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Plate Tectonics: New Findings Fill Out the 50-Year-Old Theory That Explains Earth's Landmasses

Fifty years on geophysicists have progressed from believing continents never moved to thinking that every movement may leave a lasting memory on our Earth. By discovering the secrets of our past, we may be able to predict the motion of our plate tectonic future.

Satellite image of California’s San Andreas fault, where two continental plates come together., NASA/GSFC/METI/ERSDAC/JAROS, and U.S./Japan ASTER Science Team

Fifty years ago, there was a seismic shift away from the longstanding belief that Earth’s continents were permanently stationary.

In 1966, J. Tuzo Wilson published Did the Atlantic Close and then Re-Open? in the journal Nature. The Canadian author introduced to the mainstream the idea that continents and oceans are in continuous motion over our planet’s surface. Known as plate tectonics, the theory describes the large-scale motion of the outer layer of the Earth. It explains tectonic activity (things like earthquakes and the building of mountain ranges) at the edges of continental landmasses (for instance, the San Andreas Fault in California and the Andes in South America).

At 50 years old, with a surge of interest in where the surface of our planet has been and where it’s going, scientists are reassessing what plate tectonics does a good job of explaining – and puzzling over where new findings might fit in.

Evidence for the theory

Although the widespread acceptance of the theory of plate tectonics is younger than Barack Obama, German scientist Alfred Wegener first advanced the hypothesis back in 1912.

A map of the original supercontinent, Pangaea, with modern continent outlines. Kieff, CC BY-SA

He noted that the Earth’s current landmasses could fit together like a jigsaw puzzle. After analyzing fossil records that showed similar species once lived in now geographically remote locations, meteorologist Wegener proposed that the continents had once been fused. But without a mechanism to explain how the continents could actually “drift,” most geologists dismissed his ideas. His “amateur” status, combined with anti-German sentiment in the period after World War I, meant his hypothesis was deemed speculative at best.

In 1966, Tuzo Wilson built on earlier ideas to provide a missing link: the Atlantic ocean had opened and closed at least once before. By studying rock types, he found that parts of New England and Canada were of European origin, and that parts of Norway and Scotland were American. From this evidence, Wilson showed that the Atlantic Ocean had opened, closed and re-opened again, taking parts of its neighboring landmasses with it.

And there it was: proof our planet’s continents were not stationary.

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The 15 major plates on our planet’s surface

How plate tectonics works

Earth’s crust and top part of the mantle (the next layer in toward the core of our planet) run about 150 km deep. Together, they’re called the lithosphere and make up the “plates” in plate tectonics. We now know there are 15 major plates that cover the planet’s surface, moving at around the speed at which our fingernails grow.

Based on radiometric dating of rocks, we know that no ocean is more than 200 million years old, though our continents are much older. The oceans' opening and closing process – called the Wilson cycle – explains how the Earth’s surface evolves.

A continent breaks up due to changes in the way molten rock in the Earth’s interior is flowing. That in turn acts on the lithosphere, changing the direction plates move. This is how, for instance, South America broke away from Africa. The next step is continental drift, sea-floor spreading, ocean formation – and hello, Atlantic Ocean. In fact, the Atlantic is still opening, generating new plate material in the middle of the ocean and making the flight from New York to London a few inches longer each year.

A simplified ‘Wilson Cycle’. Philip Heron, CC BY

Oceans close when their tectonic plate sinks beneath another, a process geologists call subduction. Off the Pacific Northwest coast of the United States, the ocean is slipping under the continent and into the mantle below the lithosphere, creating in slow motion Mount St Helens and the Cascade mountain range.n addition to undergoing spreading (construction) and subduction (destruction), plates can simply rub up against each other - usually generating large earthquakes. These interactions, also discovered by Tuzo Wilson back in the 1960s, are termed “conservative.” All three processes occur at the edges of plate boundaries.

In addition to undergoing spreading (construction) and subduction (destruction), plates can simply rub up against each other - usually generating large earthquakes. These interactions, also discovered by Tuzo Wilson back in the 1960s, are termed “conservative.” All three processes occur at the edges of plate boundaries.

But the conventional theory of plate tectonics stumbles when it tries to explain some things. For example, what produces mountain ranges and earthquakes that occur within continental interiors, far from plate boundaries?

