Tectonics and Surface Environments on Early Earth

Abstract

The mode of tectonics that governed early Earth is controversial. This makes it challenging to infer surface environments relevant to the origin of life. The majority of the literature published in the past two decades was inclined to favor the appearance of plate tectonics sometime around the mid-Archean (∼3 Ga), with the operation of stagnant lid convection (or its variants) dominant in the earlier part of Earth’s history. However, the available and increasing geological record from early Earth is actually equivocal, and there is no theoretical basis to prefer stagnant lid convection over plate tectonics. In fact, such a delayed onset of plate tectonics would inhibit the emergence of life in the Archean, let alone in the Hadean. On the contrary, rapid plate tectonics in the early Hadean, enabled by the fractional crystallization of a magma ocean, could quickly transform inclement young Earth into a habitable planet, with formation of multiple surface environments potentially conducive to abiogenesis.

Get full access to this article

View all access options for this article.

References

Abe

. Physical state of the very early Earth. Lithos, 1993; 30(3–4):223–235.

Ahrens

. Impact erosion of terrestrial planetary atmospheres. Annu Rev Earth Planet Sci, 1993; 21(1):525–555.

Al Asad

, Lau

HCP

. Coupled fates of Earth’s mantle and core: Early sluggish-lid tectonics and a long-lived geodynamo. Sci Adv, 2024; 10(31):eadp1991.

Al Asad

, Lau

HCP

, Crowley

, et al. Modes of mantle convection, their stability, and what controls their existence. JGR Solid Earth, 2023; 128(10):e2023JB027274; doi: 10.1029/2023JB027274

Amelin

, Lee

D-C

, Halliday

. Early-middle Archaean crustal evolution deduced from Lu-Hf and U-Pb isotopic studies of single zircon grains. Geochim. Cosmochim. Acta, 2000; 64(24):4205–4225.

Amelin

, Lee

, Halliday

, et al. Nature of the Earth’s earliest crust from hafnium isotopes in single detrital zircons. Nature, 1999; 399(6733):252–255.

Annen

, Blundy

, Sparks

RSJ

. The genesis of intermediate and silicic magmas in deep crustal hot zones. J. Petrol, 2006; 47(3):505–539.

Armstrong

, Frost

, McCammon

, et al. Deep magma ocean formation set the oxidation state of Earth’s mantle. Science, 2019; 365(6456):903–906.

Bada

, Korenaga

. Exposed areas above sea level on Earth >3.5 gyr ago: Implications for prebiotic and primitive biotic chemistry. Life (Basel), 2018; 8(4):55; doi: 10.3390/life8040055

10.

Baross

, Anderson

, Stüeken

. The environmental roots of the origin of life. In: Planetary Astrobiology. ( Meadows

, Arney

, Schmidt

, Des Marais

., eds.) University of Arizona; 2020, pp. 71–92.

11.

Bauer

, Fisher

, Vervoort

, et al. Coupled zircon Lu-Hf and U-Pb isotopic analyses of the oldest terrestrial crust, the >4.03 Ga Acasta Gneiss Complex. Earth Planet. Sci. Lett, 2017; 458:37–48.

12.

Bauer

, Reimink

, Chacko

, et al. Hafnium isotopes in zircons document the gradual onset of mobile-lid tectonics. Geochem Persp Let, 2020; 14:1–6.

13.

Bédard

. A catalytic delamination-driven model for coupled genesis of Archaean crust and sub-continental lithospheric mantle. Geochim. Cosmochim. Acta, 2006; 70(5):1188–1214.

14.

Bédard

. Stagnant lids and mantle overturns: Implications for Archaean tectonics, magmagenesis, crustal growth, mantle evolution, and the start of plate tectonics. Geosci. Frontiers, 2018; 9(1):19–49.

15.

Bell

, Harrison

, Kohl

, et al. Eoarchean crustal evolution of the Jack Hills zircon source and loss of Hadean crust. Geochim. Cosmochim. Acta, 2014; 146:27–42.

16.

Belousova

, Kostitsyn

, Griffin

, et al. The growth of the continental crust: Constraints from zircon Hf-isotope data. Lithos, 2010; 119(3–4):457–466.

17.

Benner

, Bell

, Biondi

, et al. When did life likely emerge on Earth in an RNA-first process? Chem. Sys. Chem, 2019; 2:31900035.

18.

Bennett

, Brandon

, Nutman

. Coupled ¹⁴²Nd-¹⁴³Nd isotopic evidence for Hadean mantle dynamics. Science, 2007; 318(5858):1907–1910.

19.

Bercovici

, Schubert

, Glatzmaier

, et al. Three-dimensional thermal convection in a spherical shell. J Fluid Mech, 1989; 206:75–104.

20.

Billen

. Modeling the dynamics of subducting slabs. Annu Rev Earth Planet Sci, 2008; 36(1):325–356.

21.

Borisova

, Nedelec

, Zagrtdenov

, et al. Hadean zircon formed due to hydrated ultramafic protocrust melting. Geology, 2021a;50(3):300–304.

22.

