The effect of pores (fluid-filled vs. drained) on magma rheology

The presence of pore space strongly affects the rheological behavior of magma and thus influences all volcanic processes (pre-, syn- and post- eruptive). The effects of porosity on magma rheology are, however, unresolved and subject to debate. Here, we present new high-temperature experiments design...

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Bibliographic Details
Published in:Chemical Geology
Main Authors: Stefania Sicola, Alessandro Vona, Amy G. Ryan, James K. Russell, Claudia Romano
Other Authors: Sicola, Stefania, Vona, Alessandro, Ryan, Amy G., Russell, James K., Romano, Claudia
Format: Article in Journal/Newspaper
Language:English
Published: 2021
Subjects:
Magma viscosity
Rhyolite
Porous volcanic material
Vesicularity
Fluid-filled bubbles
Drained pores
Iceland
Online Access:https://hdl.handle.net/11590/385629
https://doi.org/10.1016/j.chemgeo.2021.120147
Description
Summary:The presence of pore space strongly affects the rheological behavior of magma and thus influences all volcanic processes (pre-, syn- and post- eruptive). The effects of porosity on magma rheology are, however, unresolved and subject to debate. Here, we present new high-temperature experiments designed to constrain the rheological properties of variably porous melts (0.09–0.66 fractional porosity) deforming at high temperature (750–800 ◦C) and low strain rates (10 4 — 10 7 s 1). The starting materials are cylindrical cores of natural vesicle- and crystalfree rhyolitic obsidian from Krafla (Iceland) initially containing 0.114 wt% of dissolved H2O. Our experiments comprise two steps. First, cores are heated above the glass transition temperature (700 ◦C) to 900–1050 ◦C; second, the cores are deformed at lower temperatures (750 or 800 ◦C) under a constant low load (1.5 N). We have employed two different strategies for the second step: i) samples are deformed in situ directly after foaming (single-stage, SS); or ii) samples are quenched then reheated and deformed at 750 ◦C after 15 days repose at room conditions (double-stage, DS). Our experiments provide data that inform on the effects of porosity on the viscosity of natural rhyolitic deposits (e.g., ignimbrites, lavas, domes). Discordant results between SS and DS experiments (~0.6 log10 Pa s for 0.5 fractional porosity) suggest that the rheology of porous volcanic materials depends on whether pore spaces are isolated, fluid-filled bubbles (e.g., magmas in the conduit) or are interconnected, drained voids (e.g., domes, lavas, pyroclastic deposits).

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