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Titel |
A multi-component model for partial melting in presence of CO2 and other volatiles in the mantle. |
VerfasserIn |
Malcolm Massuyeau, Yann Morizet, Fabrice Gaillard |
Konferenz |
EGU General Assembly 2013
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Medientyp |
Artikel
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Sprache |
Englisch
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Digitales Dokument |
PDF |
Erschienen |
In: GRA - Volume 15 (2013) |
Datensatznummer |
250082532
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Zusammenfassung |
The link between volatiles and mantle melting has so far been illuminated by experiments
revealing punctually, at a given P-T condition and under a specific chemical system,
properties such as solubility laws, redox equiblibra, and phase equilibria. The aim we are
pursuing here is to establish a multi-component model describing the Gibbs free energy of
melt produced by mantle melting in presence of CO2-H2O: Carbonatite-carbonated melt and
basalts.
The generated low melt fractions are often dominated by carbonate-rich compositions,
whereas with increasing temperature, the melts evolve towards basaltic compositions.
However, the transition between carbonate-dominated and silicate-dominated melts is
complex and poorly constrained: it is characterized by a continuous evolution between a
carbonated melt and a silicated melt, or show, under specific conditions, immiscibility
between these two types of liquids. Several studies emphasize the role of alkalis in the
immiscibility between a carbonate-dominated melt and a silicate-dominated melt.
Consequently, we performed experiments in simplified systems to better understand the
influence of each (K and Na) on this immiscibility. In addition, specific experiments on more
complex compositions have been performed, in order to give first insights on the role of
various volatiles present in the melts: water, chlorine.
From a thermodynamic point of view, the carbonate-silicate transition is defined by the
activity of the component SiO2 in the liquid and is calculated from experimental data (2-10
GPa, 1100-1600Ë C) using crystal-liquid and liquid-liquid equilibria. This silicate-carbonate
immiscibility constitutes a powerful tool defining the mixing properties of the liquid. The
miscibility gap defines equilibrium melts with different compositions, but the melt
components are characterized by similar activities. This can be inverted to derive
activity-composition relationships that are strictly independent of standard state properties.
We will present a parameterization of the mixing properties allowing the complex
activity-composition relationships for multi-component carbonated melts to be accounted
for.
Graphite-liquid and fluid-liquid data allow, for the first time, to constrain the standard
state properties of CO2dissolved in liquid, and its activity.
Activity-composition relationships for CO2 are strongly non-ideal in carbonated melts,
but the presence of water apparently tends to minimize this non-ideality. We suggest that
water may have a role on the redox stability of C relative to CO32-, and consequently on the
distribution of graphite/diamond vs. carbonate species and on the onset of melting in
C-O-H-bearing mantle.
We propose several applications allowing the composition of incipient melts to be
calculated as a function of depth underneath Mid-Ocean-Ridges and underneath
Hot-Spots.
In the oceanic mantle, the top of the Lithosphere-Asthenosphere boundary is identified
by seismic data as a discontinuity at an average depth of 65 km. This observation
correlates with the onset of peridotite melting in presence of both H2O and CO2.
Therefore, partial melting must occur at 65 km, implying production of H2O-rich
carbonatitic melts as shown by our present model, and which are to the origin of the
weakening.
This thermodynamic study, supported by experimental investigation, constitutes an
essential step in modeling the distribution and fate of volatiles, especially carbon, in the
Earth’s mantle. |
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