Borisova

, Zagrtdenov

, Toplis

, et al. Hydrated peridotite - basaltic melt interaction part I: Planetary felsic crust formation at shallow depth. Frontiers Earth Sci, 2021b;9:640464; doi: 10.3389/feart.2021.640464

23.

Boukaré

C-E

, Parmentier

, Parman

. Timing of mantle overturn during magma ocean solidification. Earth Planet. Sci. Lett, 2018; 491:216–225.

24.

Bowring

, Williams

. Priscoan (4.00-4.03 Ga) orthogneisses from northwestern Canada. Contrib. Mineral. Petrol, 1999; 134(1):3–16.

25.

Brenner

, Fu

, Evans

DAD

, et al. Paleomagnetic evidence for modern-like plate motion velocities at 3.2 Ga. Sci Adv, 2020; 6(17):eaaz8670.

26.

Brenner

, Fu

, Kylander-Clark

ARC

, et al. Plate motion and a dipolar geomagnetic field at 3.25 Ga. Proc. Nat. Acad. Sci. USA, 2022; 119:e2210258119.

27.

Brown

, Johnson

, Gardiner

. Plate tectonics and the Archean Earth. Annu Rev Earth Planet Sci, 2020; 48(1):291–320.

28.

Bunge

H-P

, Richards

, Baumgardner

. Effect of depth-dependent viscosity on the planform of mantle convection. Nature, 1996; 379(6564):436–438.

29.

Campbell

, Taylor

. No water, no granites—no oceans, no continents. Geophys. Res. Lett, 1983; 10(11):1061–1064.

30.

Canup

, Righter

, Dauphas

, et al. Origin of the Moon. Rev. Mineral. Geochem, 2023; 89(1):53–102.

31.

Caro

, Morino

, Mojzsis

, et al. Sluggish Hadean geodynamics: Evidence from coupled ^146,147Sm-^142,143Nd systematics in Eoarchean supracrustal rocks of the Inukjuak domain (Quebec. Earth Planet. Sci. Lett, 2017; 457:23–37.

32.

Cates

, Mojzsis

. Pre-3750 Ma supracrustal rocks from the Nuvvuagittuq supracrustal belt, northern Quebec. Earth Planet. Sci. Lett, 2007; 255(1–2):9–21.

33.

Catling

, Zahnle

. The Archean atmosphere. Sci Adv, 2020; 6(9):eaax1420.

34.

Cawood

, Chowdhury

, Mulder

, et al. Secular evolution of continents and the Earth system. Rev. Geophys, 2022; 60(4):e2022RG000789; doi: 10.1029/2022RG000789

35.

Cawood

, Hawkesworth

, Dhuime

. The continental record and the generation of continental crust. GSA Bulletin, 2013; 125(1–2):14–32.

36.

Cawood

, Hawkesworth

, Pisarevsky

, et al. Geological archive of the onset of plate tectonics. Philos Trans A Math Phys Eng Sci, 2018; 376(2132):20170405; doi: 10.1098/rsta.2017.0405

37.

Christensen

. Convection with pressure- and temperature-dependent non-Newtonian rheology. Geophys. J. R. Astron. Soc, 1984; 77(2):343–384.

38.

Citron

, Stewart

. Large impacts onto the early Earth: Planetary sterilization and iron delivery. Planet Sci J, 2022; 3(5):116; doi: 10.3847/PSJ/ac66e8

39.

Compston

, Pidgeon

. Jack Hills, evidence of more very old detrital zircons in Western Australia. Nature, 1986; 321(6072):766–769.

40.

Condie

, Kröner

. When did plate tectonics begin? Evidence from the geologic record. In: When Did Plate Tectonics Begin on Planet Earth? ( Condie

, Pease

., eds.) Geological Society of America; 2008, pp. 281–294.

41.

Condie

, Pisarevsky

, Korenaga

, et al. Is the rate of supercontinent assembly changing with time? Precambrian Res, 2015; 259:278–289.

42.

Crowley

, O’Connell

. An analytical model of convection in a system with layered viscosity and plates. Geophys. J. Int, 2012; 188(1):61–78.

43.

Davies

. On the emergence of plate tectonics. Geol, 1992; 20(11):963–966.

44.

Davies

. Stirring geochemistry in mantle convection models with stiff plates and slabs. Geochim. Cosmochim. Acta, 2002; 66(17):3125–3142.

45.

de Niem

, Kuhrt

, Morbidelli

, et al. Atmospheric erosion and replenishment induced by impacts upon the Earth and Mars during a heavy bombardment. Icarus, 2012; 221(2):495–507.

46.

Debaille

, O’Neill

, Brandon

, et al. Stagnant-lid tectonics in early Earth revealed by ¹⁴²Nd variations in late Archean rocks. Earth Planet. Sci. Lett, 2013; 373:83–92.

47.

Deng

, Du

, Karki

, et al. A magma ocean origin to divergent redox evolutions of rocky planetary bodies and early atmospheres. Nature Comm, 2020; 11:2007; doi: 10.1038/s41467-020-15157-0

48.

DePaolo

. Crustal growth and mantle evolution: Inferences from models of element transport and Nd and Sr isotopes. Geochim. Cosmochim. Acta, 1980; 44(8):1185–1196.

