V23F-08:
Ascent Rates from Melt Embayments: Insights into the Eruption Dynamics of Arc Volcanoes

Tuesday, 16 December 2014: 3:25 PM
Philipp Ruprecht1, Alexander S Lloyd1, Erik Hauri2, William I Rose3, Helge Martin Gonnermann4 and Terry A Plank1, (1)Lamont Doherty Earth Obs., Palisades, NY, United States, (2)DTM Carnegie Institution, Washington, DC, United States, (3)Michigan Technological Univ, Houghton, MI, United States, (4)Rice University, Houston, TX, United States
Abstract:
A significant fraction of the magma that is added from the mantle to the subvolcanic plumbing system ultimately erupts at the surface. The initial volatile content of the magmas as well as the interplay between volatile loss and magma ascent plays a significant role in determining the eruption style (effusive versus explosive) as well as the magnitude of the eruption.

The October 17, 1974 sub-Plinian eruption of Volcán de Fuego represents a particularly well-characterized system in terms of volatile content and magma chemistry to investigate the relation between initial water content of the magmas and the ascent rate. By modeling volatile element distribution in melt embayments through diffusion and degassing during ascent we can estimate magma ascent from the storage region in the crust to the surface. The novel aspect is the measurement of concentration gradients multiple volatile elements (in particular CO2, H2O, S) at fine-scale (5–10 μm) using the NanoSIMS. The wide range in diffusivity and solubility of these different volatiles provides multiple constraints on ascent timescales over a range of depths. H2O, CO2, and S all decrease toward the embayment outlet bubble documenting the loss of H2O and CO2 compared to an extensive melt inclusion suite from the same day of the eruption.

The data is best described by a two-stage model. At high pressure (>145 MPa) decompression is slow (0.05– 0.3 MPa/s) and CO2 is bled off predominantly. At shallow levels decompression accelerates to 0.3–0.5 MPa/s at the point of H2O exsolution, which strongly affects the buoyancy of the ascending magma. The magma ascent rates presented are among the first for explosive basaltic eruptions and demonstrate the potential of the embayment method for quantifying magmatic timescales associated with eruptions of different vigor.

[1] Lloyd et al. (2014) JVGR, http://dx.doi.org/10.1016/j.jvolgeores.2014.06.002