Kilauea volcano, on the Big Island of Hawai‘i, typically has effusive eruptions, wherein magma flows to create ropy pahoehoe lava, for example. However, Kilauea less frequently erupts more violently, showering scoria and blocks over much of the surface of the island.
To explain the variability in Kilauea’s eruption styles, a team including Bruce Houghton, the Gordon Macdonald Professor of Volcanology in Geology and Geophysics at the University of Hawai‘i at Manoa (UHM) School of Ocean and Earth Science and Technology (SOEST) and colleagues from the University of Cambridge (UC) and Don Swanson from the Hawaiian Volcano Observatory (HVO) of the U.S. Geological Survey analyzed 25 eruptions that have taken place over the past 600 years.
The team’s research shows that the ultimate fate of a magma at Kilauea, that is if the eruption will be effusive or explosive, is strongly influenced by the variability in composition of the deep magma – with more gas-rich magmas producing more explosive eruptions. “Gas-rich magmas are ‘predisposed’ to rise quickly through the Earth’s mantle and crust and erupt powerfully,” Houghton explained.
One of the biggest challenges in volcanic forecasting is to predict at an early stage the full path that an eruption will follow. Monitoring gives scientists an indication where an eruption will occur but not always the probable form it will take.
“Other statistics like a volcano’s volume, eruption rate, and duration are keys to real-time hazard and risk mapping,” said Houghton. “They are the target of approaches like ours.”
This investigation, published this week in Nature Geoscience, required careful analysis of the physical and chemical properties of eruption products over the last 600 years. Swanson and Houghton supplied a framework of very well-characterized eruptions using a detailed classified scheme for the size and power of the eruptions. UC performed nano-scale measurements of the original gas content of the magmas as ‘frozen’ in tiny packets of chilled melt inside large crystals in the magma.
This new look at the eruption history at Kilauea has led to new understanding of what causes eruption style there. “Pre-existing wisdom had it that the form of an eruption was principally decided during the last kilometer of rise towards the surface. But now we know the content of dissolved gas at the deep source is a key,” said Houghton.
In the future, Houghton and colleagues hope to offer even more accurate models by estimating just how fast magma does rise at Kilauea prior to eruption by using the rates at which the trapped original gasses can ‘leak’ out of the trapped magma.