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Imagine you had a crystal ball that revealed when a volcano would next erupt. For the hundreds of millions of people around the world who live near active volcanoes, it would be an extremely useful device.
As it turns out, certain crystals really can help us forecast volcanic eruptions. These crystals are produced in molten rock as it travels from deep inside Earth to the surface.
With increasingly sophisticated scientific methods, we can extract a secret history of volcanoes from these crystals—the why, where and when of past eruptions.
These historical records can help us interpret if signs of volcano unrest, such as earthquakes tracking the movement of magma towards the surface, may lead to an eruption. So, as I explain in a new column in Nature Geoscience, we are getting closer to having crystal balls (for volcanoes, at least).
Image source: Adobe Stock
Magma, the super-hot molten rock which feeds volcanic eruptions, is generated many tens of kilometers below the surface in Earth's mantle.
On its journey up to the surface, magma may get stalled in different reservoirs along the way, and travel to its eventual eruption along a complex pathway. As the magma rises it also cools down, producing tiny crystals that can be brought to the surface during eruptions.
When the magma reaches the surface, it can flow—generating lavas—or explode, generating fragmented particles called pyroclasts. Once the lavas and pyroclasts cool down, they form volcanic rocks containing the crystals from great depths.
Our precious crystal balls have survived the hot and complex journey to the surface and the eruption, holding a memory of everything they "saw" inside the volcano.
The crystals look different depending on the mineral that makes them. For example, green olivine is very common in Hawaiian lavas, and white plagioclase can be as large as a square of chocolate in the lavas of Tweed volcano at the border between Queensland and New South Wales.
A very important mineral for understanding volcanoes is called clinopyroxene, which makes shiny black crystals holding particularly precious information.
Clinopyroxene crystals are often tiny, the size of a sand grain. But under the microscope, they can show spectacular growth features that record what happens inside the volcano before eruptions.
The crystals grow incrementally in concentric zones, much like tree rings. And just as tree rings contain a record of climate change, the chemistry of clinopyroxene zones changes if the magma environment inside the volcano changes.
The final growth zone at the rim of the crystal is particularly important, as it tells us if the eruption was triggered by new magma rising from the depths. We can even estimate the typical amount of time it takes the magma to reach the surface, for example by measuring the blurring of chemical changes in the crystals while they are inside the volcano.
This information is important for future volcano monitoring, because we can often tell when new magma is rising deep beneath a volcano from earthquakes or changes in the chemistry of the gases the volcano gives off. If we know new magma precedes an eruption, we would have an early warning.
Clinopyroxene crystals can also grow with different compositions in different directions, which gives us even more clues. This is called sector zoning and looks like an hourglass inside the crystal.
It is useful because it tells us the crystal grew relatively quickly, which suggests the magma underwent complex events such as mixing with other magma, convection, rising, or releasing gases before the eruption. When monitoring active volcanoes, we can then look for indirect signs of these processes from the surface to see if an eruption may occur.
It is also important to locate where eruption triggers take place inside the volcano. This can tell us if the depths of earthquakes or deformation are particularly indicative of an upcoming eruption.
The chemistry of clinopyroxene helps with this as well, because it tells us about the pressure conditions at the time of crystallization, which can be translated into the depth of magma storage below the surface.
Measuring chemical variations in these tiny crystals takes some fancy lab work. We use tools such as hair-thin lasers fired at the volcanic crystals, or synchrotron light from enormous particle accelerators like the one in Melbourne, which can be focused into a beam as small as a bacteria.
This micro-scale analysis helps us extract the magma secrets from the volcanic crystals, to reconstruct the inner anatomy of a volcano as if we were opening a doll's house.
So next time you hike a volcano, whether in Hawai'i or Iceland, or the Glass House Mountains or Mount Gambier in Australia, look for colored specks in the rocks. You may be looking at the crystal balls containing the volcano's history—and clues about its future.
Teresa Ubide, Volcanic crystal balls, Nature Geoscience (2024). DOI: 10.1038/s41561-024-01509-y
Author: Teresa Ubide
This article is republished from THE CONVERSATION under a Creative Commons license. Read the original article.
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Scientists can't know precisely when a volcano is about to erupt, but they can sometimes pick up telltale signs.
That happened two years ago with the world's largest active volcano. About two months before Mauna Loa spewed rivers of glowing orange molten lava, geologists detected small earthquakes nearby and other signs, and they warned residents on Hawaii's Big Island.
Now a study of the volcano's lava confirms their timeline for when the molten rock below was on the move.
"Volcanoes are tricky because we don't get to watch directly what's happening inside—we have to look for other signs," said Erik Klemetti Gonzalez, a volcano expert at Denison University, who was not involved in the study.
Upswelling ground and increased earthquake activity near the volcano resulted from magma rising from lower levels of Earth's crust to fill chambers beneath the volcano, said Kendra Lynn, a research geologist at the Hawaiian Volcano Observatory and co-author of a new study in Nature Communications.
When pressure was high enough, the magma broke through brittle surface rock and became lava—and the eruption began in late November 2022. Later, researchers collected samples of volcanic rock for analysis.
The chemical makeup of certain crystals within the lava indicated that around 70 days before the eruption, large quantities of molten rock had moved from around 1.9 miles (3 kilometers) to 3 miles (5 kilometers) under the summit to a mile (2 kilometers) or less beneath, the study found. This matched the timeline the geologists had observed with other signs.
The last time Mauna Loa erupted was in 1984. Most of the U.S. volcanoes that scientists consider to be active are found in Hawaii, Alaska and the West Coast.
Worldwide, around 585 volcanoes are considered active.
Scientists can't predict eruptions, but they can make a "forecast," said Ben Andrews, who heads the global volcano program at the Smithsonian Institution and who was not involved in the study.
Andrews compared volcano forecasts to weather forecasts—informed "probabilities" that an event will occur. And better data about the past behavior of specific volcanos can help researchers finetune forecasts of future activity, experts say.
"We can look for similar patterns in the future and expect that there's a higher probability of conditions for an eruption happening," said Klemetti Gonzalez.
More information: Kendra J. Lynn et al, Triggering the 2022 eruption of Mauna Loa, Nature Communications (2024). DOI: 10.1038/s41467-024-52881-7
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