Abstract
Volatile-rich silicic magma erupts either explosively as a jet of a mixture of pyroclasts and high-temperature gas, or non-explosively to effuse lava. The bifurcation of the eruption style is widely recognised as being controlled by the efficiency of open-system gas loss from vesiculated magma during ascent. However, the fundamental question of how the gas escapes from highly viscous magma still remains unsolved because the pathways of gas flow are rarely preserved in dense lava. Here we show that such pathways are visualised in groundmass glass using high-resolution chlorine (Cl) mapping analysis on the rhyolitic lava of the Mukaiyama volcano, Japan. The results showed that the glass was highly heterogeneous in Cl content. A spatial distribution of the Cl content in the groundmass glass showed that volatiles diffused towards most bubbles, but the bubbles collapsed into the dense melt rather than growing. All observations, in combination with melt inclusion analysis, indicate that vesiculation, the formation of interconnected bubble channels, open-system gas loss via the channels, and channel collapse repeated within the period of a few days to two weeks during ascent. This cycle repeated individually in centimetre-sized portions of magma with different timing.
Highlights
Silicic magma eruption has threatened human life as it frequently devastated towns by generating pyroclastic flows or wide-spreading volcanic ash and pumice
The efficiency of an open-system gas loss is key to controlling eruption style
This model has been the cornerstone of eruption models, it still remains hypothetical because lava rarely preserves bubble channels
Summary
Silicic magma eruption has threatened human life as it frequently devastated towns by generating pyroclastic flows or wide-spreading volcanic ash and pumice. We had a unique opportunity at Mukaiyama volcano in Niijima Island, Japan, to study how open-system gas loss proceeds, as a dome-forming lava from this volcano exhibited the transitional state from vesicular, bubbly magma to bubble-free, obsidian-like magma. This transitional state may have remained due to the extremely low temperature of the Mukaiyama magma We investigated the degassing processes based on texture, chlorine distribution, and water content of three representative lava samples (Samples A, B, and C) collected at a working quarry on the Mukaiyama lava dome
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