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Mixed thermal conditions in convection: how do continents affect the mantle’s circulation?

Published online by Cambridge University Press:  01 June 2017

R. Ostilla-Mónico*
Affiliation:
John A. Paulson School of Engineering and Applied Sciences and Kavli Institute for Bionano Science and Technology, Harvard University, Cambridge, MA 02138, USA
*
Email address for correspondence: [email protected]

Abstract

Natural convection is omnipresent on Earth. A basic and well-studied model for it is Rayleigh–Bénard convection, the fluid flow in a layer heated from below and cooled from above. Most explorations of Rayleigh–Bénard convection focus on spatially uniform, perfectly conducting thermal boundary conditions, but many important geophysical phenomena are characterized by boundary conditions which are a mixture of conducting and adiabatic materials. For example, the differences in thermal conductivity between continental and oceanic lithospheres are believed to play an important role in plate tectonics. To study this, Wang et al. (J. Fluid Mech., vol. 817, 2017, R1), measure the effect of mixed adiabatic–conducting boundary conditions on turbulent Rayleigh–Bénard convection, finding experimental proof that even if the total heat transfer is primarily affected by the adiabatic fraction, the arrangement of adiabatic and conducting plates is crucial in determining the large-scale flow dynamics.

Type
Focus on Fluids
Copyright
© 2017 Cambridge University Press 

1 Introduction

Convection has a prominent place in our planet: the flows in the ocean, atmosphere and in the mantle are driven primarily by density differences. Convective flows are usually studied by using a simple model, i.e. Rayleigh–Bénard convection, the flow in a layer heated from below and cooled from above (Ahlers, Grossmann & Lohse Reference Ahlers, Grossmann and Lohse2009; Lohse & Xia Reference Lohse and Xia2010; Chillà & Schumacher Reference Chillà and Schumacher2012; Xia Reference Xia2013). For intermediate and high Prandtl number convection, which covers the geophysical flows mentioned above, heat is transported mainly by small-scale structures known as plumes. Even for very large temperature differences (Rayleigh numbers), and very turbulent flows, the plumes self-organize and a large-scale coherent flow arises. Plumes are ejected from preferential places in the boundaries, and impact at other points. This has immediate consequences for the flow and how it is felt. For example, in the context of the atmosphere, an upwelling region where plumes are ejected upwards could be thought of as a ‘thermal’, which birds and gliders seek to regain altitude. For the mantle, cold, downwelling regions on tectonic plates could represent places where the continents aggregate (Bott Reference Bott1964).

While explorations of Rayleigh–Bénard convection have been extensive through the years, experiments and simulations have traditionally focused on thermally uniform boundary conditions. Both the mantle, in the shape of the differences between the oceanic and continental lithospheres, and the atmosphere and oceans, because of sea ice floating on water, have substantial inhomogeneity in their thermal boundary conditions. However, the effects of these inhomogeneities have barely been studied. In the mantle, it has been postulated that the difference in thermal conduction between continental and oceanic plates plays a crucial role in the topology of the mantle circulation, and this essentially determines the dynamics of the Wilson cycle. Sea ice comes in a wide range of topologies, and understanding how the fractures, leads and polynyas in ice affect the dynamics of oceanic and atmospheric circulation (Maykut Reference Maykut1982), and by extension global warming, is crucial in today’s world where ice caps are disappearing. And while several studies for mixed temperature boundary conditions have been performed numerically either in two dimensions (Ripesi et al. Reference Ripesi, Biferale, Sbragaglia and Wirth2014) or for lower Rayleigh numbers (Cooper, Moresi & Lenardic Reference Cooper, Moresi and Lenardic2013), no systematic analysis of the flow structure or heat transport in the turbulent regime was performed up to the work of Wang, Huang & Xia (Reference Wang, Huang and Xia2017).

2 Overview

To help understand these issues, Wang et al. (Reference Wang, Huang and Xia2017) performed an experimental study of Rayleigh–Bénard flow with mixed thermal boundary conditions, insulating a fraction of the top plate with adiabatic patches. They used two experimental set-ups: a rectangular tank and a cylindrical tank, in an attempt to make their results as general as possible. These tanks were filled up with water. In both of these systems, several patterns of adiabatic and conducting boundary conditions were used, but in general their focus was on large adiabatic patches, with sizes comparable to the system size – each patch covering either a third of the cube’s lid or a quarter of the cylinder lid. This in line with the simulations of Cooper et al. (Reference Cooper, Moresi and Lenardic2013), but contrasts with the approach by Ripesi et al. (Reference Ripesi, Biferale, Sbragaglia and Wirth2014), whose largest patches are a tenth of the plate size, and only get smaller.

Wang et al. (Reference Wang, Huang and Xia2017) first focus on the heat transfer, finding that for both geometries the leading-order effect happens through the fraction of the boundary which is adiabatic, and through the arrangement of the patterns. The adiabatic area affects the scaling behaviour of the heat transport, and for higher Rayleigh numbers the difference between a perfectly conducting plate and the mixed boundary conditions grows. However, the conducting efficiency is still higher than the fraction of conducting area – the authors find almost no decrease in heat transport for the 75 % conducting cylinder when compared to the homogeneous case, and for the 25 % conducting cylinder, the total heat transport is still over a half of the heat transport of the homogeneous case at the highest Rayleigh number. For the rectangular experiment, similar phenomena are seen. The conducting efficiency is higher than simply the fraction of the conducting area over the total area, and this efficiency tends to decrease with Rayleigh number.

