Abstract
Continental rifting does not always follow a straight line. Nevertheless, little attention has been given to the influence of rifting curvature in the evolution of extended margins. Here, using a three-dimensional model to simulate mantle dynamics, we demonstrate that the curvature of rifting along a margin also controls post-rift basin subsidence. Our results indicate that a concave-oceanward margin subsides faster than a convex margin does during the post-rift phase. This dynamic subsidence of curved margins is a result of lateral thermal conduction and mantle convection. Furthermore, the differential subsidence is strongly dependent on the viscosity structure. As a natural example, we analyse the post-rift stratigraphic evolution of the Santos Basin, southeastern Brazil. The differential dynamic subsidence of this margin is only possible if the viscosity of the upper mantle is >2–3 × 1019 Pa s.
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Introduction
The post-rift tectonic subsidence of divergent margins is mainly explained by the thermal contraction of a thinned lithosphere and its isostatic response to cooling due to vertical heat flow1,2 in a one-dimensional model. Although lithospheric cooling is mainly guided by this vertical heat flow through the margin, two-dimensional (2D) numerical models3,4,5 show that lateral thermal conduction has an important role in controlling the rate of subsidence. For the same amount of lithospheric stretching, a 2D model predicts faster subsidence than a one-dimensional model does4. A 2D model depends on the horizontal temperature gradient, which is a function of lateral variations in lithospheric thickness.
Another important process that controls subsidence of the margin is mantle advection beneath the lithosphere6,7, which is also a function of mantle viscosity. Lateral variations in lithospheric thickness across the margin induce small-scale convection8, which increases heat transfer to the thinned lithosphere and adjacent areas9. One consequence of this process is a transient uplift of the flanks of the rift and a decrease in the subsidence rate of the adjacent stretched lithosphere10. In this case, the isostatic effect of the additional heat introduced into the stretched lithosphere due to the small-scale mantle convection acts against the subsidence caused by vertical and lateral heat conduction. Therefore, the cumulative subsidence depends on the competing effects of conductive and advective heat transport within the margin.
Although previous 2D models of continental margin subsidence have shown the importance of incorporating a horizontal dimension and convective processes into the study of subsidence, little attention has been given to the influence of the assumed planar shape of the rifting, with a few exceptions11,12. Several portions of divergent marginal basins around the world have curved segments, and 2D models may not adequately describe their subsidence histories. Examples include the southeastern Brazilian margin and its conjugate, the western African margin.
To study the thermal evolution of a stretched margin following rifting, we used the three-dimensional (3D) finite element code CitcomCU13,14 to simulate convection in the upper 660 km of the Earth. Using different numerical simulations, we observe that the subsidence pattern of a curved margin is sensitive to the viscosity structure of the upper mantle. For a viscous upper mantle, the subsidence is mainly guided by the thermal conduction, which is more efficient in the concave segment of the margin than in the convex one. Therefore, a differential subsidence is expected along a curved margin. For a less-viscous upper mantle, the influence of advection in the thermal structure of the mantle becomes increasingly important and reduces the differential subsidence promoted by the thermal conduction. These concepts are applied to study the evolution of the southeastern Brazilian margin.
Results
Differential subsidence and upper mantle viscosity
In our numerical simulations, we assumed a temperature- and pressure-dependent Newtonian rheology, with the viscosity η given by the Arrhenius law:
where E and V are the (non-dimensional) activation energy and volume, respectively, z is depth, D is the thickness of the model, T is temperature, ΔT is the decrease in temperature from the base of the model to the surface, T0=0.21 is a non-dimensional constant and η0=η(D,ΔT) is the viscosity at the base of the model. The temperature profile is linear with depth to the base of the lithosphere, and the lithospheric stretching factor2 β varies from 1 to 3 (Fig. 1a). This implies that the thickness of the thinned lithosphere is 1/β of its original thickness. In plan view, the transition from the continent to the stretched margin is curved and contains a concave-oceanward segment and a convex segment (Fig. 1b). Additional information is found in the Methods section. We analysed the subsidence in three locations of the margin with β=3: location A is in the concave segment, location C is in the convex segment and location B is between locations A and C.
In the first simulation, for a mantle with η0=5 × 1020 Pa s, E=30 and V=0 (Fig. 2a, first column), the rate of subsidence decreases from the concave segment towards the convex segment (from A to C), and the difference in subsidence between locations C and A increases over time, reaching >250 m during the post-rift evolution of the margin when assuming a water-filled basin (Fig. 2a, third column). This result implies that the subsidence is faster in the concave segment than in the convex segment during the post-rift phase, generating more space to accommodate the sediments in the concave segment. The load of the sediments filling this accommodation space triples the differential subsidence caused only by the water load. Despite the fact that the lithosphere has the same stretching factor at the three locations along the margin, the subsidence histories of these sites are distinct due to more efficient cooling of the stretched lithosphere through lateral conduction in the concave segment. In addition, the small-scale convection induced beneath the stretched lithosphere is more vigorous in the concave segment than for any other geometrical configuration, with advection beneath location A that is up to 70% faster than that under location C (Fig. 2a, second column). Consequently, the heating of the margin by advection is more efficient at A than at C, reducing the difference in subsidence along the margin. However, because of the relatively high viscosity of the mantle in this case, the advection is slow (Fig. 2a, second column), and the thermal evolution of the model is mainly guided by heat conduction.
