphy.org/news/143 \|access-date=16 January 2023 \|quote=2022/10 - Hadean: GSSA instated as ratified by IUGS (5-10-2022). The GSSA is 4,567.30 ± 0.16 Ma.}}</ref>
			\| upper_boundary_def = Ten oldest U-Pb zircon ages
			\| upper_gssa_location = Along the Acasta River, ], ]
			\| upper_gssa_coords = {{Coord\|65.1738\|N\|115.5538\|W\|display=inline}}
			\| upper_gssa_accept_date = 2023<ref name="GSSP Web">{{cite web \|title=Global Boundary Stratotype Section and Point \|url=https://stratigraphy.org/gssps/ \|publisher=International Commission of Stratigraphy \|access-date=29 October 2023}}</ref>
			}}

			The '''Hadean''' ({{IPAc-en\|h\|eɪ\|ˈ\|d\|iː\|ə\|n\|,_\|ˈ\|h\|eɪ\|d\|i\|ə\|n}} {{respell\|hay\|DEE\|ən\|,_\|HAY\|dee\|ən}}) is the first and oldest of the four known ]s of ]'s ], starting with ] about 4.6 ]<ref>{{cite journal \|last=Dalrymple \|first=G. Brent \|year=2001 \|title=The age of the Earth in the twentieth century: a problem (mostly) solved \|journal=Geological Society, London, Special Publications \|bibcode=2001GSLSP.190..205D \|s2cid=130092094 \|doi=10.1144/gsl.sp.2001.190.01.14 \|volume=190 \|issue=1 \|pages=205–221 \|url=https://www.lyellcollection.org/doi/10.1144/GSL.SP.2001.190.01.14 \|access-date=2022-10-02}}</ref><ref>{{cite web \|date=1997 \|title=Age of the Earth \|publisher=U.S. Geological Survey \|url=http://pubs.usgs.gov/gip/geotime/age.html \|access-date=2022-10-03 \|url-status=live \|archive-url=https://web.archive.org/web/20051223072700/http://pubs.usgs.gov/gip/geotime/age.html \|archive-date= 23 December 2005}}</ref> (estimated 4567.30 ± 0.16 ]<ref name=Cohen2022/> set by the age of the oldest solid material in the ] — ] dust particles — found as ]s and ]s in some ]s about 4.567 billion years old),<ref name=GeolTimeScale2020>{{cite book \|last1=Strachan \|first1=R. \|last2=Murphy \|first2=J.B. \|last3=Darling \|first3=J. \|last4=Storey \|first4=C. \|last5=Shields \|first5=G. \|chapter=Precambrian (4.56–1 Ga) \|editor1-last=Gradstein \|editor1-first=F.M. \|editor2-last=Ogg \|editor2-first=J.G. \|editor3-last=Schmitz \|editor3-first=M.D. \|editor4-last=Ogg \|editor4-first=G.M. \|date=2020 \|title=Geologic Time Scale 2020 \|publisher=Elsevier \|location=Amsterdam \|isbn=978-0-12-824360-2 \|doi=10.1016/B978-0-12-824360-2.00016-4 \|s2cid=229513433 \|pages=482–483}}</ref><ref name="Episodes2024" /> and ended 4.031 billion years ago. The ] that created the ] occurred early in this eon. The Hadean eon was succeeded by the ] eon, with the ] hypothesized to have occurred at the Hadean-Archean boundary.
	==Hadean rocks==
	In the last decades of the ] geologists identified a few Hadean rocks from Western ], Northwestern ] and ]. The oldest known rock formations (the ]) comprise somewhat altered sediments from Greenland dated around 3.8 billion years ago by a ] ] that penetrated the rocks after they were deposited. Individual ] ]s redeposited in ]s in ] and the ] region of ] are much older. The oldest dated zircons date from about 4400 Ma - very close to the hypothesized time of the ].

			Hadean rocks are very rare, largely consisting of ]s from one locality (]) in ].<ref name=Korenaga2021>{{cite journal \|last=Korenaga \|first=J \|year=2021 \|title=Was There Land on the Early Earth? \|journal=Life \|doi=10.3390/life11111142 \|doi-access=free \|pmid=34833018 \|pmc=8623345 \|volume=11 \|issue=11 \|page=1142\|bibcode=2021Life...11.1142K }}</ref> Hadean ] models remain controversial among ]s: ] and the growth of ]s into ]s may have started in the Hadean, but there is still uncertainty.<ref name=Dhuime2012/><ref name=Harrison2009/><ref name=Windley2021/>
	The Greenland sediments include ] beds. They contain possibly ] ] and quite possibly indicate that ] ] had already emerged at that time. The oldest known ]s (from Australia) date from a few hundred million years later.

			Earth in the early Hadean had a very thick ]-rich ] whose ] likely resembled the ] and the ]s, with mostly ], ] and ]. As the Earth's surface cooled, vaporized atmospheric water ]d into ] and eventually a ] covering nearly all of the planet was formed, turning Earth into an ]. ] ] and ] ]s further altered the Hadean atmosphere eventually into the ]- and ]-rich, ] ].
	The ] happened during Hadean times and affected the Earth and the Moon.

			==Etymology==
	==Atmosphere and oceans==
			The eon's name "Hadean" comes from ], the ] of the ] (whose name is also used to describe the underworld itself), referring to the ]ish conditions then prevailing on ]: the planet had just been formed from recent ], and its surface was still molten with superheated ] due to that, the abundance of short-lived radioactive elements, and frequent ]s with other Solar System bodies.

