Tuesday, August 22, 2023

Watch the last billion years of Earth's tectonic plate movement in just 40 seconds

Aylin Woodward,Jenny McGrath
Mon, August 21, 2023 


Watch the last billion years of Earth's tectonic plate movement in just 40 seconds


Tourists walk between a rift in the North American and Eurasian tectonic plates at at Thingvellir National Park, Iceland.Chris Helgren/Reuters

In 2021, geologists animated a video that shows how Earth's tectonic plates moved over the last billion years.


The plates move together and apart at the speed of fingernail growth, and the video speeds up the process to under a minute.


The animation reveals the formations that came before our current seven continents and five oceans.

The land mass that became Antarctica once sat along the Equator. Over Earth's history, several supercontinents have broken up and come back together.

Our current seven continents and five oceans are the result of more than 3 billion years of planetary evolution, the tectonic plates crisscrossing atop the semi-solid mantle layer, the asthenosphere.

But charting the precise movements of those plates over all that time is challenging. Existing models often span only a few million years or focus on just continental or oceanic changes, not both.

But in 2021 a group of geologists offered up an easily digestible peek at 1 billion years of plate tectonic motion.

Geoscientists from the University of Sydney spent four years reconstructing how landmasses and oceans changed over the last billion years. As part of a 2021 study, they animated those changes into the short video below.



The animation shows green continents lumbering across oceans, which are represented in white. The Ma at the top of the video stands for mega-annum or 1 million years, so 1,000 Ma is 1 billion years ago.

The various color lines represent different types of boundaries between tectonic plates: Blue-purple lines depict divergent boundaries, where plates split apart; red triangles indicate convergent boundaries, where plates move together; and grey-green curves show transform boundaries, where plates slide sideways past each other.

"These plates move at the speed fingernails grow, but when a billion years is condensed into 40 seconds, a mesmerizing dance is revealed," Sabin Zahirovic, a University of Sydney geologist who co-authored the study, said in a press release.
Building a better model of Earth's plates

The Earth's plates move in a variety of ways and can cause earthquakes, mountains, and canyons.U.S. Geological Survey

Earth's oldest crust formed 4.4 billion years ago, cooling down enough to solidify roughly 100 million years after the planet emerged.

Subduction, when the edge of one plate slides beneath another, has caused the formation and break up of at least five supercontinents, including Kenorland, Rodinia, and Pangea. Around 175 million years ago, the video shows Pangea slowly pulling apart into the present-day continents.

Today, one can imagine the planet as a chocolate truffle — a viscous center ensconced in a hardened shell. The center consists of a 1,800-mile-thick, semi-solid mantle that encircles a super-hot core. The top layer — between 5 and 50 miles thick — is the crust, which is fragmented into tectonic plates that fit together.

These plates surf atop the mantle, moving around as hotter, less dense material from deep within the Earth rises to the crust, and colder, denser material sinks toward the core.

Geologists can piece together a picture of where the plates were hundreds of millions of years ago by analyzing what's known as paleomagnetic data. When lava at the junction of two tectonic plates cools, some of the resulting rock contains iron-rich minerals that align with the directions of Earth's magnetic poles at the time the rock solidified.

Even after the plates containing those rocks have moved, researchers can parse out where on the global map those natural magnets existed in the past.


A map of the Atlantic Ocean floor.NASA Earth Observatory maps by Joshua Stevens, using data from Sandwell, D. et al. (2014)

Using both paleomagnetics and current tectonic plate data, the study authors were able to create a thorough map of each plate's journey from 1 billion years ago until the present.

"Simply put, this complete model will help explain how our home, planet Earth, became habitable for complex creatures," Dietmar Müller, a co-author of the study, said in the press release.

The jigsaw puzzle of Earth's continents hasn't stopped shifting, of course. The Pacific Ocean, for example, is shrinking year by year. The Atlantic, meanwhile, is widening — pushing the Americas away from Africa and Europe.

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