What Makes the Surface of the Earth Move?

Disintegration of a supercontinent.
Images of the digital solution as a supercontinent (left, purple-gray) begins to disintegrate. (Image: © via Nicolas Coltice)

Does the surface of the Earth, part of the tectonic plates, move because of motion in the mantle, or is the mantle driven by the movement of the plates? Or could it be that this question is ill-posed? This is the point of view adopted by scientists at the École Normale Supérieure — PSL, the CNRS, and the University of Rome 3 — who regard the plates and the mantle as belonging to a single system.

According to their simulations, published in Science Advances, it is mainly the surface that drives the mantle, although the dynamic balance between the two changes over supercontinent cycles. Which forces drive tectonic plates? This has remained an open question ever since the advent of plate tectonic theory 50 years ago.

Do the cold edges of plates slowly sinking into the Earth’s mantle at subduction zones cause the motion observed at the surface? Or alternatively, does the mantle, with its convection currents, drive the plates? For geologists, this is rather like the problem of the chicken and the egg: The mantle apparently causes the plates to move, while they, in turn, drive the mantle…

Images of the digital solution as a supercontinent (left, purple-gray) begins to disintegrate. In the image on the left, the fictitious planet modeled is very similar to the Earth: its surface and mantle move spontaneously, at speeds close to those observed on Earth. The cutting of the 'plates' (some of large and many small) is also similar, as well as the topography: the red tones represent the shallow areas of the oceans (the dorsal) and the blue indicates the deep seabed. The darker blue parts correspond to subduction pits (where a plate dives into the mantle). The continents are translucent white (and therefore appear in purple-gray). The image on the right shows hot currents (or plumes) from the bottom of the mantle.
Images of the digital solution as a supercontinent (left, purple-gray) begins to disintegrate. In the image on the left, the fictitious planet modeled is very similar to the Earth — its surface and mantle move spontaneously, at speeds close to those observed on our home planet. The cutting of the ‘plates’ (some large and many small) is also similar, as well as the topography — the red tones represent the shallow areas of the oceans (the dorsal) and the blue indicates the deep seabed. The darker blue parts correspond to subduction pits (where a plate dives into the mantle). The continents are translucent white (and therefore appear in purple-gray). The image on the right shows hot currents (or plumes) from the bottom of the mantle. (Image: © via Nicolas Coltice)

To shed light on the forces at work, scientists from the Geology Laboratory of the École Normale Supérieure (CNRS/ENS-PSL), the Institute of Earth Sciences (CNRS/Universities Grenoble Alpes and Savoie Mont Blanc/IRD/Ifsttar), and the University of Rome 3 treated the solid Earth as a single indivisible system and carried out the most comprehensive modeling to date of the evolution of a fictional planet very similar to our home planet.

The scientists first had to find the appropriate parameters and then spend some nine months solving a set of equations with a supercomputer, reconstructing the evolution of the planet over a period of 1.5 billion years.

Earth’s surface moves faster than the underlying mantle

Using this model, the team showed that two-thirds of the surface moves faster than the underlying mantle, in other words, it is the surface that drags the interior, while the roles are reversed for the remaining third. This balance of forces changes over geological time, especially for the continents.

The video below is an aggregation of a supercontinent in a numerical model of Earth-like dynamics. 1s = 10 million years:

The latter are mainly dragged by deep motion within the mantle during the construction phases of a supercontinent, as in the ongoing collision between India and Asia: In such cases, the motion observed at the surface can provide information about the dynamics of the deep mantle.

Conversely, when a supercontinent breaks up, the motion is mainly driven by that of the plates as they sink down into the mantle.

The video below is the breakup of a supercontinent in a numerical model of Earth-like dynamics. 1s = 10 million years:

The computation contains a wealth of data that remains largely unexploited. The data obtained could help us to understand how mid-ocean ridges form and disappear, how subduction is triggered, or what determines the location of the plumes that cause vast volcanic outpourings.

Provided by: CNRS [Note: Materials may be edited for content and length.]

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