			The term was coined by American geologist ], originally to label the period before the earliest known ]s on Earth.<ref>{{cite journal \|last=Cloud \|first=Preston \|year=1972 \|title=A working model of the primitive Earth \|journal=American Journal of Science \|volume=272 \|issue=6 \|pages=537–548 \|bibcode=1972AmJS..272..537C \|doi=10.2475/ajs.272.6.537}}</ref><ref>{{cite book \|last=Bleeker \|first=W. \|year=2004 \|chapter=Chapter 10. Toward a 'natural' Precambrian time scale \|editor1-last=Gradstein \|editor1-first=Felix M. \|editor2-last=Ogg \|editor2-first=James G. \|editor3-last=Smith \|editor3-first=Alan G. \|title=A Geologic Time Scale \|publisher=Cambridge University Press \|location=Cambridge, UK \|isbn=9780521786737 \|page=145 \|chapter-url=https://books.google.com/books?id=rse4v1P-f9kC&pg=PA145}}</ref> ] later coined an almost synonymous term, the '''Priscoan period''', from ''priscus'', a Latin word for 'ancient'.<ref>{{cite encyclopedia \|title=Priscoan \|dictionary=Oxford Living dictionaries \|url=https://en.oxforddictionaries.com/definition/priscoan \|url-status=dead \|archive-url=https://web.archive.org/web/20181129225130/https://en.oxforddictionaries.com/definition/priscoan \|archive-date=2018-11-29}}</ref> Other, older texts refer to the eon as the '''Pre-Archean'''.<ref>{{cite conference \|last=Shaw \|first=D.M. \|year=1975 \|title=Early history of the Earth \|conference=Proceedings of the NATO Advanced Study Institute \|publisher=John Wiley \|location=Leicester \|isbn=0-471-01488-5 \|pages=33–53}}</ref><ref>{{cite journal \|last1=Jarvis \|first1=Gary T. \|last2=Campbell \|first2=Ian H. \|date=December 1983 \|title=Archean komatiites and geotherms: Solution to an apparent contradiction \|journal=Geophysical Research Letters \|doi=10.1029/GL010i012p01133 \|bibcode=1983GeoRL..10.1133J \|volume=10 \|issue=12 \|pages=1133–1136}}</ref>
	A sizeable quantity of water would have been in the material which formed the Earth.<ref>http://www.ingentaconnect.com/content/arizona/maps/2005/00000040/00000004/art00003;jsessionid=7ibpocfkopqql.alice</ref> Water molecules would have escaped Earth's gravity until a radius of about 40% of the current size, and water (and other volatile elements) would have been retained after that point.<ref>http://history.nasa.gov/SP-345/ch26.htm</ref> Hydrogen and helium are expected to continually leak from the atmosphere, but the lack of denser ]es in the modern atmosphere suggests that something disastrous happened to the early atmosphere.

			==Rock dating==
	Part of the young planet is theorized to have been disrupted by the ], which should have caused melting of one or two large areas. Present composition does not match complete melting and it is hard to completely melt and mix huge rock masses.<ref>http://solarsystem.nasa.gov/scitech/display.cfm?ST_ID=446</ref> However, a fair fraction of material should have been vaporized by this impact, creating a rock vapor atmosphere around the young planet. The rock vapor would have condensed within two thousand years, leaving behind hot volatiles which probably resulted in a heavy carbon dioxide atmosphere with hydrogen and water vapor. Liquid water oceans existed despite the surface temperature of 230°C because of the atmospheric pressure of the heavy CO<sub>2</sub> atmosphere. As cooling continued, subduction and dissolving in ocean water removed most CO<sub>2</sub> from the atmosphere but levels oscillated wildly as new surface and mantle cycles appeared.<ref>http://www.pnas.org/cgi/content/full/98/7/3666</ref>
			{{further\|Oldest dated rocks}}

			Prior to the 1980s and the discovery of ], scientific narratives of the early Earth explanations were almost entirely in the hands of ] modelers.<ref>{{cite book \|last1=Harrison \|first1=T. Mark \|title=Hadean earth \|date=2020 \|publisher=Springer \|location=Cham \|isbn=978-3030466862 \|page=4}}</ref>
	Study of zircons have found that liquid water must have existed as long ago as 4400 Ma, very soon after the formation of the Earth.<ref>http://wwwrses.anu.edu.au/admin/index.php?p=harrison</ref><ref>http://info.anu.edu.au/mac/Media/Media_Releases/_2005/_November/_181105harrisoncontinents.asp</ref><ref>http://www.geology.wisc.edu/%7Evalley/zircons/cool_early/cool_early_home.html</ref> This requires the presence of an atmosphere.

			]s of the ], ], ]]]
	==Subdivisions==

			In the last decades of the 20th century, geologists identified a few Hadean rocks from western ], northwestern ], and ]. In 2015, traces of carbon minerals interpreted as "remains of ]" were found in 4.1-billion-year-old rocks in Western Australia.<ref>{{cite news \|agency=] \|last=Borenstein \|first=Seth \|date=19 October 2015 \|title=Hints of life on what was thought to be desolate early Earth \|work=] \|publisher=] \|location=Yonkers, NY \|url=http://apnews.excite.com/article/20151019/us-sci--earliest_life-a400435d0d.html \|access-date=2015-10-20}}</ref><ref>{{cite journal \|last1=Bell \|first1=Elizabeth A. \|last2=Boehnike \|first2=Patrick \|last3=Harrison \|first3=T. Mark \|last4=Mao \|first4=Wendy L. \|display-authors=3 \|date=19 October 2015 \|title=Potentially biogenic carbon preserved in a 4.1 billion-year-old zircon \|journal=Proc. Natl. Acad. Sci. U.S.A. \|issn=1091-6490 \|publisher=] \|location=Washington, D.C. \|doi=10.1073/pnas.1517557112 \|doi-access=free \|pmid=26483481 \|pmc=4664351 \|bibcode=2015PNAS..11214518B \|volume=112 \|issue=47 \|pages=14518–21}}</ref>
	Since few geological traces of this period remain on Earth there are no official subdivisions. However, several major divisions of the ] occurred during the Hadean, and so these are sometimes used unofficially to refer to the same periods of time on Earth.

			The oldest dated ] crystals, enclosed in a ] ] ] in the ] of the ] of Western Australia, date to 4.404 ± 0.008 ].<ref name=Wilde2001>{{cite journal \|last1=Wilde \|first1=Simon A. \|last2=Valley \|first2=John W. \|last3=Peck \|first3=William H. \|last4=Graham \|first4=Colin M. \|date=2001 \|title=Evidence from detrital zircons for the existence of continental crust and oceans on the Earth 4.4 Gyr ago \|journal=Nature \|pmid=11196637 \|bibcode=2001Natur.409..175W \|s2cid=4319774 \|doi=10.1038/35051550 \|volume=409 \|issue=6817 \|pages=175–178}}</ref> This zircon is a slight outlier, with the oldest consistently dated zircon falling closer to 4.35 Ga<ref name=Wilde2001/>—around 200 million years after the hypothesized time of ].
	{{Eon Footer}}
	{{Hadean Footer}}

			In many other areas, ] (or relict) ]s enclosed in older rocks indicate that younger rocks have formed on older ]s and have incorporated some of the older material. One example occurs in the ] from the Iwokrama Formation of southern Guyana where zircon cores have been dated at 4.22 Ga.<ref>{{cite journal \|last1=Nadeau \|first1=Serge \|last2=Chen \|first2=Wei \|last3=Reece \|first3=Jimmy \|last4=Lachhman \|first4=Deokumar \|last5=Ault \|first5=Randy \|last6=Faraco \|first6=Maria \|last7=Fraga \|first7=Leda \|last8=Reis \|first8=Nelson \|last9=Betiollo \|first9=Leandro \|date=2013-12-01 \|title=Guyana: the Lost Hadean crust of South America? \|journal=Brazilian Journal of Geology \|doi=10.5327/Z2317-48892013000400002 \|doi-access=free \|volume=43 \|issue=4 \|pages=601–606}}</ref>
	==See also==

