49 research outputs found
Seismic and geochemical evidence for large-scale mantle upwelling beneath the eastern Atlantic and western and central Europe
Seismic tomography and the isotope geochemistry of Cenozoic volcanic rocks suggest the existence of a large, sheet-like region of upwelling in the upper mantle which extends from the eastern Atlantic Ocean to central Europe and the western Mediterranean. A belt of extension and rifting in the latter two areas appears to lie above the intersection of the centre of the upwelling region with the base of the lithosphere. Lead, strontium and neodymium isotope data for all three regions converge on a restricted composition, inferred to be that of the upwelling mantle
Timescales of Quartz Crystallization and the Longevity of the Bishop Giant Magma Body
Supereruptions violently transfer huge amounts (100 s–1000 s km3) of magma to the surface in a matter of days and testify to the existence of giant pools of magma at depth. The longevity of these giant magma bodies is of significant scientific and societal interest. Radiometric data on whole rocks, glasses, feldspar and zircon crystals have been used to suggest that the Bishop Tuff giant magma body, which erupted ∼760,000 years ago and created the Long Valley caldera (California), was long-lived (>100,000 years) and evolved rather slowly. In this work, we present four lines of evidence to constrain the timescales of crystallization of the Bishop magma body: (1) quartz residence times based on diffusional relaxation of Ti profiles, (2) quartz residence times based on the kinetics of faceting of melt inclusions, (3) quartz and feldspar crystallization times derived using quartz+feldspar crystal size distributions, and (4) timescales of cooling and crystallization based on thermodynamic and heat flow modeling. All of our estimates suggest quartz crystallization on timescales of <10,000 years, more typically within 500–3,000 years before eruption. We conclude that large-volume, crystal-poor magma bodies are ephemeral features that, once established, evolve on millennial timescales. We also suggest that zircon crystals, rather than recording the timescales of crystallization of a large pool of crystal-poor magma, record the extended periods of time necessary for maturation of the crust and establishment of these giant magma bodies
Peralkaline felsic magmatism at the Nemrut volcano, Turkey: impact of volcanism on the evolution of Lake Van (Anatolia) IV
‘If it’s a medical issue I would have covered it by now’: learning about fibromyalgia through the hidden curriculum: a qualitative study
Rare earth and high field strength element partitioning between iron-rich clinopyroxenes and felsic liquids
Protomylonite evolution potentially revealed by the 3D depiction and fractal analysis of chemical data from a feldspar
Assimilation of preexisting Pleistocene intrusions at Long Valley by periodic magma recharge accelerates rhyolite generation: rethinking the remelting model
Generation of high-silica rhyolite: A Nd, Sr, and O isotopic study of Sierra La Primavera, Mexican Neovolcanic Belt
Pantelleria island (Strait of Sicily): volcanic history and geomorphological landscape
Pantelleria is a volcanic island located in the Strait of Sicily, 95 km far from the Sicilian
coastline and 67 km from Cape Bon (Tunisia). The volcanological history of the island
begins approximately 324 ka BP and the last eruptive event was a submarine eruption that
occurred on 1891 A.D. Eruptive activity was characterized by seven very intense explosive
events, the latest being the Green Tuff (44 ka). They have all produced ignimbrite sheets
that covered large sectors of the island. The landscape of the island mirrors the variety of
the eruptive styles and their interplay with volcano-tectonics. The most evident
geomorphological features are represented by: (i) the mantle-like distribution of the Green
Tuff ignimbrite; (ii) the arcuate remnants of the two large caldera collapses, and (iii) the
intracalderic scoria cones, lava domes and lava fields. A very dense distribution of dry
walls, built since Roman times, perfectly integrate the volcanic landscape, preventing from
erosion and rock falls
