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.
Resolving discordant U–Th–Ra ages: constraints on petrogenetic processes of recent effusive eruptions at Tatun Volcano Group, northern Taiwan
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Published:January 01, 2015
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CiteCitation
Georg F. Zellmer, Kenneth H. Rubin, Christian A. Miller, J. Gregory Shellnutt, Alexander Belousov, Marina Belousova, 2015. "Resolving discordant U–Th–Ra ages: constraints on petrogenetic processes of recent effusive eruptions at Tatun Volcano Group, northern Taiwan", Chemical, Physical and Temporal Evolution of Magmatic Systems, L. Caricchi, J. D. Blundy
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Abstract
U–Th–Ra isotope analyses of whole rocks and mineral separates were conducted in order to perform isochron dating of three morphologically young lavas from Tatun volcano, northern Taiwan (from Mt Cising, the Shamao dome and the Huangzuei volcano). The data do not yield tight U–Th isochrons, indicating open-system magmatic processes. However, crystallization ages of two samples can be constrained: namely, less than about 1370 years for the Shamao dome, based on 226Ra–230Th disequilibrium in magnetite, and less than approximately 70 ka (but potentially Holocene) for a Huangzuei flow, based on 238U–230Th disequilibrium in plagioclase. Discordant Ar–Ar, 238U–230Th and 226Ra–230Th ages are best explained by young lavas having inherited some crystals from older lithologies (crystal mushes or rocks), and indicate that the above ages represent maxima. Our study provides the first evidence of effusive volcanism at the Tatun Volcano Group in Late Holocene times. All separates from the Shamao dome and Huangzuei volcano are in 234U–238U equilibrium. Minerals in the Mt Cising sample are in 234U–238U disequilibrium, despite the 234U–238U equilibrium of the whole rock. We interpret this as uptake of a hydrothermally altered, old crystal cargo into fresh melt prior to eruption. A different dating approach will thus be required to constrain the eruption age of Mt Cising.
Ar–Ar plateaus from Mt Cising and the Shamao dome, reproduced from Lee (1996), are available at www.geolsoc.org.uk/SUP18817
- absolute age
- actinides
- activity
- alkaline earth metals
- Asia
- Cenozoic
- chemical composition
- concentration
- crystallization
- dates
- eruptions
- Far East
- fractional crystallization
- genesis
- geochemistry
- Holocene
- igneous rocks
- isochrons
- isotope ratios
- isotopes
- lava domes
- lava flows
- magmas
- magmatism
- metals
- mineral assemblages
- mineral composition
- petrography
- phase equilibria
- Quaternary
- Ra-226
- radioactive isotopes
- radium
- Taipei Taiwan
- Taiwan
- Tatun Shan
- Th-230/Ra-226
- Th-232/Th-230
- thorium
- U-238/Th-232
- U-238/U-234
- upper Holocene
- uranium
- uranium disequilibrium
- volcanic rocks
- volcanism
- volcanoes
- whole rock
- Cising Shan
- Huangzuei Shan
- Shamao Shan