			==Atmosphere==
	* ] - The first sections describe the formation of the earth
			A sizable quantity of water would have been in the material that formed Earth.<ref name=Drake>{{cite journal \|last=Drake \|first=Michael J. \|date=April 2005 \|title=Origin of water in the terrestrial planets \|journal=Meteoritics & Planetary Science \|bibcode=2005M&PS...40..515J \|doi=10.1111/j.1945-5100.2005.tb00960.x \|doi-access=free \|volume=40 \|number=4 \|pages=519–527}}</ref> Water molecules would have escaped Earth's gravity more easily when the planet was less massive during its formation. ] by short-wave ] in ] could ] ] molecules into ] and ], the former of which would be readily removed by the then-], while the latter (along with the similarly light ]) would be expected to continually leave the atmosphere (as it does to the present day) due to ].
	* ] - For details of the pre-Hadean development of the solar system

			Part of the ancient planet is theorized to have been disrupted by the ], which should have caused the melting of one or two large regions of Earth. Earth's present composition suggests that there was not complete remelting as it is difficult to completely melt and mix huge rock masses.<ref>{{cite web \|last=Taylor \|first=G. Jeffrey \|title=Origin of the Earth and Moon \|website=Solar System Exploration \|publisher=NASA \|url=http://solarsystem.nasa.gov/scitech/display.cfm?ST_ID=446 \|url-status=dead \|archive-url=https://web.archive.org/web/20150308165917/http://solarsystem.nasa.gov/scitech/display.cfm?ST_ID=446 \|archive-date=March 8, 2015}}</ref> However, a fair fraction of material should have been vaporized by this impact. The material would have condensed within 2,000 years.<ref name=Sleep2001>{{cite journal \|last1=Sleep \|first1=NH \|last2=Zahnle \|first2=K \|last3=Neuhoff \|first3=PS \|year=2001 \|title=Initiation of clement surface conditions on the earliest Earth \|journal=] \|doi=10.1073/pnas.071045698 \|doi-access=free \|pmid=11259665 \|pmc=31109 \|bibcode=2001PNAS...98.3666S \|volume=98 \|issue=7 \|pages=3666–3672}}</ref> The initial ] solidified within 5 million years,<ref>{{cite journal\|first=LT\|last=Elkins-Tanton\|title=Linked magma ocean solidification and atmospheric growth for Earth and Mars\|journal=Earth and Planetary Science Letters\|volume=271\|issue=1–4\|year=2008\|pages=181–191\|doi=10.1016/j.epsl.2008.03.062\|bibcode=2008E&PSL.271..181E }}</ref> leaving behind hot volatiles which probably resulted in a heavy {{chem\|link=carbon dioxide\|CO\|2}} atmosphere with ] and ]. The initial heavy atmosphere had a surface temperature of {{cvt\|230\|C\|F}} and an ] of above 27 ]s.<ref name=Sleep2001/>

			==Oceans==
			{{anchor\|Cool early Earth}}
			Studies of zircons have found that liquid water may have existed between 4.0 and 4.4 billion years ago, very soon after the formation of Earth.<ref name=Wilde2001/><ref name=Valley2002>{{cite journal \|last1=Valley \|first1=John W. \|last2=Peck \|first2=William H. \|last3=King \|first3=Elizabeth M. \|last4=Wilde \|first4=Simon A. \|date=April 2002 \|title=A Cool Early Earth \|journal=Geology \|doi=10.1130/0091-7613(2002)030<0351:ACEE>2.0.CO;2 \|pmid=16196254 \|bibcode=2002Geo....30..351V \|volume=30 \|issue=4 \|pages=351–354 \|url=http://www.geology.wisc.edu/%7Evalley/zircons/cool_early/cool_early_home.html \|access-date=2006-08-22 \|url-status=dead \|archive-url=https://web.archive.org/web/20130616213221/http://www.geology.wisc.edu/~valley/zircons/cool_early/cool_early_home.html \|archive-date=2013-06-16}}</ref> Liquid water oceans existed despite the high surface temperature, because at an atmospheric pressure of 27 atmospheres, water remains liquid even at those high temperatures.<ref name=Sleep2001/>

			The most likely source of the water in the Hadean ocean was outgassing from the ].<ref>{{cite encyclopedia\|title=Encyclopedia of Geology\|isbn=9780081029091\|year=2020\|publisher=Elsevier Science\|editor1-first=David\|editor1-last=Alderton\|editor2-first=Scott\|editor2-last=Elias\|entry=Precambrian\|last1=Reis\|first1=HLS\|last2=Sanchez\|first2=EAM\|page=30}}</ref> ] origin of a substantial amount of water is unlikely, due to the incompatibility of ] fractions between the Earth and comets.<ref name=Drake/>

			Asteroid impacts during the Hadean and into the Archean would have periodically disrupted the ocean. The geological record from 3.2 Gya contains evidence of multiple impacts of objects up to {{convert\|100\|km}} in diameter.<ref name=Lowe2015>{{cite journal \|last1=Lowe \|first1=DR \|last2=Byerly \|first2=GR \|year=2015 \|title=Geologic record of partial ocean evaporation triggered by giant asteroid impacts, 3.29–3.23 billion years ago \|journal=Geology \|doi=10.1130/G36665.1 \|bibcode=2015Geo....43..535L \|volume=43 \|issue=6 \|pages=535–538}}</ref> Each such impact would have boiled off up to {{convert\|100\|m}} of a global ocean, and temporarily raised the atmospheric temperature to {{convert\|500\|C\|F}}.<ref name=Lowe2015/> However, the frequency of meteorite impacts is still under study: the Earth may have gone through long periods when liquid oceans and life were possible.<ref name=Valley2002/>

			The liquid water would absorb the carbon dioxide in the early atmosphere; this would not be enough by itself to substantially reduce the amount of {{chem\|CO\|2}}.<ref name=Sleep2001/>

