Chemical, Physical and Temporal Evolution of Magmatic Systems
Our understanding of the physical and chemical processes that regulate the evolution of magmatic systems has improved tremendously since the foundations were laid down 100 years ago by Bowen. The concept of crustal magma chambers has progressively evolved from molten-rock vats to thermally, chemically and physically heterogeneous reservoirs that are kept active by the periodic injection of magma. This new model, while more complex, provides a better framework to interpret volcanic activity and decipher the information contained in intrusive and extrusive rocks.
Igneous/metamorphic petrology, geochemistry, geochronology and numerical modelling all contributed towards this new picture of crustal magmatic systems. This book provides an overview of the wide range of approaches that can nowadays be used to understand the chemical, physical and temporal evolution of magmatic and volcanic systems.
Mafic magma replenishment, unrest and eruption in a caldera setting: insights from the 2006 eruption of Rabaul (Papua New Guinea)
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Published:January 01, 2015
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CiteCitation
C. Bouvet de Maisonneuve, F. Costa, H. Patia, C. Huber, 2015. "Mafic magma replenishment, unrest and eruption in a caldera setting: insights from the 2006 eruption of Rabaul (Papua New Guinea)", Chemical, Physical and Temporal Evolution of Magmatic Systems, L. Caricchi, J. D. Blundy
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Abstract
Understanding the magmatic processes that drive unrest at silicic calderas remains a major goal in Volcanology. Rabaul in Papua New Guinea is an exceptional location because after two decades of unrest and a peak in seismicity and deformation in 1983–85, eruptive activity began in 1994 and is still ongoing. A particularly large sub-Plinian eruption occurred from Tavurvur in October 2006. Whole-rock compositions are andesitic and reflect mixing/mingling between basaltic and dacitic magmas from the same system. The magmas that fed the 2006 eruption were stored at about 930°C, with 1–3 wt% H2O, 25–520 ppm CO2, and 50–2500 ppm SO2 in the melt. Melt inclusions hosted in pyroxene, and plagioclase phenocrysts record fractional crystallization at ≤200 MPa under relatively dry and poorly oxidizing conditions. Magma mixing/mingling is expressed as heterogeneous glass compositions, strongly zoned phenocrysts, and mafic crystal aggregates. A textural maturation from fine, acicular to large, blocky crystal clots implies different relative ages of formation. Modelling the chemical zoning of plagioclase shows that mafic–silicic interactions started a couple of decades prior to the 2006 eruption and continued until days to weeks prior to eruption. Basaltic replenishments have been driving unrest and eruption at the Rabaul caldera since the 1970s.
Tables and figures reporting the composition of the Tavurvur 2006, Kombiu and 1.4 ka BP caldera samples and showing thermodynamic modelling with MELTS are available at http://www.geolsoc.org.uk/SUP18816
- acidic magmas
- Australasia
- basalts
- Bismarck Archipelago
- chemical composition
- computer programs
- crystal growth
- crystal zoning
- dacites
- degassing
- electron probe data
- emplacement
- eruptions
- fluid inclusions
- fractional crystallization
- genesis
- glasses
- hybridization
- igneous rocks
- ignimbrite
- inclusions
- intrusions
- mafic magmas
- magma chambers
- magmas
- magmatic differentiation
- magmatism
- mass balance
- melt inclusions
- melts
- mesostasis
- mineral assemblages
- mineral composition
- mixing
- P-T conditions
- Papua New Guinea
- petrography
- phase equilibria
- pumice
- pyroclastics
- quenching
- Rabaul Caldera
- sulfur dioxide
- textures
- volatiles
- volcanic glass
- volcanic rocks
- volcanism
- Tavurvur
- mingling
- PETROLOG 2.1
- Kombiu