Oceanic residual depth measurements, the plate cooling model, and global dynamic topography

Hoggard, Mark; Winterbourne, J.; Czarnota, K.; White, Nicky

doi:10.1002/2016jb013457

Cited by 118 publications

(325 citation statements)

References 522 publications

(203 reference statements)

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“…Anomalies calculated using our optimal plate model are symmetric about zero irrespective of plate age with negligible skewness and a standard deviation of ±0.65 km (Figure c). In this case, the pattern, amplitude and wavelength of residual depth anomalies is similar to those determined by Hoggard et al ().…”

Section: Discussionsupporting

confidence: 89%

“…Oceanic age‐depth database. (a) Map showing global distribution of 2,028 water‐loaded depths to oceanic basement from Hoggard et al (); circles = data with both sedimentary and crustal corrections; upward/downward pointing triangles = lower/upper estimates of depth for which only sedimentary corrections are applied; yellow lines offshore northwest Africa and offshore east India = location of example seismic reflection profiles shown in (b) and (c), respectively; light/dark gray background shading = young/old oceanic plate age. (b) Seismic reflection profile offshore Guinea‐Bissau, northwest Africa, courtesy of Spectrum Geo.…”

Section: Observational Databasesmentioning

confidence: 99%

“…Thermal models that predict the development of oceanic lithosphere must be consistent with independent constraints on axial temperature structure derived from either the thickness of oceanic crust or the geochemistry of mid‐ocean ridge basalts (McKenzie et al, ). Global compilations of marine seismic experiments yield an average crustal thickness of 6.9 ± 2.2 km (Hoggard et al, ; White et al, ). Within our melting parameterization, this range of thickness is produced when the potential temperature is 1331 ± 35°C.…”

Section: Modeling Strategymentioning

confidence: 99%

See 2 more Smart Citations

Reassessing the Thermal Structure of Oceanic Lithosphere With Revised Global Inventories of Basement Depths and Heat Flow Measurements

Richards

Hoggard

Cowton³

et al. 2018

JGR Solid Earth

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154

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Half‐space cooling and plate models of varying complexity have been proposed to account for changes in basement depth and heat flow as a function of lithospheric age in the oceanic realm. Here, we revisit this well‐known problem by exploiting a revised and augmented database of 2,028 measurements of depth to oceanic basement, corrected for sedimentary loading and variable crustal thickness, and 3,597 corrected heat flow measurements. Joint inverse modeling of both databases shows that the half‐space cooling model yields a mid‐oceanic axial temperature that is >100°C hotter than permitted by petrologic constraints. It also fails to produce the observed flattening at old ages. Then, we investigate a suite of increasingly complex plate models and conclude that the optimal model requires incorporation of experimentally determined temperature‐ and pressure‐dependent conductivity, expansivity, and specific heat capacity, as well as a low‐conductivity crustal layer. This revised model has a mantle potential temperature of 1300 ± 50°C, which honors independent geochemical constraints and has an initial ridge depth of 2.6 ± 0.3 km with a plate thickness of 135 ± 30 km. It predicts that the maximum depth of intraplate earthquakes is bounded by the 700°C isothermal contour, consistent with laboratory creep experiments on olivine aggregates. Estimates of the lithosphere‐asthenosphere boundary derived from studies of azimuthal anisotropy coincide with the 1175 ± 50°C isotherm. The model can be used to isolate residual depth and gravity anomalies generated by flexural and sub‐plate convective processes.

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Section: Discussionsupporting

confidence: 89%

Section: Observational Databasesmentioning

confidence: 99%

Section: Modeling Strategymentioning

confidence: 99%

See 1 more Smart Citation

Reassessing the Thermal Structure of Oceanic Lithosphere With Revised Global Inventories of Basement Depths and Heat Flow Measurements

Richards

Hoggard

Cowton³

et al. 2018

JGR Solid Earth

Self Cite

154

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“…These processes produce dynamic topography over a range of spatial scales that cannot yet be taken into account in 3-D global models because of computational limitations. The discrepancy between numerical models of dynamic topography and observation-derived present-day dynamic topography remains debated (e.g., Hoggard et al, 2017Hoggard et al, , 2016Molnar et al, 2015;Steinberger et al, 2017;Watkins & Conrad, 2018;Yang & Gurnis, 2016;Yang et al, 2017). The dynamic topography spectra that we obtained (Figure 7) are comparable to those derived by recent inversions of present-day mantle structures (Yang & Gurnis, 2016) to simultaneously fit the long-wavelength geoid, free-air gravity anomalies, gravity gradients, and residual topography point data (Hoggard et al, 2016), and of a high-resolution upper mantle tomography model (Steinberger et al, 2017).…”

