Structure and density of molten fayalite at high pressure

C. Sanloup, J.W.E. Drewitt, C. Crépisson, Y. Kono, C. Park, C. McCammon, L. Hennet, S. Brassamin, A. Bytchkov

Research output: Contribution to journalArticlepeer-review

Abstract / Description of output

The structure of molten fayalite was studied up to 7.5GPa by means of in situ energy-dispersive X-ray diffraction. The pressure-range studied covers the fayalite-spinel-liquid triple point at 6.2GPa. For pure molten fayalite, Fe-O coordination increases gradually from 4.8(2) at ambient pressure (P) to 7.2(3) at 7.5GPa. Compressibility of the melt is derived from the extrapolation of the structure factor to q=0Å, enabling the determination of density as a function of P with an unprecedented P-resolution. This is a promising method to extract the equation of state of non-crystalline materials at moderate P. The link between observed structural changes and density increase and the fact that structural changes occur over a broad but limited P-range in silicate melts implies that the equation of state should not be extrapolated at P-values higher than obtained in measurements, and that a single equation of state cannot accurately describe the density evolution over the whole terrestrial mantle P-temperature (T) range. Fe-rich melts are expected to have a higher densification rate than their Mg counterparts in the 0-10GPa range due to the increase of Fe-O coordination number. As a consequence, Fe-rich melts are more likely to be trapped at depth.
Original languageEnglish
Pages (from-to)118-128
Number of pages11
JournalGeochimica et Cosmochimica Acta
Volume118
DOIs
Publication statusPublished - 1 Oct 2013

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