Abstract
Crystallization timescales in subvolcanic systems and the consequences of interaction between ascending magmas and gases remain largely unconstrained, as do links between these processes and monitoring signals at restless volcanoes. We apply diffusion chronometry to radially-oriented plagioclase and associated olivine in a glomerocryst from Tolbachik volcano (Kamchatka, Russia) to elucidate such processes. We show that cm-size glomerocrysts grow in a few days prior to, or during, eruption. Melt inclusions from these glomerocrysts show no compositional evolution during crystallization, implying growth in a melt-rich and dynamic environment. Volatile elements in melt inclusions show significant variability, with increasing CO2 as H2O decreases. This behaviour is inconsistent with normal degassing processes, and more likely reflects CO2-fluxing. On the basis of short residence timescales of glomerocrysts and sharp changes in melt inclusion volatile abundances, we propose that rapid (pre-)eruptive crystallization is controlled by rhythmic fluxing of magmatic H2O and CO2 through the sub-volcanic conduit. This implies that compositional zoning in plagioclase, from resorption textures to oscillatory zoning, record short-term CO2- and H2O-fluxing episodes, consistent with strombolian eruption dynamics. We propose that volcanic glomerocrysts represent the counterpart of vertical igneous layering (or comb layering) in shallow plutons. Magmatic layering and glomerocrysts dominated by radial plagioclase offer novel ways of targeting short-term crystallization and degassing processes in subvolcanic systems.
Highlights
Volcanic eruptions are controlled by two fundamental processes: advection of fresh batches of hot magma from deep reservoirs towards the surface (e.g. Sparks et al, 1977; Bouvet de Maisonneuve et al, 2013); and degassing of dissolved volatiles (CO2, H2O, SO2) from magmas during ascent (Woods and Cardoso, 1997)
On the basis of short residence timescales of glomerocrysts and sharp changes in melt inclusion volatile abundances, we propose that rapideruptive crystallization is controlled by rhythmic fluxing of magmatic H2O and CO2 through the sub-volcanic conduit
CL (Fig. 1) and EBSD (Fig. 3a) mapping indicate that plagioclase glomerocrysts are formed of radially-oriented, twinned plagioclase crystals growing from a central part of the glomerocryst towards the exterior, similar to experimental work on glomerocrysts by Arzilli et al (2015)
Summary
Volcanic eruptions are controlled by two fundamental processes: advection of fresh batches of hot magma from deep reservoirs towards the surface (e.g. Sparks et al, 1977; Bouvet de Maisonneuve et al, 2013); and degassing of dissolved volatiles (CO2, H2O, SO2) from magmas during ascent (Woods and Cardoso, 1997). Volcanic eruptions are controlled by two fundamental processes: advection of fresh batches of hot magma from deep reservoirs towards the surface The low solubility of CO2 in magmas compared to H2O (Newman and Lowenstern, 2002; Papale, 2005; Ghiorso and Gualda, 2015) implies that ascending CO2-rich fluids exsolve from deep reservoirs and interact with H2O-rich shallower magmatic systems (Papale 2005; Blundy et al, 2010; Yoshimura, 2015; Caricchi et al, 2018). A consequence of the low solubility of CO2 compared to H2O is that a small addition of CO2 to H2O-saturated magmas can have a significant effect on the confining pressures of magmatic reservoirs (Blundy et al, 2010; Caricchi et al, 2018).
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