			==Plate tectonics==
			]
			A 2008 study of zircons found that Australian Hadean rock contains minerals pointing to the existence of ] as early as 4 billion years ago (approximately 600 million years after Earth's formation).<ref>{{cite news \|last=Chang \|first=Kenneth \|date=December 2, 2008 \|title=A New Picture of the Early Earth \|work=] \|url=https://www.nytimes.com/2008/12/02/science/02eart.html?_r=1}}</ref> However, some geologists suggest that the zircons could have been formed by meteorite impacts.<ref>{{cite web \|last1=Kenny \|first1=GG \|last2=Whitehouse \|first2=MJ \|last3=Kamber \|first3=BS \|display-authors=etal \|date=April 12, 2016 \|title=Differentiated impact melt sheets may be a potential source of Hadean detrital zircon \|url=http://geology.geoscienceworld.org/content/44/6/435 \|accessdate=March 6, 2017}}</ref> The direct evidence of Hadean geology from zircons is limited, because the zircons are largely gathered in one locality in Australia.<ref name=Korenaga2021/><ref name=Harrison2020/> Geophysical models are underconstrained, but can paint a general picture of the state of Earth in the Hadean.<ref name=Korenaga2021/><ref>{{cite journal \|last1=Korenaga \|first1=J \|last2=Planavsky \|first2=NJ \|last3=Evans \|first3=DAD \|year=2017 \|title=Global water cycle and the coevolution of Earth's interior and surface environment. \|journal=Phil. Trans. R. Soc. A \|doi=10.1098/rsta.2015.0393 \|pmid=28416728 \|pmc=5394256 \|bibcode=2017RSPTA.37550393K \|s2cid=2958757 \|volume=375 \|issue=2094 \|page=20150393}}</ref>

			] in the Hadean was likely vigorous, due to lower ].<ref name=Korenaga2021/> The lower viscosity was due to the high levels of ] and the fact that water in the mantle had not yet fully outgassed.<ref name=Korenaga2021a>{{cite journal \|last=Korenaga \|first=J \|year=2021 \|title=Hadean geodynamics and the nature of early continental crust \|journal=Precambrian Res \|doi=10.1016/j.precamres.2021.106178 \|bibcode=2021PreR..35906178K \|s2cid=233441822 \|volume=359 \|page=106178}}</ref> Whether the vigorous convection led to plate tectonics in the Hadean or was confined under a rigid lid is still a matter of debate.<ref name=Korenaga2021/><ref name=Windley2021>{{cite journal \|last1=Windley \|first1=BF \|last2=Kusky \|first2=T \|last3=Polat \|first3=A \|year=2021 \|title=Onset of plate tectonics by the Eoarchean \|journal=Precambrian Res \|doi=10.1016/j.precamres.2020.105980 \|bibcode=2021PreR..35205980W \|s2cid=228993361 \|volume=352 \|page=105980}}</ref><ref name=Harrison2020>{{cite book \|last=Harrison \|first=T. Mark \|year=2020 \|title=Hadean Earth \|publisher=Springer \|location=Cham, Switzerland \|isbn=978-3-030-46686-2 \|doi=10.1007/978-3-030-46687-9 \|page=\|bibcode=2020hade.book.....H \|s2cid=128932829 }}</ref><ref name=Tang2016>{{cite journal \|last1=Tang \|first1=M \|last2=Chen \|first2=K \|last3=Rudnick \|first3=RL \|year=2016 \|title=Archean upper crust transition from mafic to felsic marks the onset of plate tectonics \|journal=Science \|doi=10.1126/science.aad5513 \|pmid=26798012\|bibcode=2016Sci...351..372T \|s2cid=206643793 \|volume=351 \|issue=6271 \|pages=372–375\|doi-access=free }}</ref> The presence of Hadean oceans is thought to have triggered plate tectonics.<ref name=Regenauer2001>{{cite journal \|last1=Regenauer-Lieb \|first1=K \|last2=Yuen \|first2=DA \|last3=Branlund \|first3=J \|year=2001 \|title=The initiation of subduction: Criticality by addition of water? \|journal=Science \|doi=10.1126/science.1063891 \|pmid=11641494 \|bibcode=2001Sci...294..578R \|s2cid=43547982 \|volume=294 \|issue=5542 \|pages=578–580}}</ref>

			] due to plate tectonics would have removed carbonate from the early oceans, contributing to the removal of the {{chem\|CO\|2}}-rich early atmosphere. Removal of this early atmosphere is evidence of Hadean plate tectonics.<ref name=Sleep2014>{{cite journal \|last1=Sleep \|first1=NH \|last2=Zahnle \|first2=KJ \|last3=Lupu \|first3=RE \|year=2014 \|title=Terrestrial aftermath of the Moon-forming impact \|journal=Phil. Trans. R. Soc. A \|doi=10.1098/rsta.2013.0172 \|pmid=25114303 \|bibcode=2014RSPTA.37230172S \|s2cid=6902632 \|volume=372 \|issue=2024 \|page=20130172\|doi-access=free }}</ref>

			If plate tectonics occurred in the Hadean, it would have formed ].<ref name=Guo2020>{{cite journal \|last1=Guo \|first1=M \|last2=Korenaga \|first2=J \|year=2020 \|title=Argon constraints on the early growth of felsic continental crust \|journal=Science Advances \|doi=10.1126/sciadv.aaz6234 \|pmid=32671213 \|pmc=7314546 \|bibcode=2020SciA....6.6234G \|volume=6 \|issue=21 \|page=eaaz6234}}</ref> Different models predict different amounts of continental crust during the Hadean.<ref name=Harrison2009>{{cite journal\|last=Harrison\|first=TM\|title=The Hadean crust: evidence from> 4 Ga zircons\|journal=Annual Review of Earth and Planetary Sciences\|volume=37\|year=2009\|issue=1 \|pages=479–505\|doi=10.1146/annurev.earth.031208.100151 \|bibcode=2009AREPS..37..479H }}</ref> The work of Dhiume ''et al.'' predicts that by the end of the Hadean, the continental crust had only 25% of today's area.<ref name=Dhuime2012>{{cite journal \|last1=Dhuime \|first1=B \|last2=Hawkesworth \|first2=CJ \|last3=Cawood \|first3=PA \|last4=Storey \|first4=CD \|year=2012 \|title=A change in the geodynamics of continental growth 3 billion years ago \|journal=Science \|doi=10.1126/science.1216066 \|pmid=22422979 \|bibcode=2012Sci...335.1334D \|s2cid=206538532 \|volume=335 \|issue=6074 \|pages=1334–1336}}</ref> The models of Korenaga, ''et al.'' predict that the continental crust grew to present-day volume sometime between 4.2 and 4.0 ].<ref name=Guo2020/><ref>{{cite journal \|last1=Rosas \|first1=JC \|last2=Korenaga \|first2=J \|year=2018 \|title=Rapid crustal growth and efficient crustal recycling in the early Earth: Implications for Hadean and Archean geodynamics \|journal=Earth Planet. Sci. Lett. \|doi=10.1016/j.epsl.2018.04.051 \|bibcode=2018E&PSL.494...42R \|s2cid=13666395 \|volume=494 \|pages=42–49\|doi-access=free }}</ref>

