Experimental study of platinum solubility in silicate melt to 14GPa and 2273K: Implications for accretion and core formation in Earth

Ertel, W.; Walter, Michael J.; Drake, M. J.; Sylvester, Paul J.

doi:10.1016/j.gca.2006.02.015

Cited by 62 publications

(57 citation statements)

References 38 publications

(52 reference statements)

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“…Nevertheless, the large apparent range of partition coefficients for HSEs, even at the elevated temperatures accompanying higher pressures in larger bodies (9)(10)(11), is not consistent with the chondritic (i.e. primitive solar system) patterns of HSEs in both the terrestrial and martian mantles, and the similarities in absolute abundances between the two bodies (12).…”

mentioning

confidence: 82%

Late Accretion on the Earliest Planetesimals Revealed by the Highly Siderophile Elements

Dale

Burton

Greenwood

et al. 2012

Science

121

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. (2012) 'Late accretion on the earliest planetesimals revealed by the highly siderophile elements. ', Science., Further information on publisher's website: Use policyThe full-text may be used and/or reproduced, and given to third parties in any format or medium, without prior permission or charge, for personal research or study, educational, or not-for-prot purposes provided that:• a full bibliographic reference is made to the original source • a link is made to the metadata record in DRO • the full-text is not changed in any way The full-text must not be sold in any format or medium without the formal permission of the copyright holders.Please consult the full DRO policy for further details.

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mentioning

confidence: 82%

Late Accretion on the Earliest Planetesimals Revealed by the Highly Siderophile Elements

Dale

Burton

Greenwood

et al. 2012

Science

121

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“…In addition to the presence of large metal and sulfide globules, some experiments (especially in IHPV) show abundant submicrometric globules of metallic melt homogeneously distributed in the silicate melt. We interpret these small globules as the result of inefficient coarsening of the metal globules (Ertel et al, 2006;Malavergne et al, 2016). …”

Section: Phase Assemblages and Microstructuresmentioning

confidence: 95%

Sulfur solubility in reduced mafic silicate melts: Implications for the speciation and distribution of sulfur on Mercury

Namur

Charlier

Holtz

et al. 2016

Earth and Planetary Science Letters

112

160

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Chemical data from the MESSENGER spacecraft revealed that surface rocks on Mercury are unusually enriched in sulfur compared to samples from other terrestrial planets. In order to understand the speciation and distribution of sulfur on Mercury, we performed high temperature (1200-1750 • C), lowto high-pressure (1 bar to 4 GPa) experiments on compositions representative of Mercurian lavas and on the silicate composition of an enstatite chondrite. We equilibrated silicate melts with sulfide and metallic melts under highly reducing conditions (IW-1.5 to IW-9.4; IW = iron-wüstite oxygen fugacity buffer). Under these oxygen fugacity conditions, sulfur dissolves in the silicate melt as S 2− and forms complexes with Fe 2+ , Mg 2+ and Ca 2+ . The sulfur concentration in silicate melts at sulfide saturation (SCSS) increases with increasing reducing conditions (from <1 wt.% S at IW-2 to >10 wt.% S at IW-8) and with increasing temperature. Metallic melts have a low sulfur content which decreases from 3 wt.% at IW-2 to 0 wt.% at IW-9. We developed an empirical parameterization to predict SCSS in Mercurian magmas as a function of oxygen fugacity ( f O 2 ), temperature, pressure and silicate melt composition. SCSS being not strictly a redox reaction, our expression is fully valid for magmatic systems containing a metal phase. Using physical constraints of the Mercurian mantle and magmas as well as our experimental results, we suggest that basalts on Mercury were free of sulfide globules when they erupted. The high sulfur contents revealed by MESSENGER result from the high sulfur solubility in silicate melt at reducing conditions. We make the realistic assumption that the oxygen fugacity of mantle rocks was set during equilibration of the magma ocean with the core and/or that the mantle contains a minor metal phase and combine our parameterization of SCSS with chemical data from MESSENGER to constrain the oxygen fugacity of Mercury's interior to IW-5.4 ± 0.4. We also calculate that the mantle of Mercury contains 7-11 wt.% S and that the metallic core of the planet has little sulfur (<1.5 wt.% S). The external part of the Mercurian core is likely to be made up of a thin (<90 km) FeS layer.