Figure 1. (ac) Time-averaged velocity fields for three configurations. The scale bar represents the modulus of the two in-plane components of velocity in units of $\text{cm}~\text{s}^{-1}$ . (df) The corresponding contour maps of the streamfunction with the scale bar in units of $\text{cm}^{2}~\text{s}^{-1}$ . The streamfunction values are set to zero at the cell boundaries. The contour interval is $0.6~\text{cm}^{2}~\text{s}^{-1}$ . Blue plates represent conducting boundaries and black plates represent adiabatic boundaries. The difference in the flow topology between the asymmetric, single roll, middle panel and the symmetric, two-roll bottom panel is apparent. Taken from Wang et al. (Reference Wang, Huang and Xia2017). (g) Sketch outlining the basic mechanism for continental drift proposed by Bott (Reference Bott1964).

The authors also find that the probability density functions of the temperature fluctuations also seem to be insensitive to the insulating pattern, and depend more on the insulating area. However, the most significant effect of the adiabatic boundary conditions is seen in the large-scale wind. As shown in figure 1, in their rectangular cell, they can switch around between two flow topologies by rearranging the adiabatic patches with the same insulating fraction: either an asymmetric single roll when the patches are arranged asymmetrically or a symmetric double roll if they are arranged symmetrically. This confirms previous geophysical intuitions such as those of Bott (Reference Bott1964) on the role of quasi-adiabatic boundary conditions for convection.

The strength of the large-scale flow is also affected by both the adiabatic fraction and arrangement of the patterns. They find that the underlying wind is strongest when the patches are arranged antisymmetrically and the insulating area is larger. While this might be counter-intuitive, it is easy to rationalize by noting that the only way of removing heat is through the conducting boundaries – so there must be more circulation to remove all the heat, especially if the heat transport is higher than simply the fraction of conducting area multiplied by the homogeneous heat transport. The results confirm this, as the large enhancement in velocity is for the horizontal component and not so much for the vertical one.

3 Future

When compared to previous studies, the work by Wang et al. (Reference Wang, Huang and Xia2017) focuses on large adiabatic patches, as do the simulations of Cooper et al. (Reference Cooper, Moresi and Lenardic2013), while the simulations of Ripesi et al. (Reference Ripesi, Biferale, Sbragaglia and Wirth2014) in two dimensions, and their recent extension by Bakhuis et al. (Reference Bakhuis, Ostilla-Mónico, van der Poel, Verzicco and Lohse2017) to three dimensions, have all focused on patches which have characteristic dimensions smaller than the distance between plates. The two latter numerical studies have shown that from a certain characteristic patch size, the effect on the flow dynamics becomes almost negligible in the turbulent regime. The three-dimensional work by Bakhuis et al. (Reference Bakhuis, Ostilla-Mónico, van der Poel, Verzicco and Lohse2017) also showed that the effect of the shape of these patches is small, something which at first glance contradicts Cooper et al. (Reference Cooper, Moresi and Lenardic2013) and Wang et al. (Reference Wang, Huang and Xia2017). Therefore, a cross-over between two regimes must exist, one where large adiabatic patches which significantly affect the flow topology and another where small adiabatic patches whose effect is only present very close to the plates must exist. Understanding where that regime lies is crucial to understand geophysical flows, because while floating icebergs seem small in comparison with the ocean depth, tectonic plates could pretty much fall in between both categories, as the mantle is slightly less than 3000 km in extension, and if mantle convection is layered, the effective height is even smaller, while the characteristic length scale of plates is in the same range: thousands of kilometres. Another interesting avenue of study would involve a set-up with even larger insulating patches, in order to check whether these could totally prevent flow underneath certain continental plates, leading to cycles of buildup and sudden release of energy.

Finally, for geophysical applications, accounting for the effect of rotation or stabilization is crucial. Around the equator, Coriolis forces become dominant, and rotation drastically changes the flow topology (Greenspan Reference Greenspan1990). Flow topology can also be changed by adding a second stabilizing field, as is the case in thermohaline convection (Schmitt Reference Schmitt1994; Kellner & Tilgner Reference Kellner and Tilgner2014; Yang, Verzicco & Lohse Reference Yang, Verzicco and Lohse2016). Whether mixed thermal boundary conditions can produce the same significant effects as they do for the non-rotating non-stabilized Rayleigh–Bénard convection is an important question which merits attention.

References

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Figure 0

Figure 1. (ac) Time-averaged velocity fields for three configurations. The scale bar represents the modulus of the two in-plane components of velocity in units of $\text{cm}~\text{s}^{-1}$. (df) The corresponding contour maps of the streamfunction with the scale bar in units of $\text{cm}^{2}~\text{s}^{-1}$. The streamfunction values are set to zero at the cell boundaries. The contour interval is $0.6~\text{cm}^{2}~\text{s}^{-1}$. Blue plates represent conducting boundaries and black plates represent adiabatic boundaries. The difference in the flow topology between the asymmetric, single roll, middle panel and the symmetric, two-roll bottom panel is apparent. Taken from Wang et al. (2017). (g) Sketch outlining the basic mechanism for continental drift proposed by Bott (1964).