			==Continents==
			The amount of exposed land in the Hadean is only loosely dependent on the amount of continental crust: it also depends on the ocean level.<ref name=Korenaga2021/> In models where plate tectonics started in the Archean, Earth has a global ocean in the Hadean.<ref>{{cite journal \|last=Russell \|first=MJ \|year=2021 \|title=The "Water Problem", the illusory pond and life's submarine emergence—A review \|journal=Life \|doi=10.3390/life11050429 \|doi-access=free \|pmid=34068713 \|pmc=8151828 \|volume=11 \|issue=5 \|page=429\|bibcode=2021Life...11..429R }}</ref><ref>{{cite journal \|last=Voosen \|first=P \|year=2021 \|title=Ancient Earth was a water world \|journal=Science \|doi=10.1126/science.371.6534.1088 \|pmid=33707245 \|bibcode=2021Sci...371.1088V \|s2cid=232206926 \|volume=371 \|issue=6534 \|pages=1088–1089}}</ref> The high heat of the mantle may have made it difficult to support high elevations in the Hadean.<ref>{{cite journal \|last1=Monteux \|first1=J \|last2=Andrault \|first2=D \|last3=Guitreau \|first3=M \|last4=Samuel \|first4=H \|last5=Demouchy \|first5=S \|year=2020 \|title=A mushy Earth's mantle for more than 500 Myr after the magma ocean solidification \|journal=Geophys. J. Int. \|doi=10.1093/gji/ggaa064 \|volume=221 \|issue=2 \|pages=1165–1181\|doi-access=free }}</ref><ref>{{cite journal \|last1=Rey \|first1=PF \|last2=Coltice \|first2=N \|year=2008 \|title=Neoarchean lithospheric strengthening and the coupling of Earth's geochemical reservoirs \|journal=Geology \|doi=((10.1130/G25031A.1;)) \|bibcode=2008Geo....36..635R \|volume=36 \|issue=8 \|pages=635–638}}</ref> If continents did form in the Hadean, their growth competed with outgassing of water from the mantle.<ref name=Korenaga2021/> Continents may have appeared in the mid-Hadean, and then disappeared under a thick ocean by the end of the Hadean.<ref>{{cite journal \|last1=Bada \|first1=JL \|last2=Korenaga \|first2=J \|year=2018 \|title=Exposed areas above sea level on Earth >3.5 Gyr ago: Implications for prebiotic and primitive biotic chemistry \|journal=Life \|doi=10.3390/life8040055 \|doi-access=free \|pmid=30400350 \|pmc=6316429 \|volume=8 \|issue=4 \|page=55\|bibcode=2018Life....8...55B }}</ref> The limited amount of land has implications for the ].<ref name=Korenaga2021/>

			==Possible life==

			Abundant Hadean-like ] ]s were shown by Salditt ''et al.'' to have the potential to support the synthesis and replication of ] and thus possibly the evolution of a primitive life form.<ref name = Salditt2023>{{cite journal\|last1=Salditt\|first1=A\|last2=Karr\|first2=L\|last3=Salibi\|first3=E\|last4=Le Vay\|first4=K\|last5=Braun\|first5=D\|last6=Mutschler\|first6=H\|title=Ribozyme-mediated RNA synthesis and replication in a model Hadean microenvironment\|journal=Nat. Commun.\|date=2023-03-17\|volume=14\|issue=1\|page=1495\|doi=10.1038/s41467-023-37206-4\|pmid=36932102\|pmc=10023712\|bibcode=2023NatCo..14.1495S}}</ref> Porous rock systems comprising heated air-water interfaces were shown to allow ]-] RNA replication of sense and antisense strands followed by subsequent strand dissociation, thus enabling combined synthesis, release and folding of active ribozymes.<ref name = Salditt2023/> Such a primitive RNA system also may have been able to undergo template strand switching during replication (]) as occurs during the RNA replication of extant ]es.<ref>{{cite journal\|last1=Su\|first1=S\|last2=Wong\|first2=G\|last3=Shi\|first3=W\|last4=Liu\|first4=J\|last5=Lai\|first5=ACK\|last6=Zhou\|first6=J\|last7=Liu\|first7=W\|last8=Bi\|first8=Y\|last9=Gao\|first9=GF\|display-authors=4\|title=Epidemiology, Genetic Recombination, and Pathogenesis of Coronaviruses\|journal=Trends Microbiol\|year=2016\|volume=24\|issue=6\|pages=490–502\|doi=10.1016/j.tim.2016.03.003\|pmid=27012512\|pmc=7125511}}</ref>
			A study published in 2024 inferred the ] to have emerged during the Hadean, between 4.09 and 4.33 Gya.<ref>{{cite journal \|last1=Moody \|first1=Edmund \|last2=Álvarez-Carretero \|first2=Sandra \|last3=Mahendrarajah \|first3=Tara \|title=The nature of the last universal common ancestor and its impact on the early Earth system \|journal=Nat. Ecol. Evol. \|date=12 July 2024 \|volume=8 \|issue=9 \|pages=1654–1666 \|doi=10.1038/s41559-024-02461-1 \|doi-access=free \|pmid=38997462 \|pmc=11383801 \|bibcode=2024NatEE...8.1654M }}</ref>

			Although the early part of the ] happened during the Hadean, the impacts were frequent only on a cosmic scale, with thousands or even millions of years between each event. As Earth already had oceans, life would have been possible, but vulnerable to ]s caused by those impacts. The risk would not be on the frequency, but on the size of the impactor, and remains on the Moon suggest impactors bigger than the ] that caused the ]. An impactor big enough may erase all life on the planet, although some models suggest that microscopic life may still survive it underground or in the oceanic depths.<ref>{{cite book \|last=Bennett \|first=Jeffrey \|author-link= \|date=2017 \|title=Life in the universe \|url= \|location=United States \|publisher=Pearson \|pages=124-125 \|isbn=978-0-13-408908-9}}</ref>

			==See also==
			* {{annotated link\|Chaotian (geology)}}
			* {{annotated link\|Faint young Sun paradox}}
	* ]		* ]
			* {{annotated link\|Hadean zircon}}
			* {{annotated link\|History of Earth}} – the first sections describe the formation of Earth
			* {{annotated link\|Oldest dated rocks}}
			* {{annotated link\|Precambrian}}
			* {{annotated link\|Timeline of natural history}}