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“…If this is true, it may lead to important implications for the gold budget of arc magmas rising up through the mantle wedge and the arc crust. A few other ore-forming metals (Mo, Pt, Te, Se,…) as well as sulfur have been previously studied to estimate the pressure effect on their solubility in silicate melts (e.g., Mavrogenes and O'Neill, 1999;Ertel et al, 2006;Rose-Weston et al, 2009;Burkemper and Agee, 2010), but all experiments were performed at much higher pressures, some of these studies aiming to constrain early Earth evolution and core-mantle differentiation. Here, we aim to evaluate the ability of the silicate melt to incorporate gold during partial melting of a deep source (upper mantle or lower crust), saturated with sulfide phases or not, and see how the initial gold budget of a primary melt will evolve during its adiabatic ascent through the arc crust.…”

Section: Introductionmentioning

confidence: 99%

Is gold solubility subject to pressure variations in ascending arc magmas?

Jégo

Nakamura

Kimura

et al. 2016

Geochimica et Cosmochimica Acta

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Magmas play a key role in the genesis of epithermal and porphyry ore deposits, notably by providing the bulk of ore metals to the hydrothermal fluid phase. It has been long shown that the formation of major deposits requires a multi-stage process, including the concentration of metals in silicate melts at depth and their transfer into the exsolved ore fluid in more superficial environments. Both aspects have been intensively studied for most of noble metals in subsurface conditions, whereas the effect of pressure on the concentration (i.e., solubility) of those metals in magmas ascending from the sublithospheric mantle to the shallow arc crust has been quite neglected. Here, we present new experimental data aiming to constrain the processes of gold (Au) dissolution in subduction-linked magmas along a range of depth. We have conducted hydrous melting experiments on two dacitic/adakitic magmas at 0.9 and 1.4GPa and ~1000°C in an end-loaded piston cylinder apparatus, under fO 2 conditions close to NNO as measured by solid Co-Pd-O sensors. Experimental charges were carried out in pure Au containers, the latter serving as the source of gold, in presence of variable amounts of H 2 O and, for half of the charges, with elemental sulfur (S) so as to reach sulfide saturation. Au concentrations in melt quenched to glass were determined by LA-ICPMS. When compared to previous data obtained at lower pressures and variable redox conditions, our results show that in both S-free and sulfide-saturated systems pressure has no direct, detectable effect on melt Au solubility. Nevertheless, pressure has a strong, negative effect on sulfur solubility. Since gold dissolution is closely related to the behaviour of sulfur in reducing and moderately oxidizing conditions, pressure has therefore a significant but indirect effect on Au solubility.The present study confirms that Au dissolution is mainly controlled by fO 2 in S-free melts and 3 by a complex interplay of fO 2 and melt S 2-concentration in sulfide-saturated melts, at given temperature. In addition, we propose that the transition from sulfide (S 2-) to sulfate (S 6+ ) species in melt is shifted towards more oxidizing conditions when pressure and the degree of melt polymerization increase. If this is true, this may have important consequences during mantle melting and magma ascent. In particular, if mantle melting occurred in moderately oxidizing conditions, a small degree of partial melting would allow the primary melts to become Au-enriched but the relatively high pressure would move the sulfide-sulfate transition to more oxidizing conditions, making the primary melts saturated with sulfide phases that would sequester gold from the melt. During magma ascent, the decreasing pressure would favour the destabilization of sulfides and the release of gold to the silicate melt. However, at shallow levels, decreasing pressure, magma evolution, and varying redox conditions would be continuously competing to concentrate or fractionate gold.

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Experimental study of platinum solubility in silicate melt to 14GPa and 2273K: Implications for accretion and core formation in Earth

Cited by 62 publications

References 38 publications

Late Accretion on the Earliest Planetesimals Revealed by the Highly Siderophile Elements

Late Accretion on the Earliest Planetesimals Revealed by the Highly Siderophile Elements

Sulfur solubility in reduced mafic silicate melts: Implications for the speciation and distribution of sulfur on Mercury

Is gold solubility subject to pressure variations in ascending arc magmas?

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