49.

Dhuime

, Hawkesworth

, Cawood

, et al. A change in the geodynamics of continental growth 3 billion years ago. Science, 2012; 335(6074):1334–1336.

50.

Dhuime

, Hawkesworth

, Delavault

, et al. Continental growth seen through the sedimentary record. Sed. Geol, 2017; 357:16–32.

51.

Drabon

, Byerly

, et al. Destablization of long-lived Hadean protocrust and the onset of pervasive hydrous melting at 3.8 Ga. AGU Adv, 2022; 3:e2021AV000520; doi: 10.1029/2021AV000520

52.

Farmer

, DePaolo

. Origin of Mesozoic and Tertiary granite in the western United States and implications for the pre-Mesozoic crustal structure, 1, Nd and Sr isotopic studies in the geocline of the northern Great Basin. J Geophys Res, 1983; 88(B4):3379–3401.

53.

Farquhar

, Savarino

, Airieau

, et al. Observation of wavelength-sensitive mass-independent sulfur isotope effects during SO₂ photolysis: Implications for the early atmosphere. J Geophys Res, 2001; 106(E12):32829–32839.

54.

Ferrick

, Korenaga

. Generalizing scaling laws for mantle convection with mixed heating. JGR Solid Earth, 2023a;128(5):e2023JB026398; doi: 10.1029/2023JB026398

55.

Ferrick

, Korenaga

. Scaling laws for mixed heated convection with pseudoplastic rheology: Implications for the bistability of tectonic mode. J. Geophys. Res. Solid Earth, 2023b;128, e2023JB027869, https://do.org/10.1029/e2023JB027869

56.

Fisher

, Vervoort

. Using the magmatic record to constrain the growth of continental crust - the Eoarchean zircon Hf record of Greenland. Earth Planet. Sci. Lett, 2018; 488:79–91.

57.

Friend

CRL

, Nutman

, Bennett

, et al. Seawater-like trace element signatures (REE+Y) of Eoarchaean chemical sedimentary rocks from southern West Greenland, and their corruption during high-grade metamorphism. Contrib Mineral Petrol, 2008; 155(2):229–246.

58.

Frost

, McLaughlin

, Frost

, et al. Hadean origins of Paleoarchean continental crust in the central Wyoming Province. GSA Bulletin, 2017; 129(3–4):259–280.

59.

, Drabon

, Weiss

, et al. Statistical reanalysis of Archean zircon paleointensities: No evidence for stagnant-lid tectonics. Earth Planet. Sci. Lett, 2024; 634:118679.

60.

Gardiner

, Hickman

, Kirkland

, et al. Processes of crust formation in the early Earth imaged through Hf isotopes form the East Pilbara Terrane. Precambrian Res, 2017; 297:56–76.

61.

Gerya

, Connolly

JAD

, Yuen

. Why is terrestrial subduction one-sided? Geol, 2008; 36(1):43–46.

62.

Goodwin

. 1996. Principles of Precambrian Geology. Academic Press: London.

63.

Griessmeier

J-M

, Stadelmann

, Motschmann

, et al. Cosmic ray impact on extrasolar Earth-like planets in close-in habitable zones. Astrobiology, 2005; 5(5):587–603.

64.

Grimes

, Wooden

, Cheadle

, et al. “fingerprinting” tectono-magmatic provenance using trace elements in igneous zircon. Contrib Mineral Petrol, 2015; 170(5–6):46.

65.

Gunawardana

, Chowdhury

, Morra

, et al. Correlating mantle cooling with tectonic transitions on early Earth. Geology, 2024; 52(4):230–234.

66.

Guo

, Korenaga

. Argon constraints on the early growth of felsic continental crust. Sci Adv, 2020; 6(21):eaaz6234.

67.

Guo

, Korenaga

. A halogen budget of the bulk silicate Earth points to a history of early halogen degassing followed by net regassing. Proc Natl Acad Sci USA, 2021; 118(51):e2116083118; doi: 10.1073/pnas.2116083118

68.

Guo

, Korenaga

. The combined Hf and Nd isotope evolution of the depleted mantle requires Hadean continental formation. Sci Adv, 2023; 9(12):eade2711.

69.

Guo

, Korenaga

. Rapid rise of early ocean pH revealed under elevated weathering rates. Nature Geosci.18, 2025; doi: 10.1038/s41561-025-01649-9

70.

Halevy

, Bachan

. The geologic history of seawater pH. Science, 2017; 355(6329):1069–1071.

71.

Harrison

. On a scientific approach for deep time investigations. Persp. Earth Space Sci, 2023; 4:e2022CN000193; doi: 10.1029/2022NC000193

72.

Harrison

. We don’t know when plate tectonics began. J Geol. Soc London., 2024, in press.

73.

Harrison

. Hadean Earth. Springer: Cham, Switzerland; 2020.

74.

Harrison

, Schmitt

, McCulloch

, et al. Early (≥4.5 Ga) formation of terrestrial crust: Lu-Hf, δ¹⁸O, and Ti thermometry results for Hadean zircons. Earth Planet. Sci. Lett, 2008; 268(3–4):476–486.