	==References==		==References==
			{{reflist}}
	<references/>
	* Valley, John W., William H. Peck, Elizabeth M. King (1999) ''Zircons Are Forever'', The Outcrop for 1999, University of Wisconsin-Madison – ''Evidence from detrital zircons for the existence of continental crust and oceans on the Earth 4.4 Gyr ago'' Accessed Jan. 10, 2006
	* Wilde S.A., Valley J.W., Peck W.H. and Graham C.M. (2001) ''Evidence from detrital zircons for the existence of continental crust and oceans on the Earth 4.4 Gyr ago.'' Nature, v. 409, pp. 175-178.
	* Wyche, S., D. R. Nelson and A. Riganti (2004) ''4350–3130 Ma detrital zircons in the Southern Cross Granite–Greenstone Terrane, Western Australia: implications for the early evolution of the Yilgarn Craton'', Australian Journal of Earth Sciences Volume 51 Accessed Jan. 10, 2006

			==Further reading==
	]
			*{{cite journal \|last1=Hopkins \|first1=Michelle \|last2=Harrison \|first2=T. Mark \|last3=Manning \|first3=Craig E. \|year=2008 \|title=Low heat flow inferred from >4 Gyr zircons suggests Hadean plate boundary interactions \|journal=] \|doi=10.1038/nature07465 \|pmid=19037314 \|bibcode=2008Natur.456..493H \|s2cid=4417456\|volume=456 \|issue=7221 \|pages=493–496}}
			*{{cite journal \|last1=Wyche \|first1=S. \|last2=Nelson \|first2=D. R. \|last3=Riganti \|first3=A. \|year=2004 \|title=4350–3130 Ma detrital zircons in the Southern Cross Granite–Greenstone Terrane, Western Australia: implications for the early evolution of the Yilgarn Craton \|journal=Australian Journal of Earth Sciences \|doi=10.1046/j.1400-0952.2003.01042.x \|bibcode=2004AuJES..51...31W \|volume=51 \|issue=1 \|pages=31–45}}
			*{{cite journal \|last1=Carley \|first1=Tamara L. \|last2=Miller \|first2=Calvin F. \|last3=Wooden \|first3=Joseph L. \|last4=Padilla \|first4=Abraham J. \|last5=Schmitt \|first5=Axel K. \|last6=Economos \|first6=Rita C. \|last7=Bindeman \|first7=Ilya N. \|last8=Jordan \|first8=Brennan T. \|display-authors=1 \|year=2014 \|title=Iceland is not a magmatic analog for the Hadean: Evidence from the zircon record \|journal=Earth and Planetary Science Letters \|doi=10.1016/j.epsl.2014.08.015 \|bibcode=2014E&PSL.405...85C \|volume=405 \|issue=1 \|pages=85–97}}
			*{{cite journal \|last1=Marchi \|first1=S. \|last2=Bottke \|first2=W. F. \|last3=Elkins-Tanton \|first3=L. T. \|last4=Bierhaus \|first4=M. \|last5=Wuennemann \|first5=K. \|last6=Morbidelli \|first6=A. \|last7=Kring \|first7=D. A. \|display-authors=1 \|year=2014 \|title=Widespread mixing and burial of Earth's Hadean crust by asteroid impacts \|journal=Nature \|doi=10.1038/nature13539 \|volume=511 \|issue=7511 \|pages=578–582\|pmid=25079556 \|bibcode=2014Natur.511..578M \|s2cid=205239647 }}

			==External links==
			{{Commons}}
			*
			*

			{{Hadean Footer}}
			{{Geological history\|c}}
			{{Authority control}}

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Latest revision as of 21:04, 22 December 2024

Geologic eon, 4567–4031 million years ago For the Romanian chef, see Adrian Hădean.

Hadean

4567.3 ± 0.16 – 4031 ± 3 Ma Pha. Proterozoic Archean Had.

Chronology

−4500 —–—–−4000 —–—–−3500 —–—–−3000 —–—–−2500 —–—–−2000 —–—–−1500 —–—–−1000 —–—–−500 —–—–0 —

PrecambrianHadean Archean Proterozoic Phaner
ozoic Eoarchean Paleoarchean Mesoarchean Neoarchean Paleoproterozoic Mesoproterozoic Neoproterozoic Paleozoic Mesozoic Cenozoic

Vertical axis scale: Millions of years ago

Etymology

Synonym(s)

Priscoan Period
Harland et al., 1989

Usage information

Celestial body

Earth

Regional usage

Global (ICS)

Definition

Chronological unit

Eon

Stratigraphic unit

Eonothem

First proposed by

Preston Cloud, 1972

Time span formality

Formal

Lower boundary definition

Age of the oldest solid material in the Solar System's protoplanetary disk (4567.30 ± 0.16) Ma

Lower GSSA ratified

October 5th, 2022

Upper boundary definition

Ten oldest U-Pb zircon ages

Upper boundary GSSA

Along the Acasta River, Northwest Territories, Canada
65°10′26″N 115°33′14″W / 65.1738°N 115.5538°W / 65.1738; -115.5538

Upper GSSA ratified

2023

The Hadean (/heɪˈdiːən, ˈheɪdiən/ hay-DEE-ən, HAY-dee-ən) is the first and oldest of the four known geologic eons of Earth's history, starting with the planet's formation about 4.6 billion years ago (estimated 4567.30 ± 0.16 million years ago set by the age of the oldest solid material in the Solar System — protoplanetary disk dust particles — found as chondrules and calcium–aluminium-rich inclusions in some meteorites about 4.567 billion years old), and ended 4.031 billion years ago. The interplanetary collision that created the Moon occurred early in this eon. The Hadean eon was succeeded by the Archean eon, with the Late Heavy Bombardment hypothesized to have occurred at the Hadean-Archean boundary.

Hadean rocks are very rare, largely consisting of granular zircons from one locality (Jack Hills) in Western Australia. Hadean geophysical models remain controversial among geologists: plate tectonics and the growth of cratons into continents may have started in the Hadean, but there is still uncertainty.

Earth in the early Hadean had a very thick hydride-rich atmosphere whose composition likely resembled the solar nebula and the gas giants, with mostly water vapor, methane and ammonia. As the Earth's surface cooled, vaporized atmospheric water condensed into liquid water and eventually a superocean covering nearly all of the planet was formed, turning Earth into an ocean planet. Volcanic outgassing and asteroid bombardments further altered the Hadean atmosphere eventually into the nitrogen- and carbon dioxide-rich, weakly reducing Paleoarchean atmosphere.

