Search engine for discovering works of Art, research articles, and books related to Art and Culture
Javascript must be enabled to continue!
Magma chamber decompression during explosive caldera-forming eruption of Aira caldera
View through CrossRef
AbstractDecompression of a magma chamber is a fundamental condition of caldera collapse. Although theoretical models have predicted the decompression of magma chambers before caldera collapse, few previous studies have demonstrated the amount of magma chamber decompression. Here, we determine water content in quartz glass embayments and inclusions from pyroclastic deposits of a caldera-forming eruption at Aira volcano approximately 30,000 years ago and apply this data to calculate decompression inside the magma chamber. We identify a pressure drop from 140–260 MPa to 20–90 MPa during the extraction of around 50 km3of magma prior to the caldera collapse. The magma extraction may have caused down-sag subsidence at the caldera center before the onset of catastrophic caldera collapse. We propose that this deformation resulted in the fracturing and collapse of the roof rock into the magma chamber, leading to the eruption of massive ignimbrite.
Springer Science and Business Media LLC
Title: Magma chamber decompression during explosive caldera-forming eruption of Aira caldera
Description:
AbstractDecompression of a magma chamber is a fundamental condition of caldera collapse.
Although theoretical models have predicted the decompression of magma chambers before caldera collapse, few previous studies have demonstrated the amount of magma chamber decompression.
Here, we determine water content in quartz glass embayments and inclusions from pyroclastic deposits of a caldera-forming eruption at Aira volcano approximately 30,000 years ago and apply this data to calculate decompression inside the magma chamber.
We identify a pressure drop from 140–260 MPa to 20–90 MPa during the extraction of around 50 km3of magma prior to the caldera collapse.
The magma extraction may have caused down-sag subsidence at the caldera center before the onset of catastrophic caldera collapse.
We propose that this deformation resulted in the fracturing and collapse of the roof rock into the magma chamber, leading to the eruption of massive ignimbrite.
Related Results
Caldera collapse thresholds correlate with magma chamber dimensions
Caldera collapse thresholds correlate with magma chamber dimensions
AbstractExplosive caldera-forming eruptions eject voluminous magma during the gravitational collapse of the roof of the magma chamber. Caldera collapse is known to occur by rapid d...
Tracking caldera cycles in the Aso-4 magmatic system
Tracking caldera cycles in the Aso-4 magmatic system
<p>Caldera-forming eruptions are among the most hazardous natural events on Earth and pose a significant risk for global consequences in the future. Recent petrologic...
Pressure conditions in coupled magma bodies and their evolution during eruptions and caldera collapse: Piton de la Fournaise 2007
Pressure conditions in coupled magma bodies and their evolution during eruptions and caldera collapse: Piton de la Fournaise 2007
<p>Understanding the interplay between pressure evolution in magma bodies in volcano roots and caldera collapses is important to for the general understanding of volc...
Volcanological challenges to understanding explosive large-scale eruptions
Volcanological challenges to understanding explosive large-scale eruptions
AbstractAn explosive eruption, associated with the formation of a large ignimbrite sheet and collapsed caldera, is the most severe volcanic disaster on Earth. As modern society has...
Deformation driven magma ascent in stratified magma reservoirs: an experimental study
Deformation driven magma ascent in stratified magma reservoirs: an experimental study
<p>Mature volcanic systems (e.g., Yellowstone, USA; Campi Flegrei, Italy) are fed by stratified magma reservoirs &#8211; small bodies of eruptible, crystal-po...
Generation of Pre-Caldera Qixiangzhan and Syn-Caldera Millennium Rhyolites from Changbaishan Volcano by Shallow Remelting: Evidence from Zircon Hf–O Isotopes
Generation of Pre-Caldera Qixiangzhan and Syn-Caldera Millennium Rhyolites from Changbaishan Volcano by Shallow Remelting: Evidence from Zircon Hf–O Isotopes
The Changbaishan volcano is well known for its major caldera-forming Millennium Eruption (ME) in 946 CE (Common Era). We report Hf–O isotopes of zircon grains from pre-caldera Qixi...
Melt re-injection into giant magma reservoir after giant caldera eruption
Melt re-injection into giant magma reservoir after giant caldera eruption
Abstract
Melt re-injection after a giant caldera eruption was quantitatively investigated for the Kikai Caldera Volcano in Japan, which erupted 7300 years ago (Kikai-Akahoy...
Deformation around the Creede Caldera: A consequence of isostatic adjustment following Caldera Formation
Deformation around the Creede Caldera: A consequence of isostatic adjustment following Caldera Formation
The pattern of deformation around the Creede caldera (26.5 Ma), southwest Colorado, may provide clues to the physical mechanisms of caldera evolution, particularly resurgent doming...