What do those numbers mean? A handy animation illustrates the enormous difference in power from one level to the next on the earthquake magnitude scale. Read on for a story on the largest earthquake ever recorded – and an explanation of the tectonic forces that are behind the most colossal of these cataclysms on our planet.
Earthquake Magnitude: Just How Big Was the Biggest Earthquake?
This week marks the anniversary of the largest earthquake ever recorded — a magnitude-9.5 earthquake that ripped along the coast of southern Chile on May 22, 1960.
The colossal quake and the powerful tsunami that followed killed more than 1,400 people and left 2 million homeless in Chile. And its devastation reached far beyond South America.
The tsunami swept across the Pacific Ocean, wreaking havoc in Hawaii, the Philippines and Japan; a day after the earthquake, walls of water up to 18 feet (5.5 meters) high rushed ashore at Honshu, Japan’s main island, destroying 1,600 homes and killing 138 people.
The colossal quake was what is known as a megathrust earthquake. These giant quakes, the most powerful quakes the planet is capable of unleashing, occur along subduction zones, where one tectonic plate dives beneath another.
In this case, the quake was caused when a 620-mile-long (1,000 kilometers) stretch of the Nazca plate, an oceanic plate that forms a large swath of the Pacific Ocean floor, lurched deeper beneath the South American plate, producing the only 9.5-magnitude quake on record.
So just how big is a 9.5? An earthquake magnitude video, created with an animation from Nathan Becker, an oceanographer at the Pacific Tsunami Warning Center, offers a simple way to understand the vast differences between one magnitude and the next.
Essentially, each successive magnitude is 33 times larger than the last. That means a magnitude-8.0 earthquake is 33 times stronger than a 7.0, and a magnitude-9.0 earthquake is 1,089 (33 x 33) times more powerful than a 7.0 — the energy ramps up fast.
Although figuring out an earthquake’s power requires lots of complicated math and lots of data, magnitude boils down to three basic factors: area, distance and friction.
“It’s about the physical properties of the fault,” said Paul Earle, a seismologist with the U.S. Geological Survey.
To get the magnitude, Earle told OurAmazingPlanet, you multiply the area of the fault that slipped — how much real estate moved — by the distance it moved and by the amount of friction on the fault.
Fiddling with any of those factors will change the magnitude.
Yet some earthquakes are, by the mechanism that causes them, able to unleash far more power than others. All the most powerful earthquakes on record are so-called subduction earthquakes — the sort that happen where tectonic plates overlap.
And that’s because they simply have more real estate at their disposal than earthquakes that happen in the middle of a continental plate, known as strike-slip earthquakes.
These earthquakes happen along faults that are, essentially, vertical — the San Andreas Fault is perhaps the most famous such fault in the United States.
The faults that produce strike-slip quakes plunge into the Earth’s interior in a fairly straight line. That means they reach hotter, gooier geological territory — places where the rocks aren’t rigid enough to make an earthquake — faster than the faults at subduction zones, which head into the Earth at an angle.
“If you go straight down, you get to the non-brittle zone faster than if you go at an angle,” Earle said. And that means strike-slip faults just don’t have as much area as the angled faults at subduction zones, and thus can’t produce quakes with quite as much punch.
Yet strike-slip quakes can still cause catastrophic damage. And scientists are hard at work on designing systems that will provide a few seconds of warning when an earthquake hits, no matter what the mechanism that caused it.