Regardless of the location along the margin, the stretched lithosphere closer to the continent subsides faster than that farther from the continent. This more rapid subsidence persists over time during the evolution of the margin (Supplementary Figs S1–S5).
In the following simulations, we consider a less-viscous mantle (Fig. 2b–d, first column), which causes small-scale convection to be more vigorous and advective heating to be more efficient. As in the first simulation, the advection under the concave segment is more vigorous than that under the convex segment (Fig. 2b–d, second column). The influence of advective heat under the stretched margin with a lower-viscosity mantle reduces the differential subsidence along the margin promoted by lateral thermal conduction, resulting in 100–150 m of differential subsidence between locations A and C during the post-rift evolution of the margin (Fig. 2b–d, third column) for a water-filled basin.
The interaction of small-scale mantle convection with the lithosphere also produces oscillations in subsidence along the margin over periods of a few millions of years (Myr), with a peak-to-peak amplitude of a few metres to tens of metres. These oscillations are in addition to the increasing differential subsidence along the margin (Fig. 2b–d, third column) and can be associated with the development of stratigraphic sequences15. The combined effect of small-scale mantle convection and thermal conduction in the 3D model predicts another important phenomenon: the modelled rate of relative subsidence along the margin does not reach its maximum in the initial stage of the process and decrease with time; instead, its maximum occurs after ~15–20 Myr (Fig. 2b–d, third column). This result indicates that the post-rift differential subsidence along the margin may originate up to many millions of years after the end of the rifting phase. In addition, >70% of the differential subsidence occur during the first 50 Myr. Therefore, most of the differential subsidence occur ~15–50 Myr after the beginning of the simulation for models (Fig. 2b–d).
For a less-viscous upper mantle with η<2–3 × 1019 Pa s under the stretched margin (Fig. 2e, first column), the subsidence of the margin does not depend on its position along the curved margin. Only oscillations related to the small-scale convection with amplitudes <100 m are observed (Fig. 2e, third column). In this case, lateral heat conduction is overcome by vigorous advection (Fig. 2e, second column; Supplementary Fig. S6). Therefore, the differential subsidence along the margin is strongly dependent on the viscosity of the upper mantle (Fig. 3).
The influence of the lithospheric flexural rigidity
To evaluate how the differential subsidence along a curved margin is affected when we account for the flexural rigidity of the lithosphere, we assume that a thin elastic plate represents the flexural behaviour of the lithosphere. In this case, the vertical deflection w of the lithosphere due to the vertical load q is given by the following equation:
where
EY is Young’s modulus, Te is the effective elastic thickness, ν is Poisson’s ratio, and ρm and ρw are mantle and water density, respectively. Assuming a constant flexural rigidity D, we use a spectral method to determine the vertical deflection of the thin elastic plate16. We calculate the flexural response of the lithosphere for the models in Fig. 2a–e at t=70 Myr, with Te ranging from 0 to 39 km. Other constants of the model are EY=1011 Pa and ν=0.25. The vertical displacements of locations A and C relative to B are shown in Supplementary Fig. S7.
For the models in Fig. 2a–d where the differential subsidence was observed, the magnitude of the vertical deflection of the plate between the three locations does not change significantly for Te<15–20 km. Therefore, the flexural rigidity of the lithosphere also influences the magnitude of the differential subsidence, but this is only significant when the effective elastic thickness Te is large (Te>15–20 km) because the viscous lithosphere naturally filters out short-wavelength stresses applied to its base17. In addition, the increase in flexural rigidity does not necessarily smooth differential subsidence, but it may eventually amplify differential subsidence due to the curved geometry of the margin18,12.
Discussion
To apply this 3D model to a curved margin, we analysed the stratigraphic evolution of the Santos Basin offshore of southeastern Brazil. This sedimentary basin originated in a stretched lithosphere with a geometrical configuration similar to that used in our numerical model (Fig. 4). The southwestern portion of the basin lies on a concave-oceanward segment of the margin, whereas the northeastern portion is similar to a convex segment, with an estimated mean β2.9 (ref. 19). The sedimentation in the Santos Basin has varied substantially along the margin over time (section in Fig. 4), and the depocentre migrated northeastward during the Cenomanian to Maastrichtian20 (depositional sequences III–VII in Fig. 4). In particular, the Cenomanian-lower Turonian sedimentation was initiated nearly 23 Myr after the end of rifting and is limited by the Cenomanian and the intra-Turonian unconformities21. This sedimentation occurred mainly in the southwestern portion of the basin, with a present-day mean thickness of ~400–600 m (Fig. 4, III). The asymmetric sedimentation continued with lower magnitude in the upper Turonian-lower Santonian sedimentation (Fig. 4, IV), with the top limited by the Santonian unconformity21. This sedimentary pattern can be explained by the differential subsidence of the margin due to the combined effect of the 3D geometry and the dynamic evolution of the stretched margin, resulting in faster subsidence rates to the southwest during this period. A simple variation in the stretching factor β along the margin cannot explain the beginning of the differential subsidence many million years after the end of rifting.
