For billions of years, the continents have moved across the Earth’s surface like tectonic vessels, but they have not survived unscathed. Waves in the lower layer known as the mantle could sweep away the keels of continents, pushing their surfaces upward to form visible landforms away from any active plate boundaries, researchers proposed on Aug. 8. Nature. The study provides a plausible origin story for the enigmatic plateaus that emerge from geologically quiet landscapes.
The researchers “have been able to expand and tie together processes that we have speculated about for a long period of time,” says geologist David Foster of the University of Florida in Gainesville. The study builds on research published last year, which suggested that mantle waves also triggered eruptions of diamond-bearing magmas called kimberlite.
At the center of this story are cratons, large blocks of mostly crystalline rock that typically occupy the interior of continents. They are the oldest fragments of the Earth’s crust, with many of them having formed more than 2.5 billion years ago, during the Archean Eon. Much of the crust that once existed on Earth has been destroyed at subduction zones, where one tectonic plate sinks beneath another in the mantle. However, the Kratons avoided this fate.
Cratons owe their longevity to their roots, Foster says. Cratons are much thicker than the surrounding continental crust, with keels that can extend hundreds of kilometers down into the mantle. Keels are relatively buoyant, helping to keep cratons afloat and intact while other parts of the crust sink.
But something about cratons had long puzzled geologists. Some, such as the Kaapvaal craton in southern Africa, are topped by vast plateaus that are surrounded by dramatic escarpments. But cratons are assumed to be stable and are often located far from the uplift tectonic activity that occurs at plate boundaries. So what raised these plateaus?
Some studies have suggested that landforms appeared when the craton passed over a large plume of material rising from deep within the mantle (SN: 15.3.23). But the geological record doesn’t seem to support that explanation, says earth scientist Thomas Gernon of the University of Southampton in England.
So Gernon and colleagues used computer simulations to trace the evolution of a rift that opened in the middle of a continent. They found that pressure changes beneath the rift drove circulation in the mantle, driving a wave that propagated laterally under a continent roughly 20 kilometers every million years.
When the wave encountered a keel of the craton in the simulation, it jumped and swept material into the mantle. This gradually emptied the continent, causing the upper surface to rise up like a ship relieved of its cargo. This uplift followed mantle waves for hundreds of kilometers across the craton, raising a stable plateau roughly one to two kilometers high, Gernon says. And as these elevated regions were eroded by wind and water, the surface rose even more.
Catch the wave
Continental rifts can initiate waves in the underlying mantle that crash up into the crust and build an extended plateau. Click through the slideshow below to see how this happens. In each illustration, the continent is divided into its upper crust, lower crust, and layers of continental lithosphere plus a relatively unstable thermal boundary layer. Beneath the continent is the asthenosphere, the upper ductile layer of the Earth’s mantle.
How mantle waves lift the Earth’s surface to form vast plateaus
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As a rift zone (left) begins to extend toward a continent, it begins to influence the convection of material in the mantle (lower left arrows). Volcanic activity (marked by the vertical red line above the fissure) is mainly clustered around the developing fissure. TM Gernon et al/Nature 2024 -
As the rift progresses, material from the asthenosphere rises up to form oceanic lithosphere—the floor of a sea. In the mantle, a wave of convective material (bottom center) propagates outward from the crack. This mantle wave sweeps material from the thermal boundary layer, a relatively weak part of the continental keel. This removal of material causes the upper surface to rise, and also triggers kimberlite eruptions (red lines), which carry diamonds to the surface and solidify as kimberlite pipes. TM Gernon et al/Nature 2024 -
The mantle wave penetrates far beneath the continent, and kimberlite uplift and volcanism also migrate inland. A broad plateau has formed on the surface and is pierced by kimberlite pipes (red lines). TM Gernon et al/Nature 2024
The researchers also correlated their simulations with geological data. From previously published research, they extracted geochemical data from rocks on the southern African plateau, which recorded the thermal history of the plateau. The data showed that faster cooling rates — an indicator of when the rocks were rising faster — swept across the plateau at a rate consistent with the migration of a mantle wave.
The study ties together many different hypotheses, says geophysicist Cynthia Ebinger of Tulane University in New Orleans. Scientists had previously linked rifting to kimberlite volcanism and showed that the keels of the craton can be hidden by material circulating in the mantle.SN: 19.9.23). But until now, no one had connected those parts to the enigmatic topography of the craton.
“These Archean fragments are still controlling aspects of plate tectonics,” says Ebinger. “That early stage in Earth’s history is still very important.”
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