Abstract
Active volcanoes are typically fed by magmatic reservoirs situated within the upper crust. The development of thermal and/or compositional gradients in such magma chambers may lead to vigorous convection as inferred from theoretical models and evidence for magma mixing recorded in volcanic rocks. Bi-directional flow is also inferred to prevail in the conduits of numerous persistently-active volcanoes based on observed gas and thermal emissions at the surface, as well as experiments with analogue models. However, more direct evidence for such exchange flows has hitherto been lacking. Here, we analyse the remarkable oscillatory zoning of anorthoclase feldspar megacrystals erupted from the lava lake of Erebus volcano, Antarctica. A comprehensive approach, combining phase equilibria, solubility experiments and melt inclusion and textural analyses shows that the chemical profiles are best explained as a result of multiple episodes of magma transport between a deeper reservoir and the lava lake at the surface. Individual crystals have repeatedly travelled up-and-down the plumbing system, over distances of up to several kilometers, presumably as a consequence of entrainment in the bulk magma flow. Our findings thus corroborate the model of bi-directional flow in magmatic conduits. They also imply contrasting flow regimes in reservoir and conduit, with vigorous convection in the former (regular convective cycles of ∼150 days at a speed of ∼0.5 mm s−1) and more complex cycles of exchange flow and re-entrainment in the latter. We estimate that typical, 1-cm-wide crystals should be at least 14 years old, and can record several (from 1 to 3) complete cycles between the reservoir and the lava lake via the conduit. This persistent recycling of phonolitic magma is likely sustained by CO2 fluxing, suggesting that accumulation of mafic magma in the lower crust is volumetrically more significant than that of evolved magma within the edifice.
Highlights
Many volcanoes, such as Etna and Stromboli in Italy, persistently emit prodigious quantities of gas and heat at the surface without significant accompanying lava flows or tephra production (Francis et al, 1993)
We present the results of phase equilibrium experiments, and compare the chemistry of synthetic and natural anorthoclase
The possible temperature range of the natural system is narrow and well established: it cannot be colder than 925 ◦C or biotite, a phase never observed in Erebus lavas, would crystallise
Summary
Many volcanoes, such as Etna and Stromboli in Italy, persistently emit prodigious quantities of gas and heat at the surface without significant accompanying lava flows or tephra production (Francis et al, 1993). Tween two fluids of contrasting density and viscosity (Kazahaya et al, 1994; Stevenson and Blake, 1998; Huppert and Hallworth, 2007; Beckett et al, 2011) These studies suggest that a stable bi-directional flow can develop in volcanic conduits, and reinforce interpretations of the magma dynamics of a number of persistently degassing volcanoes (e.g., Oppenheimer et al, 2009; Shinohara and Tanaka, 2012). All bombs analysed since 1972 are virtually identical in terms of mineral assemblage (with one exception) and whole rock and matrix glass major, minor and trace elements (Kelly et al, 2008) This chemical stability extends to older lava flows, such that all lavas erupted from Erebus in the last 20 ka have the same composition (Kelly et al, 2008) making the volcano an ideal system to investigate using experimental petrology tools at equilibrium conditions
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