No one really knows how the High Plains got so high. ŷڱƵ 70 million years ago, eastern ŷڱƵ, southeastern Wyoming, western Kansas and western Nebraska were near sea level. Since then, the region has risen about 2 kilometers, leading to some head scratching at geology conferences.
Now researchers at the Cooperative Institute for Research in Environmental Sciences () and the Department of Geological Sciences at the University of ŷڱƵ Boulder have proposed a new way to explain the uplift: Water trapped deep below Earth’s crust may have flooded the lower crust, creating buoyancy and lift. The research appears online this week in the journal and could represent a new mechanism for elevating broad regions of continental crust.
“The High Plains are perplexing because there is no deformation—such as major faults or volcanic activity—in the area to explain how this big, vast area got elevated,” said lead author Craig Jones, a CIRES fellow and associate professor of geology at ŷڱƵ-Boulder. “What we suggest is that by hydrating the lower crust, it became more buoyant, and the whole thing came up.”
“It’s like flooding ŷڱƵ from below,” Jones said.
Jones and his colleagues propose the water came from the subducting Farallon oceanic plate under the Pacific Ocean 75 to 45 million years ago. This slab slid underneath the North American continental plate, bringing with it a tremendous amount of water bound in minerals. Trapped and under great pressure and heat, the water was released from the oceanic plate and moved up through the mantle and toward the lower crust. There, it hydrated lower crust minerals, converting dense ones, like garnet, into lighter ones, such as mica and amphibole.
“If you get rid of the dense garnet in the lower crust, you get more elevation because the crust becomes more buoyant,” Jones said. “It’s like blowing the water out of a ballast tank in a submarine.”
Jones had the lightbulb moment for this idea when colleagues, including co-author Kevin Mahan, were describing xenoliths (pieces of crust ejected by volcanic eruptions) from across Wyoming and Montana. The researchers were reviewing the xenoliths’ composition and noticed something striking. Xenoliths near the Canadian border were very rich in garnet. But farther south, the xenoliths were progressively more hydrated, the garnet replaced by mica and other less-dense minerals. In southern Wyoming, all the garnet was gone.
Upon hearing these findings, Jones blurted out, “You’ve solved why Wyoming is higher than Montana,” a puzzle that other theories haven’t been able to explain.
At the time, Mahan, a ŷڱƵ-Boulder assistant professor of geological sciences, noted that the alteration of garnet was thought to be far too ancient, from more than a billion years ago, to fit the theory. But since then, he and another co-author, former ŷڱƵ-Boulder graduate student Lesley Butcher, dated the metamorphism of one xenolith sample from the ŷڱƵ Plateau and discovered it had been hydrated “only” 40-70 million years ago.
Past seismic studies also support the new mechanism. These studies show that from the High Plains of ŷڱƵ to eastern Kansas, the crustal thickness or density correlates with a decline in elevation, from about 2 kilometers in the west to near sea level in the east. A similar change is seen from northern ŷڱƵ north to the Canadian border. In other words, as the crust gets less hydrated, the elevation of the Great Plains also gets lower.
“You could say it’s just by happenstance that we seem to have thicker more buoyant crust in higher-elevation ŷڱƵ than in lower-elevation central Kansas,” Jones said, “but why would crust buoyancy magically correlate today with topography if that wasn’t what created the topography?”
Still, Jones is quick to point out that this mechanism “is not the answer, but a possible answer. It’s a starting point that gives other researchers a sense of what to look for to test it,” he said.
CIRES is a partnership of the dministration and the ŷڱƵ-Boulder.
Other co-authors of the , “Continental uplift through crustal hydration,” are and Lang Farmer, both of CIRES and ŷڱƵ-Boulder’s Department of Geological Sciences. Journalists may obtain a copy of the paper by contacting Kea Giles at kgiles@geosociety.org.
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