'Before' image of landslide site taken
on Aug. 12, 2023. Credit: Søren Rysgaard
In
September 2023, scientists around the world detected a mysterious seismic
signal that lasted for nine straight days. An international team of scientists,
including seismologists Alice Gabriel and Carl Ebeling of UC San Diego's
Scripps Institution of Oceanography came together to solve the mystery.
A study published in Science provides
the stunning solution: In an East Greenland fjord, a mountaintop collapsed into
the sea and triggered a mega-tsunami about 200 meters (650 feet) tall. The giant wave rocked back and forth inside the narrow fjord
for nine days, generating the seismic waves that reverberated through Earth's
crust, baffling scientists around the world.
This rhythmic sloshing is a phenomenon
known as a seiche.
Fortunately, no people were hurt, but the waves destroyed some $200,000 in
infrastructure at an unoccupied research station on Ella Island.
"When we set out on this scientific
adventure, everybody was puzzled and no one had the faintest idea what caused
this signal," said Kristian Svennevig, a geologist at the Geological
Survey of Denmark and Greenland (GEUS) and the study's lead author.
"All we knew was that it was
somehow associated with the landslide. We only managed to solve this enigma
through a huge interdisciplinary and international effort."
Climate change set the stage for the landslide by melting the glacier at the base of the mountain, destabilizing the more than 25 million cubic meters (33 million cubic yards) of rock and ice—enough to fill 10,000 Olympic-sized swimming pools—that ultimately crashed into the sea. As climate change continues to melt Earth's polar regions it could lead to an increase in large, destructive landslides such as this one.
Image of landslide site taken on Sept.
19, 2023 following Sept. 16, 2023 event. Credit: Danish Army
"Climate
change is shifting what is typical on Earth, and it can set unusual events into
motion," said Gabriel.
When seismic monitoring networks first
detected this signal in September 2023, it was puzzling for two main reasons.
First, the signal looked nothing like the busy squiggle that earthquakes
produce on seismographs. Instead, it oscillated with a 92-second-interval
between its peaks, too slow for humans to perceive. Second, the signal stayed
strong for days on end, where more common seismic events weaken more rapidly.
The global community of Earth scientists
started buzzing with online discussion of what could be causing the strange
seismic waves. The discussion turned up reports of a huge landslide in a remote
Greenland fjord that occurred on Sept. 16, around the time the seismic signal
was first detected.
To figure out if and how these two phenomena might be connected, the team, led by Kristian Svennevig of the Geological Survey of Denmark and Greenland, combined seismic recordings from around the world, field measurements, satellite imagery and computer simulations to reconstruct the extraordinary events.
The team, comprised of 68 scientists from 41 research institutions, analyzed satellite and on-the-ground imagery to document the enormous volume of rock and ice in the landslide that triggered the tsunami. They also analyzed the seismic waves to model the dynamics and trajectory of the rock-ice avalanche as it moved down the glacial gully and into the fjord.
To understand the tsunami and resulting seiche, the researchers used supercomputers to create high-resolution simulations of the events.
"It was a big challenge to do an accurate computer simulation of such a long-lasting, sloshing tsunami," said Gabriel.
Ultimately, these simulations were able to closely match the real-world tsunami's height as well as the long-lasting seiche's slow oscillations.
By integrating these diverse data sources, the researchers determined that the nine-day seismic signal was caused by the massive landslide and resulting seiche within Greenland's Dickson Fjord.
Video recorded of the landslide area three days
after the landslide in Dickson fjord. Credit: Danish Army, Joint Arctic Command
"It was exciting to be working
on such a puzzling problem with an interdisciplinary and international team of
scientists," said Robert Anthony, a geophysicist with the United States
Geological Survey's Earthquake Hazards program and co-author of the study.
"Ultimately, it took a
plethora of geophysical observations and numerical modeling from researchers
across many countries to put the puzzle together and get a complete picture of
what had occurred."
The study's findings demonstrate
the complex, cascading hazards posed by climate change in polar regions. While
no people were in the area when the landslide and mega-tsunami occurred, the
fjord is close to a route commonly used by cruise ships, highlighting the need to monitor polar regions as
climate change accelerates. For example, a landslide in western
Greenland's Karrat Fjord in 2017 triggered a tsunami that flooded the village of
Nuugaatsiaq, destroying 11 houses and killing four people.
Gabriel said the results could also
inspire researchers to comb back through the seismic record to look for similar
events now that scientists know what to look for. Finding more seiches could
help more clearly define the conditions that give rise to the phenomenon.
"This shows there is stuff out
there that we still don't understand and haven't seen before," said
Ebeling, who co-authored the study with support from NSF and helped manage a
network of seismic sensors that detected the seiche's vibrations.
"The essence of science is trying to answer a question we don't know the answer to—that's why this was so exciting to work on."
by University of California - San
Diego
Source: Climate change-triggered landslide unleashes a 650-foot mega-tsunami (phys.org)
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