Etymology

The eon's name "Hadean" comes from Hades, the Greek god of the underworld (whose name is also used to describe the underworld itself), referring to the hellish conditions then prevailing on early Earth: the planet had just been formed from recent accretion, and its surface was still molten with superheated lava due to that, the abundance of short-lived radioactive elements, and frequent impact events with other Solar System bodies.

The term was coined by American geologist Preston Cloud, originally to label the period before the earliest known rocks on Earth. W.B. Harland later coined an almost synonymous term, the Priscoan period, from priscus, a Latin word for 'ancient'. Other, older texts refer to the eon as the Pre-Archean.

Rock dating

Further information: Oldest dated rocks

Prior to the 1980s and the discovery of Hadean lithic fragments, scientific narratives of the early Earth explanations were almost entirely in the hands of geodynamic modelers.

In the last decades of the 20th century, geologists identified a few Hadean rocks from western Greenland, northwestern Canada, and Western Australia. In 2015, traces of carbon minerals interpreted as "remains of biotic life" were found in 4.1-billion-year-old rocks in Western Australia.

The oldest dated zircon crystals, enclosed in a metamorphosed sandstone conglomerate in the Jack Hills of the Narryer Gneiss Terrane of Western Australia, date to 4.404 ± 0.008 Ga. This zircon is a slight outlier, with the oldest consistently dated zircon falling closer to 4.35 Ga—around 200 million years after the hypothesized time of Earth's formation.

In many other areas, xenocryst (or relict) Hadean zircons enclosed in older rocks indicate that younger rocks have formed on older terranes and have incorporated some of the older material. One example occurs in the Guiana shield from the Iwokrama Formation of southern Guyana where zircon cores have been dated at 4.22 Ga.

Atmosphere

A sizable quantity of water would have been in the material that formed Earth. Water molecules would have escaped Earth's gravity more easily when the planet was less massive during its formation. Photodissociation by short-wave ultraviolet in sunlight could split surface water molecules into oxygen and hydrogen, the former of which would be readily removed by the then-reducing atmosphere, while the latter (along with the similarly light helium) would be expected to continually leave the atmosphere (as it does to the present day) due to atmospheric escape.

Part of the ancient planet is theorized to have been disrupted by the impact that created the Moon, which should have caused the melting of one or two large regions of Earth. Earth's present composition suggests that there was not complete remelting as it is difficult to completely melt and mix huge rock masses. However, a fair fraction of material should have been vaporized by this impact. The material would have condensed within 2,000 years. The initial magma ocean solidified within 5 million years, leaving behind hot volatiles which probably resulted in a heavy CO
₂ atmosphere with hydrogen and water vapor. The initial heavy atmosphere had a surface temperature of 230 °C (446 °F) and an atmospheric pressure of above 27 standard atmospheres.

Oceans

Studies of zircons have found that liquid water may have existed between 4.0 and 4.4 billion years ago, very soon after the formation of Earth. Liquid water oceans existed despite the high surface temperature, because at an atmospheric pressure of 27 atmospheres, water remains liquid even at those high temperatures.

The most likely source of the water in the Hadean ocean was outgassing from the Earth's mantle. Bombardment origin of a substantial amount of water is unlikely, due to the incompatibility of isotope fractions between the Earth and comets.

Asteroid impacts during the Hadean and into the Archean would have periodically disrupted the ocean. The geological record from 3.2 Gya contains evidence of multiple impacts of objects up to 100 kilometres (62 mi) in diameter. Each such impact would have boiled off up to 100 metres (330 ft) of a global ocean, and temporarily raised the atmospheric temperature to 500 °C (932 °F). However, the frequency of meteorite impacts is still under study: the Earth may have gone through long periods when liquid oceans and life were possible.

The liquid water would absorb the carbon dioxide in the early atmosphere; this would not be enough by itself to substantially reduce the amount of CO
₂.

Plate tectonics

A 2008 study of zircons found that Australian Hadean rock contains minerals pointing to the existence of plate tectonics as early as 4 billion years ago (approximately 600 million years after Earth's formation). However, some geologists suggest that the zircons could have been formed by meteorite impacts. The direct evidence of Hadean geology from zircons is limited, because the zircons are largely gathered in one locality in Australia. Geophysical models are underconstrained, but can paint a general picture of the state of Earth in the Hadean.

Mantle convection in the Hadean was likely vigorous, due to lower viscosity. The lower viscosity was due to the high levels of radiogenic heat and the fact that water in the mantle had not yet fully outgassed. Whether the vigorous convection led to plate tectonics in the Hadean or was confined under a rigid lid is still a matter of debate. The presence of Hadean oceans is thought to have triggered plate tectonics.

Subduction due to plate tectonics would have removed carbonate from the early oceans, contributing to the removal of the CO
₂-rich early atmosphere. Removal of this early atmosphere is evidence of Hadean plate tectonics.

If plate tectonics occurred in the Hadean, it would have formed continental crust. Different models predict different amounts of continental crust during the Hadean. The work of Dhiume et al. predicts that by the end of the Hadean, the continental crust had only 25% of today's area. The models of Korenaga, et al. predict that the continental crust grew to present-day volume sometime between 4.2 and 4.0 Gya.

Continents

The amount of exposed land in the Hadean is only loosely dependent on the amount of continental crust: it also depends on the ocean level. In models where plate tectonics started in the Archean, Earth has a global ocean in the Hadean. The high heat of the mantle may have made it difficult to support high elevations in the Hadean. If continents did form in the Hadean, their growth competed with outgassing of water from the mantle. Continents may have appeared in the mid-Hadean, and then disappeared under a thick ocean by the end of the Hadean. The limited amount of land has implications for the origin of life.

Possible life

Abundant Hadean-like geothermal microenvironments were shown by Salditt et al. to have the potential to support the synthesis and replication of RNA and thus possibly the evolution of a primitive life form. Porous rock systems comprising heated air-water interfaces were shown to allow ribozyme-catalyzed RNA replication of sense and antisense strands followed by subsequent strand dissociation, thus enabling combined synthesis, release and folding of active ribozymes. Such a primitive RNA system also may have been able to undergo template strand switching during replication (genetic recombination) as occurs during the RNA replication of extant coronaviruses. A study published in 2024 inferred the last common ancestor of all current life to have emerged during the Hadean, between 4.09 and 4.33 Gya.