Gone but not forgotten

The answer may lie in a map of ancient continental collisions my colleagues and I assembled.

Over the past 20 years, improved computer power and mathematical techniques have allowed researchers to more clearly look below the Earth’s crust and explore the deeper parts of our plates. Globally, we find many instances of scarring left over from the ancient collisions of continents that formed our present-day continental interiors.

Present day plate boundaries (white) with hidden ancient plate boundaries that may reactivate to control plate tectonics (yellow). Regions where anomalous scarring beneath the crust are marked by yellow crosses. Philip Heron, CC BY

A map of ancient continental collisions may represent regions of hidden tectonic activity. These old impressions below the Earth’s crust may still govern surface processes – despite being so far beneath the surface. If these deep scarred structures (more than 30 km down) were reactivated, they would cause devastating new tectonic activity.

It looks like previous plate boundaries (of which there are many) may never really disappear. These inherited structures contribute to geological evolution, and may be why we see geological activity within current continental interiors.

Mysterious blobs 2,900 km down

Modern geophysical imaging also shows two chemical “blobs” at the boundary of Earth’s core and mantle – thought to possibly stem from our planet’s formation.

These hot, dense piles of material lie beneath Africa and the Pacific. Located more than 2,900 km below the Earth’s surface, they’re difficult to study. And nobody knows where they came from or what they do. When these blobs of anomalous substance interact with cold ocean floor that has subducted from the surface down to the deep mantle, they generate hot plumes of mantle and blob material that cause super-volcanoes at the surface.

Does this mean plate tectonic processes control how these piles behave? Or is it that the deep blobs of the unknown are actually controlling what we see at the surface, by releasing hot material to break apart continents?

Answers to these questions have the potential to shake the very foundations of plate tectonics.

Arizona State seismology expert Ed Garnero’s summary of how far we have come in over 100 years of studying the interior of the Earth. Ed Garnero, CC BY

Plate tectonics in other times and places

And the biggest question of all remains unsolved: How did plate tectonics even begin?

The early Earth’s interior had significantly hotter temperatures – and therefore different physical properties – than current conditions. Plate tectonics then may not be the same as what our conventional theory dictates today. What we understand of today’s Earth may have little bearing on its earliest beginnings; we might as well be thinking about an entirely different world.

In the coming years, we may be able to apply what we discover about how plate tectonics got started here to actual other worlds – the billions of exoplanets found in the habitable zone of our universe.

Venus has some geologic features, but not plate tectonics. NASA/JPL, CC BY

So far, amazingly, Earth is the only planet we know of that has plate tectonics. In our solar system, for example, Venus is often considered Earth’s twin - just with a hellish climate and complete lack of plate tectonics.

Incredibly, the ability of a planet to generate complex life is inextricably linked to plate tectonics. A gridlocked planetary surface has helped produce Venus' inhabitable toxic atmosphere of 96 percent CO₂. On Earth, subduction helps push carbon down into the planet’s interior and out of the atmosphere.

It’s still difficult to explain how complex life exploded all over our world 500 million years ago, but the processes of removing carbon dioxide from the atmosphere is further helped by continental coverage. An exceptionally slow process starts with carbon dioxide mixing with rain water to wear down continental rocks. This combination can form carbon-rich limestone that subsequently washes away to the ocean floor. The long removal processes (even for geologic time) eventually could create a more breathable atmosphere. It just took 3 billion years of plate tectonic processes to get the right carbon balance for life on Earth.

A theory works now, but what’s in the future?

Fifty years on from Wilson’s 1966 paper, geophysicists have progressed from believing continents never moved to thinking that every movement may leave a lasting memory on our Earth.

Life here would be vastly different if plate tectonics changed its style – as we know it can. A changing mantle temperature may affect the interaction of our lithosphere with the rest of the interior, stopping plate tectonics. Or those continent-sized chemical blobs could move from their relatively stable state, causing super-volcanoes as they release material from their deep reservoirs.

It’s hard to understand what our future holds if we don’t understand our beginning. By discovering the secrets of our past, we may be able to predict the motion of our plate tectonic future.

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Philip Heron is a Postdoctoral Fellow in Geodynamics, University of Toronto