TY - JOUR
T1 - Early Earth “subduction”
T2 - short-lived, off-craton, shuffle tectonics, and no plate boundaries
AU - Nebel, O.
AU - Vandenburg, E. D.
AU - Capitanio, F. A.
AU - Smithies, R. H.
AU - Mulder, J.
AU - Cawood, P. A.
N1 - Funding Information:
Many of the aspects outlined here have been part of discussions over the years with many colleagues, but there are too many to be named here. Some agreed, and others did not, which is the nature of scientific research in areas of unknowns and discovery. As such, we wish to highlight here that many concepts and statements are part of our interpretation of data, and we do acknowledge that some aspects may be interpreted differently. We also need to stress that literature citations for such a complex matter are rarely complete, and we are aware that ours is certainly not. Any oversight is not deliberate. We thank Hugh Rollinson and an anonymous reviewer for their constructive feedback that improved the quality of this manuscript and Victoria Pease for editorial handling. ON thanks the Melbourne TIEF team for their continuous support. PAC acknowledges support from Australian Research Council grant FL160100168. RHS publishes with the permission of the Executive Director of the Geological Survey of Western Australia.
Funding Information:
Many of the aspects outlined here have been part of discussions over the years with many colleagues, but there are too many to be named here. Some agreed, and others did not, which is the nature of scientific research in areas of unknowns and discovery. As such, we wish to highlight here that many concepts and statements are part of our interpretation of data, and we do acknowledge that some aspects may be interpreted differently. We also need to stress that literature citations for such a complex matter are rarely complete, and we are aware that ours is certainly not. Any oversight is not deliberate. We thank Hugh Rollinson and an anonymous reviewer for their constructive feedback that improved the quality of this manuscript and Victoria Pease for editorial handling. PAC acknowledges support from Australian Research Council grant FL160100168 . RHS publishes with the permission of the Executive Director of the Geological Survey of Western Australia .
Publisher Copyright:
© 2024
PY - 2024/7/15
Y1 - 2024/7/15
N2 - Subduction is a key geodynamic feature on modern Earth that drives crustal chemical diversity, bridging the atmo-, hydro-, and lithosphere, but remains an enigmatic, unique planetary feature. Indisputable is the critical role of subduction in shaping Earth's geomorphology and crustal dichotomy (ocean vs continental crust) and its impacts on long-term climate, making it arguably the most important process on present-day Earth across all geosciences. It is thus important to understand to what degree, or if at all, subduction was operational during the billions of years that led to our geological status quo. Here, we assess the feasibility of Archean subduction with a focus on early Earth geodynamics. We argue that convection-driven rifting, but not spreading, formed the first keels under the primordial crust, providing the necessary stability for crustal survival. These sections of crustal rejuvenation would counterintuitively forge the first stable proto-cratonic terranes, which later evolved into cratons. Hydrated upper crustal rocks were vital in generating early fluxed mantle melting and related volcanism, but also for partial melting in hydrated lower crustal sections within proto-cratons, giving rise to tonalite-trondhjemite granodiorites (TTGs). Both processes operated off- and on-craton, respectively, and required melting of hydrated crust and crustal convergence but are unrelated. Away from proto-cratonic regions of minor episodic divergence and rifting, relative motions were accommodated by convergence and shuffle tectonics, leading to Archean-style subduction in localised regions that were prone to destruction. This primitive form of subduction and crustal maturation has operated from the earliest Archean time in a plate-and-lid regime. Crucially, this ‘Archean subduction’ represents short-lived crustal shuffle-tectonics outside areas of today's cratons with fluxed melting in upper mantle regions but does not resemble present-day Benioff-style subduction. The development of subduction akin to present-day processes towards the end of the Archean could plausibly have driven atmospheric oxygenation over a few hundred million years between ca. 2.8–2.3 Ga, with H-loss to space accompanied by atmospheric oxidation through subduction-related global volcanic SO2 emissions.
AB - Subduction is a key geodynamic feature on modern Earth that drives crustal chemical diversity, bridging the atmo-, hydro-, and lithosphere, but remains an enigmatic, unique planetary feature. Indisputable is the critical role of subduction in shaping Earth's geomorphology and crustal dichotomy (ocean vs continental crust) and its impacts on long-term climate, making it arguably the most important process on present-day Earth across all geosciences. It is thus important to understand to what degree, or if at all, subduction was operational during the billions of years that led to our geological status quo. Here, we assess the feasibility of Archean subduction with a focus on early Earth geodynamics. We argue that convection-driven rifting, but not spreading, formed the first keels under the primordial crust, providing the necessary stability for crustal survival. These sections of crustal rejuvenation would counterintuitively forge the first stable proto-cratonic terranes, which later evolved into cratons. Hydrated upper crustal rocks were vital in generating early fluxed mantle melting and related volcanism, but also for partial melting in hydrated lower crustal sections within proto-cratons, giving rise to tonalite-trondhjemite granodiorites (TTGs). Both processes operated off- and on-craton, respectively, and required melting of hydrated crust and crustal convergence but are unrelated. Away from proto-cratonic regions of minor episodic divergence and rifting, relative motions were accommodated by convergence and shuffle tectonics, leading to Archean-style subduction in localised regions that were prone to destruction. This primitive form of subduction and crustal maturation has operated from the earliest Archean time in a plate-and-lid regime. Crucially, this ‘Archean subduction’ represents short-lived crustal shuffle-tectonics outside areas of today's cratons with fluxed melting in upper mantle regions but does not resemble present-day Benioff-style subduction. The development of subduction akin to present-day processes towards the end of the Archean could plausibly have driven atmospheric oxygenation over a few hundred million years between ca. 2.8–2.3 Ga, with H-loss to space accompanied by atmospheric oxidation through subduction-related global volcanic SO2 emissions.
KW - Archean Subduction
KW - Craton
KW - Cratonic Lithosphere
KW - Geodynamic regimes
UR - http://www.scopus.com/inward/record.url?scp=85193499165&partnerID=8YFLogxK
U2 - 10.1016/j.precamres.2024.107431
DO - 10.1016/j.precamres.2024.107431
M3 - Article
AN - SCOPUS:85193499165
SN - 0301-9268
VL - 408
JO - Precambrian Research
JF - Precambrian Research
M1 - 107431
ER -