Although the early part of the Late Heavy Bombardment happened during the Hadean, the impacts were frequent only on a cosmic scale, with thousands or even millions of years between each event. As Earth already had oceans, life would have been possible, but vulnerable to extinction events caused by those impacts. The risk would not be on the frequency, but on the size of the impactor, and remains on the Moon suggest impactors bigger than the Chicxulub impactor that caused the extinction of dinosaurs. An impactor big enough may erase all life on the planet, although some models suggest that microscopic life may still survive it underground or in the oceanic depths.

References

^ Halla, J.; et al. (2024). "Ratification of the base of the ICS Geological Time Scale: the Global Standard Stratigraphic Age (GSSA) for the Hadean lower boundary". Episodes. 47 (2): 381–389. doi:10.18814/epiiugs/2024/024002. hdl:2164/23819.
^ Cohen, Kim (October 2022). "New edition of the Chart - 2022-10". International Commission on Stratigraphy. Retrieved 16 January 2023. 2022/10 - Hadean: GSSA instated as ratified by IUGS (5-10-2022). The GSSA is 4,567.30 ± 0.16 Ma.
"Global Boundary Stratotype Section and Point". International Commission of Stratigraphy. Retrieved 29 October 2023.
Dalrymple, G. Brent (2001). "The age of the Earth in the twentieth century: a problem (mostly) solved". Geological Society, London, Special Publications. 190 (1): 205–221. Bibcode:2001GSLSP.190..205D. doi:10.1144/gsl.sp.2001.190.01.14. S2CID 130092094. Retrieved 2022-10-02.
"Age of the Earth". U.S. Geological Survey. 1997. Archived from the original on 23 December 2005. Retrieved 2022-10-03.
Strachan, R.; Murphy, J.B.; Darling, J.; Storey, C.; Shields, G. (2020). "Precambrian (4.56–1 Ga)". In Gradstein, F.M.; Ogg, J.G.; Schmitz, M.D.; Ogg, G.M. (eds.). Geologic Time Scale 2020. Amsterdam: Elsevier. pp. 482–483. doi:10.1016/B978-0-12-824360-2.00016-4. ISBN 978-0-12-824360-2. S2CID 229513433.
^ Korenaga, J (2021). "Was There Land on the Early Earth?". Life. 11 (11): 1142. Bibcode:2021Life...11.1142K. doi:10.3390/life11111142. PMC 8623345. PMID 34833018.
^ Dhuime, B; Hawkesworth, CJ; Cawood, PA; Storey, CD (2012). "A change in the geodynamics of continental growth 3 billion years ago". Science. 335 (6074): 1334–1336. Bibcode:2012Sci...335.1334D. doi:10.1126/science.1216066. PMID 22422979. S2CID 206538532.
^ Harrison, TM (2009). "The Hadean crust: evidence from> 4 Ga zircons". Annual Review of Earth and Planetary Sciences. 37 (1): 479–505. Bibcode:2009AREPS..37..479H. doi:10.1146/annurev.earth.031208.100151.
^ Windley, BF; Kusky, T; Polat, A (2021). "Onset of plate tectonics by the Eoarchean". Precambrian Res. 352: 105980. Bibcode:2021PreR..35205980W. doi:10.1016/j.precamres.2020.105980. S2CID 228993361.
Cloud, Preston (1972). "A working model of the primitive Earth". American Journal of Science. 272 (6): 537–548. Bibcode:1972AmJS..272..537C. doi:10.2475/ajs.272.6.537.
Bleeker, W. (2004). "Chapter 10. Toward a 'natural' Precambrian time scale". In Gradstein, Felix M.; Ogg, James G.; Smith, Alan G. (eds.). A Geologic Time Scale. Cambridge, UK: Cambridge University Press. p. 145. ISBN 9780521786737.
"Priscoan". Oxford Living dictionaries. Archived from the original on 2018-11-29.
Shaw, D.M. (1975). Early history of the Earth. Proceedings of the NATO Advanced Study Institute. Leicester: John Wiley. pp. 33–53. ISBN 0-471-01488-5.
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External links

v t e Hadean Eon
Cryptic Basin Groups Nectarian Lower Imbrian
The Hadean does not have any subdivisions recognized by the International Commission on Stratigraphy. These subdivisions represent one proposal that is loosely based on the lunar geologic timescale.

Geological history of Earth

Cenozoic Era
(present–66.0 Ma)

Quaternary (present–2.58 Ma)	Holocene (present–11.7 ka) Pleistocene (11.7 ka–2.58 Ma)
Neogene (2.58–23.0 Ma)	Pliocene (2.59–5.33 Ma) Miocene (5.33–23.0 Ma)
Paleogene (23.0–66.0 Ma)	Oligocene (23.0–33.9 Ma) Eocene (33.9–56.0 Ma) Paleocene (56.0–66.0 Ma)

Mesozoic Era
(66.0–252 Ma)

Cretaceous (66.0–145 Ma)	Late (66.0–100 Ma) Early (100–145 Ma)
Jurassic (145–201 Ma)	Late (145–164 Ma) Middle (164–174 Ma) Early (174–201 Ma)
Triassic (201–252 Ma)	Late (201–237 Ma) Middle (237–247 Ma) Early (247–252 Ma)

Paleozoic Era
(252–539 Ma)

Permian (252–299 Ma)	Lopingian (252–260 Ma) Guadalupian (260–272 Ma) Cisuralian (272–299 Ma)
Carboniferous (299–359 Ma)	Pennsylvanian (299–323 Ma) Mississippian (323–359 Ma)
Devonian (359–419 Ma)	Late (359–383 Ma) Middle (383–393 Ma) Early (393–419 Ma)
Silurian (419–444 Ma)	Pridoli (419–423 Ma) Ludlow (423–427 Ma) Wenlock (427–433 Ma) Llandovery (433–444 Ma)
Ordovician (444–485 Ma)	Late (444–458 Ma) Middle (458–470 Ma) Early (470–485 Ma)
Cambrian (485–539 Ma)	Furongian (485–497 Ma) Miaolingian (497–509 Ma) Series 2 (509–521 Ma) Terreneuvian (521–539 Ma)

Proterozoic Eon
(539 Ma–2.5 Ga)

Neoproterozoic (539 Ma–1 Ga)	Ediacaran (539–635 Ma) Cryogenian (635–720 Ma) Tonian (720 Ma–1 Ga)
Mesoproterozoic (1–1.6 Ga)	Stenian (1–1.2 Ga) Ectasian (1.2–1.4 Ga) Calymmian (1.4–1.6 Ga)
Paleoproterozoic (1.6–2.5 Ga)	Statherian (1.6–1.8 Ga) Orosirian (1.8–2.05 Ga) Rhyacian (2.05–2.3 Ga) Siderian (2.3–2.5 Ga)