A Revised Estimate of Early Pliocene Global Mean Sea Level Using Geodynamic Models of the Patagonian Slab Window

Paleoshorelines serve as measures of ancient sea level and ice volume but are affected by solid Earth deformation including processes such as glacial isostatic adjustment (GIA) and mantle dynamic topography (DT). The early Pliocene Epoch is an important target for sea‐level reconstructions as it con...

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Published in:Geochemistry, geophysics, geosystems : G3 geophysics, geosystems : G3, 2023-02, Vol.24 (2), p.n/a
Main Authors: Hollyday, Andrew, Austermann, Jacqueline, Lloyd, Andrew, Hoggard, Mark, Richards, Fred, Rovere, Alessio
Format: Article
Language:English
Subjects:
Asthenosphere
Buoyancy
Climate
Convection
Deformation
Downwelling
Dynamic topography
Earth
geodynamics
glacial isostatic adjustment
Glaciation
Ice
Ice effects
Ice sheet models
Ice sheets
Ice volume
Mantle convection
Mean sea level
Modelling
Ocean circulation
Paleoshorelines
Passive margins
Patagonia
Pliocene
Sea level
Sea level measurements
sea‐level change
Shorelines
Tomography
Topography
Transition zone
Upwelling
Viscosity
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Summary:Paleoshorelines serve as measures of ancient sea level and ice volume but are affected by solid Earth deformation including processes such as glacial isostatic adjustment (GIA) and mantle dynamic topography (DT). The early Pliocene Epoch is an important target for sea‐level reconstructions as it contains information about the stability of ice sheets during a climate warmer than today. Along the southeastern passive margin of Argentina, three paleoshorelines date to early Pliocene times (4.8–5.5 Ma), and their variable present‐day elevations (36–180 m) reflect a unique topographic deformation signature. We use a mantle convection model to back‐advect present‐day buoyancy variations, including those that correspond to the Patagonian slab window. Varying the viscosity and initial tomography‐derived mantle buoyancy structures allows us to compute a suite of predictions of DT change that, when compared to GIA‐corrected shoreline elevations, makes it possible to identify both the most likely convection parameters and the most likely DT change. Our simulations illuminate an interplay of upwelling asthenosphere through the Patagonian slab window and coincident downwelling of the subducted Nazca slab in the mantle transition zone. This flow leads to differential upwarping of the southern Patagonian foreland since early Pliocene times, in line with the observations. Using our most likely DT change leads to an estimate of global mean sea level of 17.5 ± 6.4 m (1σ) in the early Pliocene Epoch. This confirms that sea level was significantly higher than present and can be used to calibrate ice sheet models. Plain Language Summary Understanding the height of global mean sea level (GMSL) during the early Pliocene Epoch, when Earth's climate was warmer than today, will help to improve predictive models of current sea‐level rise. In eastern Patagonia, shorelines that formed during this time period have been uplifted due to convective flow in the mantle beneath southern South America. We model both mantle flow and the effects of ice sheet loading changes, which also cause Earth's topography to evolve through time, to correct the present‐day elevations of these shorelines. After subtracting out the effects of solid Earth deformation, we calculate a GMSL of 17.5 ± 6.4 m (1σ) in the early Pliocene Epoch. Key Points Mantle flow through the Patagonian slab window, coupled with slab ponding in the mantle transition zone, has uplifted eastern Patagonia since 5 Ma Accounting for the
ISSN:1525-2027
1525-2027
DOI:10.1029/2022GC010648