What is the risk of a volcano erupting? To answer this question, scientists need information about its underlying internal structure. However, gathering this data can take several years of fieldwork, analyses and monitoring, which explains why only 30% of active volcanoes are currently well documented. A team from the University of Geneva (UNIGE) has developed a method for rapidly obtaining valuable information. It is based on three parameters: the height of the volcano, the thickness of the layer of rock separating the volcano’s reservoir from the surface, and the average chemical composition of the magma. These results open new prospects for identifying volcanoes that present the greatest risk and are published in the journal Geology.
The Earth is home to some 1,500 active volcanoes, yet we only have accurate data for 30% of them. This is due to the difficulty of observing their “fuel,” the famous magma, which is rich in information. This molten rock is first generated at a depth of between 60 km and 150 km in the Earth’s mantle, whereas the deepest human boreholes generally only reach a depth of around ten kilometres, preventing direct observation. The production rate of magma in the Earth’s deep crust beneath a volcano determines the size and frequency of future eruptions.
This lack of data is a danger as more than 800 million people live close to active volcanoes. Therefore, in many regions, there is no basis on which to assess the risk a given volcano poses and the extent of the protective measures to be taken — the evacuation perimeter, for example — in the event of a suspected eruption.
Three key parameters
Geochemical and geophysical analysis methods are regularly used by scientists to monitor volcanoes, but it can take decades to gain an in-depth understanding of how a specific volcano works. Thanks to recent work by the team of Luca Caricchi, full professor at the Department of Earth Sciences of the UNIGE Faculty of Science, it is now possible to obtain valuable information more rapidly.
This method uses three easy-to-measure parameters: the height of the volcano, the thickness of the rocks separating the volcano’s “reservoir” from the surface, and the chemical composition of the magma released over its eruptive history. The first can be determined by satellite, the second by geophysics and/or chemical analysis of minerals (crystals) in the volcanic rocks, and the third by direct sampling in the field.
A “snapshot”
By analysing existing data on the volcanic arc of the Lesser Antilles, a well-studied archipelago of volcanic islands, the UNIGE team has highlighted a correlation between the height of volcanoes and the rate at which magma is produced. “The highest volcanoes produce the biggest eruptions on average during their life. In other words, they can erupt a greater quantity of magma in a single event,” explains Oliver Higgins, a former doctoral student in Luca Caricchi’s group and first author of the study.
Scientists have also found that the thinner the Earth’s crust beneath the volcano, the closer its magma reservoir is to the surface, and the more thermally mature the volcano is. “When the magma rises from depth, it tends to cool and solidify, which halts its ascent. But when the supply of magma is large, magma retains its temperature, accumulates in the reservoir that will fuel a future eruption, and ‘eats away’ at the Earth’s crust,” explains Luca Caricchi, the second and last author of the study.
Identifying the volcanoes most at risk
Finally, the researchers observed that the average chemical composition of magma that has already erupted is an indicator of its explosiveness. “High levels of silica, for example, indicate that the volcano is fed by a large quantities of magma. In this case, there is a greater risk of a large, explosive eruption from that volcano,” explains the researcher.
Together, the three parameters identified by the UNIGE team produce a “snapshot” of a volcano’s internal structure. They enable an initial assessment of the hazard associated with poorly studied volcanoes, without the need for major technical and financial resources. This method can be used to identify the active volcanoes that are most likely to produce a large-scale eruption, and that require increased surveillance.
Reference:
Oliver Higgins, Luca Caricchi. Eruptive dynamics reflect crustal structure and mantle productivity beneath volcanoes. Geology, 2023; DOI: 10.1130/G51355.1
Note: The above post is reprinted from materials provided by Université de Genève.
