Newswise — From the Greek island of Santorini, the eruption had been visible for several weeks. In the late summer of 1650, people reported that the colour of the water had changed and the water was boiling. About seven kilometres north-east of Santorini, an underwater volcano had risen from the sea and began ejecting glowing rocks. Fire and lightning could be seen, and plumes of smoke darkened the sky. Then the water suddenly receded, only to surge towards the coastline moments later, battering it with waves up to 20 metres high. A huge bang was heard more than 100 kilometres away, pumice and ash fell on the surrounding islands, and a deadly cloud of poisonous gas claimed several lives.
"We know these details of the historic eruption of Kolumbo because there are contemporary reports that were compiled and published by a French volcanologist in the 19th century," says Dr Jens Karstens, marine geophysicist at GEOMAR Helmholtz Centre for Ocean Research Kiel. But how did these devastating events come about? To find out, he and his German and Greek colleagues went to the Greek Aegean Sea in 2019 to study the volcanic crater with special technology. Karstens: "We wanted to understand how the tsunami came about at that time and why the volcano exploded so violently."
On board the now decommissioned research vessel POSEIDON, the team used 3D seismic methods to create a three-dimensional image of the crater, which is now 18 metres below the water's surface. Dr Gareth Crutchley, co-author of the study: "This allows us to look inside the volcano." Not only did the 3D imaging show that the crater was 2.5 kilometres in diameter and 500 metres deep, suggesting a truly massive explosion, the seismic profiles also revealed that one flank of the cone had been severely deformed. Crutchley: "This part of the volcano has certainly slipped." The researchers then took a detective’s approach, comparing the various mechanisms that could have caused the tsunami with the historical eyewitness accounts. They concluded that only a combination of a landslide followed by a volcanic explosion could explain the tsunami. Their findings are published today in the journal Nature Communications.
By combining 3D seismics with computer simulations, the researchers were able to reconstruct how high the waves would have been if they had been generated by the explosion alone. Karstens: "According to this, waves of six metres would have been expected at one particular location, but we know from the reports of eyewitnesses that they were 20 metres high there". Furthermore, the sea is said to have first receded at another point, but in the computer simulation a wave crest reaches the coast first. Thus, the explosion alone cannot explain the tsunami event. However, when the landslide was included in the simulations, the data agreed with historical observations.
Jens Karstens explains: "Kolumbo consists partly of pumice with very steep slopes. It is not very stable. During the eruption, which had been going on for several weeks, lava was continuously ejected. Underneath, in the magma chamber, which contained a lot of gas, there was enormous pressure. When one of the volcano's flanks slipped, the effect was like uncorking a bottle of champagne: the sudden release of pressure allowed the gas in the magma system to expand, resulting in a huge explosion". Something similar could have happened during the 2022 eruption of the Hunga Tonga undersea volcano, whose volcanic crater has a similar shape to Kolumbo's.
The study thus provides valuable information for the development of monitoring programmes for active submarine volcanic activity, such as SANTORY, which is led by co-author Prof. Dr Paraskevi Nomikou of the National and Kapodistrian University of Athens (NKUA). "We hope to be able to use our results to develop new approaches to monitor volcanic unrest," says Jens Karstens, "maybe even an early warning system, collecting data in real time. That would be my dream”.
About 3D Marine Reflection Seismics
3D seismics is a geophysical technique that exploits the fact that sound waves are partially reflected at the boundaries of layers. This makes it possible to create cross-sectional profiles of geological structures beneath the seabed. Unlike 2D reflection seismics, marine 3D reflection seismics uses multiple measuring cables (housing receivers) towed in parallel behind the research vessel. The result is a three-dimensional image, known as a seismic volume, which allows us to look beneath the seafloor and analyse the geology in detail.