The Pacific Dodged a Monster Tsunami After One of the Biggest Quakes Ever. Here's Why
Countries around much of the Pacific, including in East Asia and North and South America, issued alerts and, in some cases, evacuation orders in anticipation of potentially devastating waves. Waves of up to 4 meters [13.1 feet] hit coastal towns in Kamchatka near where the earthquake struck, apparently causing severe damage in some areas.
But in other places waves have been smaller than expected, including in Japan, which is much closer to Kamchatka than most of the Pacific Rim. Many warnings have now been downgraded or lifted with relatively little damage. It seems that for the size of the earthquake, the tsunami has been rather smaller than might have been the case. To understand why, we can look to geology.
The earthquake was associated with the Pacific tectonic plate, one of several major pieces of the Earth's crust. This pushes northwest against the part of the North American plate that extends west into Russia and is forced downwards beneath the Kamchatka peninsula in a process called subduction.
The United States Geological Survey (USGS) says the average rate of convergence—a measure of plate movement—is around 80 millimeters [3.15 inches] per year. This is one of the highest rates of relative movement at a plate boundary.
But this movement tends to take place as an occasional sudden movement of several meters. In any earthquake of this type and size, the displacement may occur over a contact area between the two tectonic plates of slightly less than 400 kilometers [249 miles] by 150 km [93 miles], according to the USGS.
The Earth's crust is made of rock that is very hard and brittle at the small scale and near the surface. But over very large areas and depths, it can deform with slightly elastic behavior. As the subducting slab—the Pacific plate—pushes forward and descends, the depth of the ocean floor may suddenly change.
Nearer to the coastline, the crust of the overlying plate may be pushed upward as the other pushes underneath, or—as was the case off Sumatra in 2004—the outer edge of the overlying plate may be dragged down somewhat before springing back a few meters.
It is these near-instantaneous movements of the seabed that generate tsunami waves by displacing huge volumes of ocean water. For example, if the seabed rose just one meter [3 feet] across an area of 200 by 100 km [124 by 62 miles] where the water is 1 km [0.6 miles] deep, then the volume of water displaced would fill Wembley Stadium to the roof 17.5 million times.
A one-meter rise like this will then propagate away from the area of the uplift in all directions, interacting with normal wind-generated ocean waves, tides, and the shape of the sea floor to produce a series of tsunami waves. In the open ocean, the tsunami wave would not be noticed by boats and ships, which is why a cruise ship in Hawaii was quickly moved out to sea.
The tsunami waves travel across the deep ocean at up to 440 miles per hour [708 km/hr], so they may be expected to reach any Pacific Ocean coastline within 24 hours. However, some of their energy will dissipate as they cross the ocean, so they will usually be less hazardous at the farthest coastlines away from the earthquake.
The hazard arises from how the waves are modified as the seabed rises towards a shoreline. They will slow and, as a result, grow in height, creating a surge of water towards and then beyond the normal coastline.
The Kamchatka earthquake was slightly deeper in the Earth's crust (20.7 km, 12.9 miles) than the Sumatran earthquake of 2004 and the Japanese earthquake of 2011. This will have resulted in somewhat less vertical displacement of the seabed, with the movement of that seabed being slightly less instantaneous. This is why we've seen tsunami warnings lifted some time before any tsunami waves would have arrived there.
Alan Dykes, Associate Professor in Engineering Geology, Kingston University. This article is republished from The Conversation under a Creative Commons license. Read the original article.
Hashtags
Try Our AI Features
Explore what Daily8 AI can do for you:
Comments
No comments yet...
Related Articles
Yahoo
2 hours ago
- Yahoo
Kamchatka quake may have caused volcano's eruption after 600 years, Russia says
(Reuters) -The overnight eruption of the Krasheninnikov Volcano in Kamchatka, its first in 600 years, may be connected to the huge earthquake that rocked Russia's Far East last week, Russia's RIA state news agency and scientists reported on Sunday. "This is the first historically confirmed eruption of Krasheninnikov Volcano in 600 years," RIA cited Olga Girina, head of the Kamchatka Volcanic Eruption Response Team, as saying. She added that the eruption may be connected to the earthquake on Wednesday that triggered tsunami warnings as far away as French Polynesia and Chile, and was followed by an eruption of Klyuchevskoy, the most active volcano on the Kamchatka Peninsula. On the Telegram channel of the Institute of Volcanology and Seismology, Girina said that Krasheninnikov's last lava effusion took place on 1463 - plus/minus 40 years - and no eruption has been known since. The Kamchatka branch of Russia's ministry for emergency services said that an ash plume rising up to 6,000 meters (3.7 miles) has been recorded following the volcano's eruption. The volcano itself stands at 1,856 metres. "The ash cloud has drifted eastward, toward the Pacific Ocean. There are no populated areas along its path," the ministry said on Telegram. The eruption of the volcano has been assigned an orange aviation code, indicating a heightened risk to aircraft, the ministry said.
