Satellite composition of the Hawaiian islands


Scientists have long considered volcanic hot spots, like those that created the Hawaiian Islands, stationary points, but a new study finds they are actually in constant motion.

The findings, which appear in in Nature Communications, solve a major debate about the origin of the large-scale structure of the Earth’s surface and deep interior.

The Earth’s lithosphere is the outermost shell of our planet, composed of seven major puzzle pieces known as tectonic plates. While today each of the tectonic plates roughly encompasses one of the seven continents and the Pacific Ocean, scientists believe the pieces once fit together to form supercontinents.

Earth’s last supercontinent, Pangea, began to break apart about 175 million years ago. Much of the Earth’s seismic activity, including earthquakes and volcanoes, occurs at the boundaries of the tectonic plates.

But there are other regions on Earth characterized by volcanic activity, independent of the plate boundaries. Researchers refer to these areas as hot spots. Scientists believe hot spots develop above abnormally hot upwellings of magma in the Earth’s mantle called mantle plumes.

Although researchers can’t travel to the mantle to observe these processes, they are able to infer hot spots because of the volcanism that develops when the magma pushes through the lithosphere. The most active hot spots include those beneath Yellowstone, the Galapagos Islands, Iceland, and Hawaii.

Volcanic hot spots on the move

Scientists widely accepted the theory of plate tectonics in the 1960s, but “deciphering the past motion of Earth’s tectonic plates and linking these motions to deeper processes within the Earth is an ongoing challenge in the geosciences,” says John Tarduno, a professor of earth and environmental sciences at the University of Rochester.

For decades after the plate tectonics revolution, researchers thought hot spots stayed fixed, providing a reference frame to measure the motion of the Earth’s plates.

An iconic illustration of this idea was the 60-degree bend in the chain of islands that make up Hawaii. Researchers believed an assembly line-like process created the Hawaiian Islands: an island would form over a hot spot, the motion of the plate would move the island off the hot spot, and the hot spot would remain in place and generate a new island.

In 2001, Tarduno and colleagues collected samples of rocks and sediment via scientific ocean drilling in Hawaii’s Emperor Seamounts—undersea, extinct volcanoes in the Pacific Ocean. By studying the magnetism locked in the ancient samples—a field known as paleomagnetism—the researchers determined that the hot spot beneath Hawaii was not fixed but had moved. This painted a picture more consistent with an actively convecting and constantly churning mantle.

Despite this evidence, however, controversy over the fixity of hot spots continued.

Satellite composition of the Hawaiian islands. (Credit: NASA/Goddard Space Flight Center)

Slow traveling seismic waves

The debate heightened when researchers recognized that many hot spots were rooted in one of two large regions above the core-mantle boundary: one region under Africa and the other under the Pacific. Seismologists’ research indicated these were regions, known as large low-shear-velocity provinces (LLSVPs), where seismic waves travel slowly. The slow speed meant the regions were unusually hot or chemically different from surrounding rock.

Some scientists believe LLSVPs are relics of plate subduction, where one plate moves downward into the mantle beneath another place, suggesting that LLSVPs are constantly moving. Other scientists believe LLSVPs are stationary and formed from a primordial formation, dating to the earliest processes that shaped the planet.

The new analyses including modeling, geochemistry, and paleomagnetism, suggest LLSVPs are in motion, relics of subduction that has been taking place since the breakup of Pangea.

“LLSVPs are clearly ancient, greater than 100 million years old, but some researchers have claimed they are also fixed and thus can be used as a reference frame for plate motion,” Tarduno says. “The new analyses suggest that LLSVPs can attract mantle plumes until the LLSVPs and the mantle plumes merge.”

The researchers also discovered that LLSVPs can undergo large-scale motion comparable in speed to the motion of the tectonic plates. This provides even more evidence that it was the motion of hot spots—and not their fixity—that caused the bend in the Hawaiian Islands.

Source: University of Rochester



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