75.

Hawkesworth

, Cawood

, Dhuime

. Tectonics and crustal evolution. GSAT, 2016; 26(09):4–11.

76.

Hawkesworth

, Cawood

, Dhuime

. Rates of generation and growth of the continental crust. Geosci. Frontiers, 2019; 10(1):165–173.

77.

Hawkesworth

, Cawood

, Dhuime

, et al. Earth’s continental lithosphere through time. Annu Rev Earth Planet Sci, 2017; 45(1):169–198.

78.

Hawkesworth

, Cawood

, Dhuime

, et al. Tectonic processes and the evolution of the continental crust. JGS, 2024; 181(4); doi: 10.1144/jgs2024-027

79.

Herzberg

. Understanding the Paleoproterozoic Circum-Superior Large Igneous Province constrains the thermal properties of Earth’s mantle through time. Precambrian Res, 2022; 375:106671.

80.

Herzberg

, Condie

, Korenaga

. Thermal evolution of the Earth and its petrological expression. Earth Planet. Sci. Lett, 2010; 292(1–2):79–88.

81.

Hirschmann

. Magma ocean influence on early atmosphere mass and composition. Earth Planet. Sci. Lett, 2012; 341–344:48–57.

82.

Hirth

, Kohlstedt

. Water in the oceanic mantle: Implications for rheology, melt extraction, and the evolution of the lithosphere. Earth Planet. Sci. Lett, 1996; 144(1–2):93–108.

83.

Hopkins

, Harrison

, Manning

. Constraints on Hadean geodynamics from mineral inclusions in >4 Ga zircons. Earth Planet. Sci. Lett, 2010; 298(3–4):367–376.

84.

Iizuka

, Komiya

, Johnson

, et al. Reworking of Hadean crust in the Acasta gneisses, northwestern Canada: Evidence from in-situ Lu-Hf isotope analysis of zircon. Chem. Geol, 2009; 259(3–4):230–239.

85.

Iizuka

, Komiya

, Rino

, et al. Detrital zircon evidence for Hf isotopic evolution of granitoid crust and continental growth. Geochim. Cosmochim. Acta, 2010; 74(8):2450–2472.

86.

Iizuka

, Komiya

, Ueno

, et al. Geology and zircon geochronology of the Acasta Gneiss Complex, northwestern Canada: New constraints on its tectonothermal history. Precambrian Res, 2007; 153(3–4):179–208.

87.

Jacobsen

, Wasserburg

. The mean age of mantle and crustal reservoirs. J Geophys Res, 1979; 84(B13):7411–7427.

88.

Jarvis

, Peltier

. Mantle convection as a boundary layer phenomenon. Geophys. J. R. Astron. Soc, 1982; 68(2):389–427.

89.

Jiang

, Zou

, Mitchell

, et al. Sediment subduction in Hadean revealed by machine learning. Proc Natl Acad Sci U S A, 2024; 121(30):e2405160121; doi: 10.1073/pnas.2405160121

90.

Johnson

, Brown

, Kaus

BJP

, et al. Delamination and recycling of Archaean crust caused by gravitational instabilities. Nature Geosci, 2014; 7(1):47–52.

91.

Karato

. Deformation of Earth Materials: Introduction to the Rheology of the Solid Earth. Cambridge, New York; 2008.

92.

Karato

. Does partial melting reduce the creep strength of the upper mantle? Nature, 1986; 319(6051):309–310.

93.

Katayama

. Strength models of the terrestrial planets and implications for their lithospheric structure and evolution. Prog. Earth Planet. Sci, 2021; 8; doi: 10.1186/s40645-020-00388-2

94.

Keller

, Harrison

. Constraining crustal silica on ancient Earth. Proc Natl Acad Sci U S A, 2020; 117(35):21101–21107.

95.

Keller

, Schoene

. Plate tectonics and continental basaltic geochemistry throughout Earth history. Earth Planet. Sci. Lett, 2018; 481:290–304.

96.

Kempe

, Degens

. An early soda ocean? Chem. Geol, 1985; 53(1–2):95–108.

97.

Kemp

AIS

, Hawkesworth

. 2014. Growth and differentiation of the continental crust from isotope studies of accessory minerals. In: Treatise on Geochemistry, 2nd ed. Vol. 4. Elsevier, pp. 379–421.

98.

Kemp

AIS

, Hickman

, Kirkland

, et al. Hf isotopes in detrital and inherited zircons of the Pilbara Craton provide no evidence for Hadean continents. Precambrian Res, 2015; 261:112–126.

99.

Kemp

AIS

, Wilde

, Hawkesworth

, et al. Hadean crustal evolution revisited: New constraints from Pb-Hf isotope systematics of the Jack Hills zircons. Earth Planet. Sci. Lett, 2010; 296(1–2):45–56.

100.

Keppler

, Golabek

. Graphite floatation on a magma ocean and the fate of carbon during core formation. Geochem Persp Let, 2019; 11:12–17.

101.

Kirschvink

, Weiss

. Mars, panspermia, and the origin of life: Where did it all begin? Paleontrol. Electro, 2001; 4:8–15.

102.