CNN
2 hours ago
- CNN
Small earthquake shakes the New York area. USGS says magnitude was 3.0
Earthquakes Federal agenciesFacebookTweetLink Follow A small earthquake rattled the New York metropolitan area Saturday night. The U.S. Geological Survey said the tremor had a magnitude of 3.0. It hit in the New Jersey suburb of Hasbrouck Heights, less than 8 miles west of Central Park, at a depth of about 6.2 miles. One resident of New York's Brooklyn borough described it as a very brief tremor, just a slight swaying for a moment. Nevertheless, social media quickly lit up with people who felt it. The official account of the Empire State Building reported in on the social platform X to say: 'I AM FINE.' The tremor was much milder than a 4.8-magnitude quake in 2024 that struck in Tewksbury, New Jersey, a little farther west of the city.
Yahoo
8 hours ago
- Yahoo
Massive Earthquake Could Strike Canada as Ancient Fault Line Wakes
The Tintina fault stretches 1,000 kilometers (621 miles) across northern Canada, crossing the Yukon and ending in Alaska. The fault is thought to have been dormant for 40 million years, but that thinking is challenged by a new study that suggests a major earthquake may be imminent. Researchers from the University of Victoria and the University of Alberta in Canada have spotted signs of two relatively recent groups of earthquakes that significantly shifted the ground: one 2.6 million years ago and one 132,000 years ago. What's more, the team found no evidence of notable earthquakes within the last 12,000 years. That quiet period could actually a warning; based on calculations that the fault is shifting and building up pressure at the rate of 0.2–0.8 millimeters (0.008–0.03 inches) per year, it means a major quake may be imminent. Related: "Over the past couple of decades there have been a few small earthquakes of magnitude 3 to 4 detected along the Tintina fault, but nothing to suggest it is capable of large ruptures," says geologist Theron Finley from the University of Victoria. "The expanding availability of high-resolution data prompted us to re-examine the fault, looking for evidence of prehistoric earthquakes in the landscape." Using a combination of the latest high-resolution satellite imagery and LIDAR (Light Detection and Ranging) technology – measuring laser light reflections to assess terrain levels – the team carried out a fresh look at the Tintina fault. This close analysis helped reveal narrow surface ruptures that are usually well concealed by Canada's forested wilderness. This turned up fault scarps (offsets in the ground surface called 'slips') pointing to past earthquakes, but nothing in the recent geological past. Based on the calculations of the researchers, the fault should have slipped around 6 meters (nearly 20 feet) in that time, but hasn't. When that pressure is eventually released, it could mean an earthquake with a magnitude of more than 7.5. "The Tintina fault therefore represents an important, previously unrecognized, seismic hazard to the region," write the researchers in their published paper. "If 12,000 years or more have elapsed since the last major earthquake, the fault may be at an advanced stage of strain accumulation." This isn't the most populated part of the world, but lives are still in danger – including in nearby Dawson City, home to 1,600 people. Damage to infrastructure and ecosystems also needs to be considered. The researchers want to see further studies of the Tintina fault – and other faults like it – to better figure out the chances of it triggering an earthquake in the future. The more data experts have about historical seismic activity in the area, the better the computer models will be at predicting future events. "Further paleoseismic investigations are required to determine the recurrence intervals between past earthquakes, and whether slip rates have changed through time due to shifts in tectonic regime, or glacial isostatic adjustment," write the researchers. The research has been published in Geophysical Research Letters. Related News Surprising Study Finds Potatoes Evolved From Tomato Ancestor Giant Wave in Pacific Ocean Was The Most Extreme 'Rogue Wave' Ever Recorded Mind-Blowing Discovery: Peacocks Have Lasers In Their Tails