To illustrate how the 3D geometry of the Brazilian margin influenced the subsidence of the Santos Basin, we constructed a numerical model with a simple margin geometry that resembles the southeastern Brazilian margin (see Methods). For this example, we used the viscosity structure of the model in Fig. 2c. From the numerical results, we calculated the total subsidence of the margin for the time interval equivalent to the Cenomanian to lower Santonian sedimentation in the Santos Basin after the end of rifting (Lower Aptian). Assuming a sediment-filled basin, the numerical model can predict the main pattern of sediment thickness along the Santos Basin deposited during this interval of time (Fig. 5). Despite some discrepancies between the observed and calculated thicknesses, this example shows that the regional variations in the sedimentary thickness can be guided by the geometry of the margin combined with the mantle dynamics.
The gliding of Aptian salt from the platform to the deep ocean created an additional accommodation space during the post-rift evolution of the Santos Basin and may hinder the quantification of differential subsidence produced by mantle dynamics. However, although the timing of salt gliding is not clearly known, previous studies suggest that the gliding occurred mainly during the Albian22,23, Santonian-Maastrichtian24 and Palaeocene25. Therefore, the asymmetric Cenomanian-lower Santonian sedimentation could have been partially driven by the differential subsidence as a result of the margin curvature and the mantle dynamics. Later, the Santonian-Maastrichtian salt gliding may have contributed to the migration of the depocentre of the Santos Basin towards the northeast, with the additional contribution of varying sediment supply along the margin26 (Fig. 4, IV–VII).
In addition, previous estimates of Te for the southeastern Brazilian margin indicate that Te<20 km27,28. Therefore, based on our flexural analysis for different lithospheric flexural rigidities, the differential subsidence along the margin is not significantly modified for the low Te values observed in the southeastern Brazilian margin.
The differential subsidence in the Santos Basin promoted by the curved geometry of the margin and mantle dynamics is only possible if the viscosity of the upper mantle under the margin is >2–3 × 1019 Pa s. This lower limit for the viscosity is coherent with the viscosity obtained for other continental margins from the observation of sea-level variations due to glacial melting in the Upper Pleistocene and Holocene and the Earth’s consequent adjustment to the water load, indicating that the upper mantle viscosity beneath continental margins ranges between 1020 and 1021 Pa s (refs 29,30).
Our study demonstrates how the integration of mantle dynamics and the use of a full 3D model in basin analysis may provide new insights into the physical properties of the mantle. This approach could be extended to other curved margins such as the Gulf of Guinea, northeastern Brazil and Angola margins.
Methods
Model parameters and boundary conditions
Using the finite element code CitcomCU, we constructed a 3D Cartesian box that is 660 km deep, 1,320 km wide and 1,980 km long, with 65 × 65 × 97=409,825 nodes. The initial thermal structure follows the scheme shown in Fig. 1. The temperatures at the surface and base of the model were held constant at T=0 and 1,400 °C, respectively. To improve the numerical stability, we imposed an upper limit for the viscosity of η≤2.0 × 1025 Pa s, which is similar to the maximum cut-off value for the viscosity used in previous works31,32. As boundary conditions, we assumed free slip at the top and at the bottom and reflecting sidewalls. Other parameters used in the numerical model are shown in Table 1.
Numerical model for the Brazilian margin
To adequately simulate the subsidence of the Brazilian margin, we constructed a model very similar to the model shown in Fig. 1 with the only difference that the transition from β=1 to β=3 is narrower, with nearly half of the width of the transition shown in Fig. 1. In addition, the model shown in Fig. 5 was rotated 24° clockwise. The viscosity structure of the model is the same as that of the model shown in Fig. 2c: η0=1 × 1020 Pa s, E=30 and V=0.
In this simulation, the total subsidence of the margin was calculated relative to the interior of the continent, specifically the node at the corner of the model in (x,y)=(0,0) (see Fig. 1).
Additional information
How to cite this article: Sacek, V. and Ussami, N. Upper mantle viscosity and dynamic subsidence of curved continental margins. Nat. Commun. 4:2036 doi: 10.1038/ncomms3036 (2013).
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Acknowledgements
FAPESP provided the Post-Doc scholarship to V.S., process 2011/10400-0. The project was funded by the FAPESP thematic project (2009/50493-8) and CNPq (306284/2011-1) grant to N.U. The software CitcomCU was obtained from the website of the Computational Infrastructure for Geodynamics (CIG): http://www.geodynamics.org/. Maps were constructed using the GMT33 software.
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V.S. and N.U. conceived the work. V.S. created the numerical models and made the sensitivity analysis. V.S. and N.U. analysed the numerical results and wrote the paper.
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Sacek, V., Ussami, N. Upper mantle viscosity and dynamic subsidence of curved continental margins. Nat Commun 4, 2036 (2013). https://doi.org/10.1038/ncomms3036
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DOI: https://doi.org/10.1038/ncomms3036
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