TY - JOUR
T1 - Gas-driven filter pressing in magmas
T2 - insights into in-situ melt segregation from crystal mushes
AU - Pistone, Mattia
AU - Arzilli, Fabio
AU - Dobson, Katherine J.
AU - Cordonnier, Benoît
AU - Reusser, Eric
AU - Ulmer, Peter
AU - Marone, Federica
AU - Whittington, Alan G.
AU - Mancini, Lucia
AU - Fife, Julie L.
AU - Blundy, Jonathan D.
PY - 2015/8/1
Y1 - 2015/8/1
N2 - Gas-driven filter pressing is the process of melt expulsion from a volatile-saturated crystal mush, induced by the buildup and subsequent release of gas pressure. Filter pressing is inferred to play a major role in magma fractionation at shallow depths (<10 km) by moving melt and gas relative to the solid, crystalline framework. However, the magmatic conditions at which this process operates remain poorly constrained. We present novel experimental data that illustrate how the crystal content of the mush affects the ability of gas-driven filter pressing to segregate melt. Hydrous haplogranite (2.1 wt% water in the melt) and dacite (4.2 wt% water in the melt) crystal mushes, with a wide range of crystallinities (34-80 vol% crystals), were investigated using in-situ, hightemperature (500-800 °C) synchrotron X-ray tomographic microscopy with high spatial (3 μm/pixel) and temporal resolution (~8 s per threedimensional data set). Our experimental results show that gas-driven filter pressing operates only below the maximum packing of bubbles and crystals (~74 vol%). Above this threshold, the mush tends to fracture and gas escapes via fractures. Therefore, the efficiency of gas-driven filter pressing is promoted close to the percolation threshold and in situations where a mush inflates slowly relative to build-up of pressure and expulsion of melt. Such observations offer a likely explanation for the production of eruptible, crystal-poor magmas within Earth's crust.
AB - Gas-driven filter pressing is the process of melt expulsion from a volatile-saturated crystal mush, induced by the buildup and subsequent release of gas pressure. Filter pressing is inferred to play a major role in magma fractionation at shallow depths (<10 km) by moving melt and gas relative to the solid, crystalline framework. However, the magmatic conditions at which this process operates remain poorly constrained. We present novel experimental data that illustrate how the crystal content of the mush affects the ability of gas-driven filter pressing to segregate melt. Hydrous haplogranite (2.1 wt% water in the melt) and dacite (4.2 wt% water in the melt) crystal mushes, with a wide range of crystallinities (34-80 vol% crystals), were investigated using in-situ, hightemperature (500-800 °C) synchrotron X-ray tomographic microscopy with high spatial (3 μm/pixel) and temporal resolution (~8 s per threedimensional data set). Our experimental results show that gas-driven filter pressing operates only below the maximum packing of bubbles and crystals (~74 vol%). Above this threshold, the mush tends to fracture and gas escapes via fractures. Therefore, the efficiency of gas-driven filter pressing is promoted close to the percolation threshold and in situations where a mush inflates slowly relative to build-up of pressure and expulsion of melt. Such observations offer a likely explanation for the production of eruptible, crystal-poor magmas within Earth's crust.
KW - gas-driven filter pressing
KW - melt expulsion
KW - crystal content
KW - crystalline framework
UR - http://www.scopus.com/inward/record.url?scp=84942234361&partnerID=8YFLogxK
U2 - 10.1130/G36766.1
DO - 10.1130/G36766.1
M3 - Article
AN - SCOPUS:84942234361
SN - 0091-7613
VL - 43
SP - 699
EP - 702
JO - Geology
JF - Geology
IS - 8
ER -