Korenaga

. Energetics of mantle convection and the fate of fossil heat. Geophys. Res. Lett, 2003; 30(8):1437; doi: 10.1029/2003GL016982

103.

Korenaga

. 2006. Archean geodynamics and the thermal evolution of Earth. In: Archean Geodynamics and Environments. ( Benn

, Mareschal

J-C

, Condie

., Eds.) American Geophysical Union: Washington, DC, pp. 7–32.

104.

Korenaga

. Scaling of plate-tectonic convection with pseudoplastic rheology. J Geophys Res, 2010; 115(B11):B11405; doi: 10.1029/2010JB007670

105.

Korenaga

. Initiation and evolution of plate tectonics on Earth: Theories and observations. Annu Rev Earth Planet Sci, 2013; 41(1):117–151.

106.

Korenaga

. Pitfalls in modeling mantle convection with internal heating. JGR Solid Earth, 2017; 122(5):4064–4085; doi: 10.1002/2016JB013850

107.

Korenaga

. Crustal evolution and mantle dynamics through Earth history. Phil Trans R Soc A, 2018a;376(2132):20170408; doi: 10.1098/rsta.2017.0408

108.

Korenaga

. Estimating the formation age distribution of continental crust by unmixing zircon age data. Earth Planet. Sci. Lett, 2018b;482:388–395.

109.

Korenaga

. Plate tectonics and surface environment: Role of the oceanic upper mantle. Earth-Sci. Rev, 2020; 205:103185; doi: 10.1016/j.earscirev.2020.103185

110.

Korenaga

. Hadean geodynamics and the nature of early continental crust. Precambrian Res, 2021a;359:106178.

111.

Korenaga

. Was there land on the early Earth? Life, 2021b;11(11):1142.

112.

Korenaga

, Spencer

. 2025. An evaluation of continental growth and early Earth tectonics: Observations and models. In: Treatise on Geochemistry, 3rd ed. Vol. 2. ( Chauvel

., ed.) Elsevier, pp. 699–727.

113.

Kuwahara

, Nakada

, Kadoya

, et al. Hadean mantle oxidation inferred from melting of peridotite under lower-mantle conditions. Nat Geosci, 2023; 16(5):461–465.

114.

Lenardic

, Crowley

. On the notion of well-defined tectonic regimes for terrestrial planets in this solar system and others. ApJ, 2012; 755(2):132.

115.

Lenardic

, Crowley

, Jellinek

, et al. The solar system of forking paths: Bifurcations in planetary evolution and the search for life-bearing planets in our galaxy. Astrobiology, 2016; 16(7):551–559.

116.

Maas

, Kinny

, Williams

, et al. The Earth’s oldest known crust: A geochronological and geochemical study of 3900-4200 Ma old detrital zircons from Mt. Narryer and Jack Hills, Western Australia. Geochim. Cosmochim. Acta, 1992; 56(3):1281–1300.

117.

Macleod

, McKeown

, Hall

, et al. Hydrothermal and oceanic pH conditions of possible relevance to the origin of life. Origins Life Evol Biosphere, 1994; 24(1):19–41.

118.

Maher

, Stevenson

. Impact frustration of the origin of life. Nature, 1988; 331(6157):612–614.

119.

Marchi

, Bottke

, Elkins-Tanton

, et al. Widespread mixing and burial of Earth’s Hadean crust by asteroid impacts. Nature, 2014; 511(7511):578–582.

120.

Marchi

, Canup

, Walker

. Heterogeneous delivery of silicate and metal to the Earth by large planetesimals. Nat Geosci, 2018; 11:77–81.

121.

Marchi

, Rufu

, Korenaga

. Long-lived volcanic resurfacing of Venus driven by early collisions. Nat Astron, 2023; 7(10):1180–1187; doi: 10.1038/s41550-023-02037-2

122.

Marty

, Avice

, Bekaert

, et al. Salinity of the Archaean oceans from analysis of fluid inclusions in quartz. C. R. Geoscience, 2018; 350(4):154–163.

123.

Maurice

, Tosi

, Samuel

, et al. Onset of solid-state mantle convection and mixing during magma ocean solidification. JGR Planets, 2017; 122(3):577–598; doi: 10.1002/2016JB005250

124.

McCollom

. Miller-Urey and beyond: What have we learned about prebiotic organic synthesis reactions in the past 60 years? Annu Rev Earth Planet Sci, 2013; 41(1):207–229.

125.

McCulloch

, Bennett

. Progressive growth of the Earth’s continental crust and depleted mantle: Geochemical constraints. Geochim. Cosmochim. Acta, 1994; 58(21):4717–4738.

126.

Melosh

, Williams

. Mechanics of graben formation in crustal rocks: A finite element analysis. J Geophys Res, 1989; 94(B10):13961–13973.

127.

Mian

, Tozer

. No water, no plate tectonics: Convective heat transfer and the planetary surfaces of Venus and Earth. Terra Nova, 1990; 2(5):455–459.

128.

Miyazaki

, Korenaga

. On the timescale of magma ocean solidification and its chemical consequences: 2. compositional differentiation under crystal accumulation and matrix compaction. JGR Solid Earth, 2019; 124(4):3399–3419; doi: 10.1029/2018JB016928

129.

