Fe-Mg Partitioning between Olivine and High-magnesian Melts and the Nature of Hawaiian Parental Liquids

We conducted 1 atm experiments on a synthetic Hawaiian picrite at f O-2 values ranging from the quartz-fayalite-magnetite (QFM) buffer to air and temperatures ranging from 1302 to 1600 degrees C. Along the QFM buffer, olivine is the liquidus phase at similar to 1540 degrees C and small amounts of spinel (< 0 center dot 2 wt %) are present in experiments conducted at and below 1350 degrees C. The olivine becomes progressively more ferrous with decreasing temperature [Fo(92 center dot 3) to Fo(87 center dot 3), where Fo = 100 x Mg/(Mg + Fe), atomic]; compositions of coexisting liquids reflect the mode and composition of the olivine with concentrations of SiO2, TiO2, Al2O3, and CaO increasing monotonically with decreasing temperature, those of NiO and MgO decreasing, and FeO* (all Fe as FeO) remaining roughly constant. An empirical relationship based on our data, T(degrees C) = 19 center dot 2 x (MgO in liquid, wt %) + 1048, provides a semi-quantitative geothermometer applicable to a range of Hawaiian magma compositions. The olivine-liquid exchange coefficient, = (FeO/MgO)(ol)/(FeO/MgO)(liq), is 0 center dot 345 +/- 0 center dot 009 (1 Sigma ) for our 11 experiments. A literature database of 446 1 atm experiments conducted within 0 center dot 25 log units of the QFM buffer (QFM +/- 0 center dot 25) yields a median of 0 center dot 34; values from single experiments range from 0 center dot 41 to 0 center dot 13 and are correlated with SiO2 and alkalis in the liquid, as well as the forsterite (Fo) content of the olivine. For 78 experiments with broadly tholeiitic liquid compositions (46-52 wt % SiO2 and 3 wt % Na2O + K2O) coexisting with Fo(92-80) olivines, and run near QFM (QFM +/- 0 center dot 25), is approximately independent of composition with a median value of 0 center dot 340 +/- 0 center dot 012 (error is the mean absolute deviation of the 78 olivine-glass pairs from the database that meet these compositional criteria), a value close to the mean value of 0 center dot 343 +/- 0 center dot 008 from our QFM experiments. Thus, over the composition range encompassed by Hawaiian tholeiitic lavas and their parental melts, similar to 0 center dot 34 and, given the redox conditions and a Fo content for the most magnesian olivine phenocrysts, a parental melt composition can be reconstructed. The calculated compositions of the parental melts are sensitive to the input parameters, decreasing by similar to 1 wt % MgO for every log unit increase in the selected f O-2, every 0 center dot 5 decrease in the Fo-number of the target olivine, and every 0 center dot 015 decrease in. For plausible ranges in redox conditions and Fo-number of the most MgO-rich olivine phenocrysts, the parental liquids for Hawaiian tholeiites are highly magnesian, in the range of 19-21 wt % MgO for Kilauea, Mauna Loa and Mauna Kea.