Effect of oxygen fugacity on the storage of water in wadsleyite and olivine in H and H-C fluids and implications for melting atop the transition zone

This study aims to experimentally constrain the water storage capacities of olivine and wadsleyite at a depth near 410 km (12-14 GPa) under water-saturated conditions, as a function of temperature, oxygen fugacity, and the presence of carbon (molar H/C of 2). Experiments have been conducted in the multi-anvil press, with sealed double capsules to preserve fluids, at 1200 to 1400 degrees C and three different oxygen fugacities fixed at the rhenium-rhenium oxide buffer (RRO), nickel-nickel oxide buffer (NNO), and iron-wustite (IW) for oxidizing, intermediate, and reducing conditions, respectively. The water contents of minerals were measured by Raman spectroscopy that allows a very small beam size to be used and were cross-checked on a few samples with NanoSIMS analyses. We observe an effect, although slight, of f(O2) on the water storage capacity of both wadsleyite and olivine and also on their solidus temperatures. At 1200 degrees C, the storage capacity of the nominally anhydrous minerals (NAMS) increases with increasing oxygen fugacity (from the IW to the RRO buffer) from 1 wt% to 1.5 wt% H2O in wadsleyite and from 0.1 wt% to 0.2 wt% in olivine, owing to the increase in H2O/H-2 speciation in the fluid, whereas at 1400 degrees C the storage capacity decreases from 1 wt% to 0.75 wt% H2O in wadsleyite and down to 0.03 wt% for olivine. At high temperature, the water storage capacity is lowered due to melting, and the more oxidized the conditions are the more the solidus is depressed. Still, at 1400 degrees C and IW, wadsleyite can store substantial amounts of water: 0.8 wt% to 1 wt% H2O. The effect of carbon is to decrease water storage capacity in both wadsleyite and olivine by an average factor 2 at 1300-1400 degrees C. The trends in water storage as a function of f(O2) and C presence are confirmed by NanoSIMS measurements. The solidus at IW without C is located between 1300 and 1400 degrees C in the wadsleyite stability field and drops to temperatures below 1300 degrees C in the olivine stability field. With the addition of C, the solidus is found between 1200 and 1300 degrees C in both olivine and wadsleyite stability fields.