Miyazaki

, Korenaga

. A wet heterogeneous mantle creates a habitable world in the Hadean. Nature, 2022; 603(7899):86–90.

130.

Mojzsis

, Harrison

, Pidgeon

. Oxygen-isotope evidence from ancient zircons for liquid water at the Earth’s surface 4,300 Myr ago. Nature, 2001; 409(6817):178–181.

131.

Mondal

, Korenaga

. A propagator matrix method for the Rayleigh-Taylor instability of multiple layers: A case study on crustal delamination in the early Earth. Geophys. J. Int, 2018; 212(3):1890–1901.

132.

Moore

, Webb

AAG

. Heat-pipe Earth. Nature, 2013; 501(7468):501–505.

133.

Moresi

, Solomatov

. Mantle convection with a brittle lithosphere: Thoughts on the global tectonic styles of the Earth and Venus. Geophys J Int, 1998; 133(3):669–682.

134.

Mueller

, Wooden

. Trace element and Lu-Hf systematics in Hadean-Archean detrital zircons: Implications for crustal evolution. J. Geol, 2012; 120(1):15–29.

135.

Mulder

, Cawood

. 2025. Continental evolution from detrital mineral petrochronology. In: Treatise on Geochemistry, 3rd ed. Vol. 2. Elsevier, pp. 203–247.

136.

Nutman

, Bennett

, Friend

CRL

, et al. Fifty years of the Eoarchean and the case for evolving uniformitarianism. Precambrian Res, 2021; 367:106442.

137.

Nutman

, Friend

CRL

, Bennett

. Evidence for 3650-3600 Ma assembly of the northern end of the Itsaq Gneiss Complex, Greenland: Implication for early Archean tectonics. Tectonics, 2002; 21(1):1005; doi: 10.1029/2000TC001203

138.

Nutman

, McGregor

, Friend

CRL

, et al. The Itsaq Gneiss Complex of the southern West Greenland: The world’s most extensive record of ealry crustal evolution (3900–3600 Ma). Precambrian Res, 1996; 78(1–3):1–39.

139.

O’Neil

, Carlson

, Paquette

J-L

, et al. Formation age and metamorphic history of the Nuvvuagittuq greenstone belt. Precambrian Res, 2012; 220–221:23–44.

140.

O’Neill

, Lenardic

, Moresi

, et al. Episodic Precambrian subduction. Earth Planet. Sci. Lett, 2007; 262(3–4):552–562.

141.

O’Neill

, Lenardic

, Weller

, et al. A window for plate tectonics in terrestrial planet evolution? Phys. Earth Planet. Inter, 2016; 255:80–92.

142.

Olson

, Yuen

, Balsiger

. Convective mixing and the fine structure of mantle heterogeneity. Earth Planet. Sci. Lett, 1984; 36(3–4):291–304.

143.

Palin

, Santosh

, Cao

, et al. Secular change and the onset of plate tectonics on Earth. Earth-Sci. Rev, 2020; 207:103172.

144.

Pan

, Holloway

, Hervig

. The pressure and temperature dependence of carbon dioxide solubility in theoleiitic basalt melts. Geochim. Cosmochim. Acta, 1991; 55(6):1587–1595.

145.

Papale

. Modeling of the solubility of a one-component H₂O or CO₂ fluid in silicate liquids. Contrib. Mineral. Petrol, 1997; 126(3):237–251.

146.

Patchett

, Arndt

. Nd isotopes and tectonics of 1.9-1.7 Ga crustal genesis. Earth Planet. Sci. Lett, 1986; 78(4):329–338.

147.

Paterson

, Wong

T-F

. 2005. Experimental Rock Deformation—The Brittle Field. Springer.

148.

Petersson

, Kemp

AIS

, Hickman

, et al. A new 3.59 Ga magmatic suite and a chondritic source to the east Pilbara Craton. Chem. Geol, 2019a;511:51–70.

149.

Petersson

, Kemp

AIS

, Whitehouse

. A Yilgarn seed to the Pilbara Craton (Australia)? evidence from inherited zircons. Geology, 2019b;47(11):1098–1102.

150.

Petford

, Gallagher

. Partial melting of mafic (amphibolitic) lower crust by periodic influx of basaltic magma. Earth Planet. Sci. Lett, 2001; 193(3–4):483–499.

151.

Piccolo

, Palin

, Kaus

BJP

, et al. Generation of Earth’s early continents from a relatively cool Archean mantle. Geochem Geophys Geosyst, 2019; 20(4):1679–1697; doi: 10.1029/2018GC008079

152.

Piper

JDA

. A planetary perspective on Earth evolution: Lid tectonics before plate tectonics. Tectonophysics, 2013; 589:44–56.

153.

Planck

. Scientific Autobiography and Other Papers. Williams & Norgate: London, UK; 1950.

154.

Pujol

, Marty

, Burgess

, et al. Argon isotopic composition of Archaean atmosphere probes early Earth geodynamics. Nature, 2013; 498(7452):87–90.

155.