Section: Spatial and Temporal Influence Of Dynamic Topography On Surfmentioning

confidence: 99%

“…Our models predict significant intermediate to small scales of dynamic topography, with a spectral distribution similar to the global residual topography spectrum of Hoggard et al (2016) at spherical harmonic degrees larger than 5 (Figure 7). Indeed, Hoggard et al, (2016Hoggard et al, ( , 2017 proposed from models of residual topography based on seismic profiles in the oceanic realm and free-air gravity anomalies in the continental domain that large-scale dynamic topography has an amplitude of ±300 m at most. Nevertheless, we note a significant discrepancy at low spherical harmonic degrees (1-4) between global model dynamic topography spectra, including ours, and the residual topography spectrum of Hoggard et al (2016), for which power is 10 times lower (Figure 7).…”

Section: Spatial and Temporal Influence Of Dynamic Topography On Surfmentioning

confidence: 99%

On the Scales of Dynamic Topography in Whole‐Mantle Convection Models

Arnould

Coltice

Flament

et al. 2018

Geochem Geophys Geosyst

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Mantle convection shapes Earth's surface by generating dynamic topography. Observational constraints and regional convection models suggest that surface topography could be sensitive to mantle flow for wavelengths as short as 1,000 and 250 km, respectively. At these spatial scales, surface processes including sedimentation and relative sea‐level change occur on million‐year timescales. However, time‐dependent global mantle flow models do not predict small‐scale dynamic topography yet. Here we present 2‐D spherical annulus numerical models of mantle convection with large radial and lateral viscosity contrasts. We first identify the range of Rayleigh number, internal heat production rate and yield stress for which models generate plate‐like behavior, surface heat flow, surface velocities, and topography distribution comparable to Earth's. These models produce both whole‐mantle convection and small‐scale convection in the upper mantle, which results in small‐scale (<500 km) to large‐scale (>104 km) dynamic topography, with a spectral power for intermediate scales (500 to 104 km) comparable to estimates of present‐day residual topography. Timescales of convection and the associated dynamic topography vary from five to several hundreds of millions of years. For a Rayleigh number of 107, we investigate how lithosphere yield stress variations (10–50 MPa) and the presence of deep thermochemical heterogeneities favor small‐scale (200–500 km) and intermediate‐scale (500–104 km) dynamic topography by controlling the formation of small‐scale convection and the number and distribution of subduction zones, respectively. The interplay between mantle convection and lithosphere dynamics generates a complex spatial and temporal pattern of dynamic topography consistent with constraints for Earth.

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Spatial and temporal uplift history of South America from calibrated drainage analysis

Tribaldos

White

Hoggard

2017

Geochem Geophys Geosyst

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A multidisciplinary approach is used to analyze the Cenozoic uplift history of South America. Residual depth anomalies of oceanic crust abutting this continent help to determine the pattern of present‐day dynamic topography. Admittance analysis and crustal thickness measurements indicate that the elastic thickness of the Borborema and Altiplano regions is ≤10 km with evidence for sub‐plate support at longer wavelengths. A drainage inventory of 1827 river profiles is assembled and used to investigate landscape development. Linear inverse modeling enables river profiles to be fitted as a function of the spatial and temporal history of regional uplift. Erosional parameters are calibrated using observations from the Borborema Plateau and tested against continent‐wide stratigraphic and thermochronologic constraints. Our results predict that two phases of regional uplift of the Altiplano plateau occurred in Neogene times. Regional uplift of the southern Patagonian Andes also appears to have occurred in Early Miocene times. The consistency between observed and predicted histories for the Borborema, Altiplano, and Patagonian plateaux implies that drainage networks record coherent signals that are amenable to simple modeling strategies. Finally, the predicted pattern of incision across the Amazon catchment constrains solid sedimentary flux at the Foz do Amazonas. Observed and calculated flux estimates match, suggesting that erosion and deposition were triggered by regional Andean uplift during Miocene times.

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Oceanic residual depth measurements, the plate cooling model, and global dynamic topography

Cited by 118 publications

References 522 publications

Reassessing the Thermal Structure of Oceanic Lithosphere With Revised Global Inventories of Basement Depths and Heat Flow Measurements

Reassessing the Thermal Structure of Oceanic Lithosphere With Revised Global Inventories of Basement Depths and Heat Flow Measurements

On the Scales of Dynamic Topography in Whole‐Mantle Convection Models

Spatial and temporal uplift history of South America from calibrated drainage analysis

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