TY - JOUR
T1 - Secular Evolution of Continents and the Earth System
AU - Cawood, Peter A.
AU - Chowdhury, Priyadarshi
AU - Mulder, Jacob A.
AU - Hawkesworth, Chris J.
AU - Capitanio, Fabio A.
AU - Gunawardana, Prasanna M.
AU - Nebel, Oliver
N1 - Funding Information:
The authors acknowledge support from the Australian Research Council Grant FL160100168, and thank editor Valerio Acocella, and reviewers Taras Gerya, Tim Johnson, and Ming Tang for their constructive feedback. Our knowledge of the early history of the Earth has benefitted from discussions with Bruno Dhuime, Jeff Moyen, and Hugh Smithies and for modern continental crust with Di‐Cheng Zhu. Open access publishing facilitated by Monash University, as part of the Wiley ‐ Monash University agreement via the Council of Australian University Librarians.
Funding Information:
The authors acknowledge support from the Australian Research Council Grant FL160100168, and thank editor Valerio Acocella, and reviewers Taras Gerya, Tim Johnson, and Ming Tang for their constructive feedback. Our knowledge of the early history of the Earth has benefitted from discussions with Bruno Dhuime, Jeff Moyen, and Hugh Smithies and for modern continental crust with Di-Cheng Zhu. Open access publishing facilitated by Monash University, as part of the Wiley - Monash University agreement via the Council of Australian University Librarians.
Publisher Copyright:
© 2022. The Authors.
PY - 2022/12
Y1 - 2022/12
N2 - Understanding of secular evolution of the Earth system is based largely on the rock and mineral archive preserved in the continental lithosphere. Based on the frequency and range of accessible data preserved in this record, we divide the secular evolution into seven phases: (a) “Proto-Earth” (ca. 4.57–4.45 Ga); (b) “Primordial Earth” (ca. 4.45–3.80 Ga); (c) “Primitive Earth” (ca. 3.8–3.2 Ga); (d) “Juvenile Earth” (ca. 3.2–2.5 Ga); (e) “Youthful Earth” (ca. 2.5–1.8 Ga); (f) “Middle Earth” (ca. 1.8–0.8 Ga); and (g) “Contemporary Earth” (since ca. 0.8 Ga). Integrating this record with knowledge of secular cooling of the mantle and lithospheric rheology constrains the changes in the tectonic modes that operated through Earth history. Initial accretion and the Moon forming impact during the Proto-Earth phase likely resulted in a magma ocean. The solidification of this magma ocean produced the Primordial Earth lithosphere, which preserves evidence for intra-lithospheric reworking of a rigid lid, but which also likely experienced partial recycling through mantle overturn and meteorite impacts. Evidence for craton formation and stabilization from ca. 3.8 to 2.5 Ga, during the Primitive and Juvenile Earth phases, likely reflects some degree of coupling between the convecting mantle and a lithosphere initially weak enough to favor an internally deformable, squishy-lid behavior, which led to a transition to more rigid, plate like, behavior by the end of the early Earth phases. The Youthful to Contemporary phases of Earth, all occurred within a plate tectonic framework with changes between phases linked to lithospheric behavior and the supercontinent cycle.
AB - Understanding of secular evolution of the Earth system is based largely on the rock and mineral archive preserved in the continental lithosphere. Based on the frequency and range of accessible data preserved in this record, we divide the secular evolution into seven phases: (a) “Proto-Earth” (ca. 4.57–4.45 Ga); (b) “Primordial Earth” (ca. 4.45–3.80 Ga); (c) “Primitive Earth” (ca. 3.8–3.2 Ga); (d) “Juvenile Earth” (ca. 3.2–2.5 Ga); (e) “Youthful Earth” (ca. 2.5–1.8 Ga); (f) “Middle Earth” (ca. 1.8–0.8 Ga); and (g) “Contemporary Earth” (since ca. 0.8 Ga). Integrating this record with knowledge of secular cooling of the mantle and lithospheric rheology constrains the changes in the tectonic modes that operated through Earth history. Initial accretion and the Moon forming impact during the Proto-Earth phase likely resulted in a magma ocean. The solidification of this magma ocean produced the Primordial Earth lithosphere, which preserves evidence for intra-lithospheric reworking of a rigid lid, but which also likely experienced partial recycling through mantle overturn and meteorite impacts. Evidence for craton formation and stabilization from ca. 3.8 to 2.5 Ga, during the Primitive and Juvenile Earth phases, likely reflects some degree of coupling between the convecting mantle and a lithosphere initially weak enough to favor an internally deformable, squishy-lid behavior, which led to a transition to more rigid, plate like, behavior by the end of the early Earth phases. The Youthful to Contemporary phases of Earth, all occurred within a plate tectonic framework with changes between phases linked to lithospheric behavior and the supercontinent cycle.
KW - continental lithosphere
KW - plate tectonics
KW - secular evolution
KW - squishy lid
KW - tectonic mode
UR - http://www.scopus.com/inward/record.url?scp=85144080859&partnerID=8YFLogxK
U2 - 10.1029/2022RG000789
DO - 10.1029/2022RG000789
M3 - Review Article
AN - SCOPUS:85144080859
SN - 8755-1209
VL - 60
JO - Reviews of Geophysics
JF - Reviews of Geophysics
IS - 4
M1 - e2022RG000789
ER -