Puster

, Jordan

, Hager

. Characterization of mantle convection experiments using two-point correlation functions. J Geophys Res, 1995; 100(B4):6351–6365.

156.

Ramirez-Salazar

, Muller

, Piazolo

, et al. Tectonics of the Isua supracrustal belt, 1. P-T-X-d constraints on a poly-metamorphic terrane. Tectonics, 2021; 40(3):e2020TC006516; doi: 10.1029/2020TC006516

157.

Raymond

, Morbidelli

. Planet formation: Key mechanisms and global models. In: Demographics of Exoplantary Systems. ( Biazzo

, Bozza

, Mancini

, Sozzetti

., eds.) Springer; 2021, pp. 3–82.

158.

Regenauer-Lieb

, Yuen

, Branlund

. The initiation of subduction: Criticality by addition of water? Science, 2001; 294(5542):578–580.

159.

Reimink

, Davies

JHFL

, Chacko

, et al. No evidence for Hadean continental crust within Earth’s oldest evolved rock unit. Nature Geosci, 2016; 9(10):777–780.

160.

Reimink

, Davies

JHFL

, Moyen

J-F

, et al. A whole-lithosphere view of continental growth. Geochem Persp Let, 2023; 26:45–49.

161.

Reimink

, Pearson

, Shirey

, et al. Onset of new, progressive crustal growth in the central Slave craton at 3.55 Ga. Geochem Persp Let, 2019; 10:8–13.

162.

Richards

, Yang

W-S

, Baumgardner

, et al. Role of a low-viscosity zone in stabilizing plate tectonics: Implications for comparative terrestrial planetology. Geochem. Geophys. Geosys, 2001; 22000GC000115.

163.

Rizo

, Boyet

, Blichert-Toft

, et al. The elusive Hadean enriched reservoir revealed by ¹⁴²Nd deficits in Isua Archaean rocks. Nature, 2012; 491(7422):96–100.

164.

Roman

, Arndt

. Differentiated Archean oceanic crust: Its thermal structure, mechanical stability and a test of the sagduction hypothesis. Geochim. Cosmochim. Acta, 2020; 278:65–77.

165.

Rose

, Korenaga

. Mantle rheology and the scaling of bending dissipation in plate tectonics. J Geophys Res, 2011; 116(B6):B06404; doi: 10.1029/2010JB008004

166.

Roth

ASG

, Bourdon

, Mojzsis

, et al. Combined ^147,146Sm-^143,142Nd constraints on the longevity and residence time of early terrestrial crust. Geochem Geophys Geosyst, 2014; 15(6):2329–2345.

167.

Rozel

, Golabek

, Jain

, et al. Continental crust formation on early Earth controlled by intrusive magmatism. Nature, 2017; 545(7654):332–335.

168.

Russell

, Hall

. The onset and early evolution of life. In: Evolution of Early Earth’s Atmosphere, Hydrosphere, and Biosphere—Constraints from Ore Deposits. ( Kesler

, Ohmoto

., Eds.) Geological Society of America; 2006, pp. 1–32.

169.

Salerno

, Vervoort

, Fisher

, et al. The coupled Hf-Nd isotope record of the early Earth in the Pilbara Craton. Earth Planet. Sci. Lett, 2021; 572:117139.

170.

Scharf

, Cronin

. Quantifying the origins of life on a planetary scale. Proc Natl Acad Sci U S A, 2016; 113(29):8127–8132.

171.

Schlichting

, Sari

, Yalinewich

. Atmospheric mass loss during planet formation: The importance of planetesimal impacts. Icarus, 2015; 247:81–94.

172.

Schopf

, Kudryavtsev

, Czaja

, et al. Evidence of Archean life: Stromatolites and microfossils. Precambrian Res, 2007; 158(3–4):141–155.

173.

Shirey

, Richardson

. Start of the Wilson cycle at 3 Ga shown by diamonds from subcontinental mantle. Science, 2011; 333(6041):434–436.

174.

Sinclair

, Wyatt

, Morbidelli

, et al. Evolution of the Earth’s atmosphere during Late Veneer accretion. Mon. Not. R. astr. Soc, 2020; 499(4):5334–5362.

175.

Sleep

, Zahnle

. Carbon dioxide cycling and implications for climate on ancient Earth. J Geophys Res, 2001; 106(E1):1373–1399.

176.

Sleep

, Zahnle

, Kasting

, et al. Annihilation of ecosystems by large asteroid impacts on the early Earth. Nature, 1989; 342(6246):139–142.

177.

Sleep

, Zahnle

, Lupu

. Terrestrial aftermath of the Moon-forming impact. Philos Trans A Math Phys Eng Sci, 2014; 372(2024):20130172; doi: 10.1098/rsta.2013.0172

178.

Sleep

, Zahnle

, Neuhoff

. Initiation of clement surface conditions on the earliest Earth. Proc Natl Acad Sci U S A, 2001; 98(7):3666–3672.

179.

Smit

, Shirey

, Hauri

, et al. Sulfur isotopes in diamonds reveal differences in continent construction. Science, 2019; 364(6438):383–385.

180.

Solomatov

. Initiation of subduction bysmall-scale convection. J. Geophys. Res, 2004; 109:B01412; doi: 10.1029/2003JB002628

181.

Solomatov

, Moresi

L-N

. Scaling of time-dependent stagnant lid convection: Application to small-scale convection on Earth and other terrestrial planets. J Geophys Res, 2000; 105(B9):21795–21817.

182.

Sossi

, Burnham

, Badro

, et al. Redox state of Earth’s magma ocean and its Venus-like early atmosphere. Sci Adv, 2020; 6(48):eabd1387.

183.

Spencer

. Continuous continental growth as constrained by the sedimentary record. Am J Sci, 2020; 320(4):373–401.

184.

Spencer

, Cavosie

, Morrell

, et al. Disparities in oxygen isotopes of detrital and igneous zircon identify erosional bias in crustal rock record. Earth Planet. Sci. Lett, 2022; 577:117248.

185.

Stein

, Schmalzl

, Hansen

. The effect of rheological parameters on plate behavior in a self-consistent model of mantle convection. Phys. Earth Planet. Inter, 2004; 142(3–4):225–255.

186.

Stern

. The evolution of plate tectonics. Philos Trans A Math Phys Eng Sci, 2018; 376(2132):20170406; doi: 10.1098/rsta.2017.0406

187.

Stüeken

, Anderson

, Bowman

, et al. Did life originate from a global chemical reactor? Geobiology, 2013; 11(2):101–126.

188.

Tackley

. Effects of strongly variable viscosity on three-dimensional compressible convection in planetary mantles. J Geophys Res, 1996; 101(B2):3311–3332.

189.

Tackley

. 2015. Mantle geochemical geodynamics. In: Treatise on Geophysics, 2nd ed., Vol. 7. Elsevier, pp. 521–585.

190.

Tang

, Chen

, Rudnick

. Archean upper crust transition from mafic to felsic marks the onset of plate tectonics. Science, 2016; 351(6271):372–375.

191.

Tarduno

, Cottrell

, Bono

, et al. Hadaean to Palaeoarchaean stagnant-lid tectonics revealed by zircon magnetism. Nature, 2023; 618(7965):531–536.

192.

Trail

, Watson

, Tailby

. The oxidation state of Hadean magmas and implications for early Earth’s atmosphere. Nature, 2011; 480(7375):79–82.

193.

van Hunen

, Moyen

J-F

. Archean subduction: Fact or fiction? Annu Rev Earth Planet Sci, 2012; 40(1):195–219.

194.

van Hunen

, van den Berg

. Plate tectonics on the early Earth: Limitations imposed by strength and buoyancy of subducted lithosphere. Lithos, 2008; 103(1–2):217–235.

195.

Van Kranendonk

, Djokic

, Poole

, et al. 2019. Depositional setting of the fossiliferous, c.3480 Ma Dresser Formation, Pilbara Craton: A review. In: Earth’s Oldest Rocks, 2nd ed. ( Van Kranendonk

, Bennett

, Hoffmann

, eds.) Elsevier, pp. 985–1006.

196.

Van Kranendonk

, Smithies

, Hickman

, et al. Review: Secular tectonic evolution of Archean continental crust: Interplay between horizontal and vertical processes in the formation of the Pilbara Craton, Australia. Terra Nova, 2007; 19(1):1–38.

197.

Webb

AAG

, Muller

, Zuo

, et al. A non-plate tectonic model for the Eoarchean Isuä supracrustal belt. Lithosphere, 2020; 12(1):166–179.

198.

Weller

, Lenardic

. Hysteresis in mantle convection: Plate tectonics systems. Geophys. Res. Lett, 2012; 39(10):L10202; doi: 10.1029/2012GL051232

199.

Weller

, Lenardic

, O’Neill

. The effects of internal heating and large scale climate variations on tectonic bistability in terrestrial planets. Earth Planet. Sci. Lett, 2015; 420:85–94.

200.

Windley

, Kusky

, Polat

. Onset of plate tectonics by the Eoarchean. Precambrian Res, 2021; 352:105980; doi: 10.1016/j.precamres.2020.105980

201.

Zahnle

, Arndt

, Cockell

, et al. Emergence of a habitable planet. Space Sci Rev, 2007; 129(1–3):35–78.

202.

Zahnle

, Lupu

, Catling

, et al. Creation and evolution of impact-generated reduced atmospheres of early Earth. Planet Sci J, 2020; 1(1):11; doi: 10.3847/PSJ/ab7e2cs

203.

Zhong

, Gurnis

. Dynamic feedback between a continentlike raft and thermal convection. J Geophys Res, 1993; 98(B7):12219–12232.

204.

Zhu

, Campbell

, Allen

, et al. Evolution of the preserved European continental crust, constrained by U-Pb, O and Hf isotopic analyses of river detrital zircons. Geochim. Cosmochim. Acta, 2023; 346:133–148.

205.

Zuo

, Webb

AAG

, Piazolo

, et al. Tectonics of the Isua supracrustal belt, 2. microstructures reveal distributed strain in the absense of major fault structures. Tectonics, 2021; 40(3):e2020TC006514; doi: 10.1029/2020TC006514.9