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Metasomatism in mantle xenoliths from the Letlhakane kimberlites: estimation of element fluxes 总被引:1,自引:3,他引:1
Esmé van Achterbergh William L. Griffin Johann Stiefenhofer 《Contributions to Mineralogy and Petrology》2001,141(4):397-414
A suite of metasomatised xenoliths from the Letlhakane kimberlite (Botswana) forms a metasomatic sequence from garnet peridotite to garnet phlogopite peridotite to phlogopite peridotite. Before the modal metasomatism, most of the Letlhakane xenoliths were depleted harzburgites that had been subjected to an earlier cryptic metasomatic event. Modal phlogopite and clinopyroxene - Cr-spinel increase at the expense of garnet and orthopyroxene with increasing degrees of metasomatism. The most metasomatised xenolith is a wehrlite. With progressive modal metasomatism, the clinopyroxene becomes enriched in Sr, Sc and the LREE, orthopyroxene becomes depleted in Ca and Ni, but enriched in Al and Mn, and olivine becomes depleted in Al and V. Garnet chemical composition largely remains unchanged. The garnet replacement reaction seen in most xenoliths allows the measurement of the flux of trace elements through detailed modal analysis of the pseudomorphs. Mass balance calculations show that the modally metasomatised rocks became enriched in incompatible elements such as Sr, Na, K, the LREE and the HFSE (Ti, Zr and Nb). Major elements (Al, Cr and Fe) and garnet-compatible trace elements (V, Y, Sc, and the HREE) were removed during this metasomatic process. The modal metasomatism caused a strong depletion in Al, and the results challenge previous suggestions that this metasomatic process merely occurred within an Al-poor environment. The data suggest that the xenoliths represent the mantle wallrock adjacent to a major conduit for an alkaline basic silicate melt (with high contents of volatile and incompatible elements). The volatile and incompatible element-enriched component of this melt percolated into the wallrock along a strong temperature gradient and caused the observed range of metasomatism. 相似文献
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Esmé?M.?SpicerEmail author Gary?Stevens Ian?S.?Buick 《Contributions to Mineralogy and Petrology》2004,148(2):160-179
This study has examined the ~300 MPa partial melting behaviour of four metapelites collected from the highest grade rocks occurring below the anatectic zone of the Mt. Stafford area, Arunta Inlier, central Australia. In this area, metasediments are interpreted to have undergone partial melting within the andalusite stability field; possibly as a result of a lowering of the metapelite solidus by the presence of boron in the rocks. Two of the samples were two mica metapelites (MTS70 and MTS71). These both contained significant quantities of tourmaline and were thus boron enriched. The other two samples are biotite metapelites. One of these rocks contains only a trace of tourmaline (MTS8) and the other is tourmaline free (MTS7). Despite expectations that muscovite in the two mica samples would break down via a subsolidus reaction, muscovite was stable to above 750°C due to the incorporation of Ti, phengitic and possibly F components into its structure. Between 750 and 800°C, muscovite melted out completely via a coupled muscovite + biotite fluid-absent incongruent reaction. Tourmaline was partially consumed in this reaction, with the elbaitic component being preferentially consumed. In the most mica-rich sample this reaction produced ~60% melt at 800°C. In the biotite metapelites, biotite melting began at a temperature below 800°C and was accompanied by very modest melt production at this low temperature. In contrast to the two mica metapelites, the main pulse of melt production in these samples occurred at a temperature between 850 and 950°C. In both these samples biotite + melt coexisted over a temperature range in excess of 150°C, and in MTS8, biotite was still in the run products at 950°C. The very refractory nature of these evolved biotite compositions is most likely a consequence of both the presence of a Ti buffering phase in the assemblage (ilmenite) and the essentially plagioclase-free nature of the starting compositions. Under the fluid-absent conditions of this study, tourmaline is clearly a reactant in the partial melting process, but does not appear to shift the fluid-absent incongruent melting reactions markedly. In the tourmaline-rich two mica metapelites, tourmaline only disappears from the run products at a temperature above 850°C, where it coexisted with a substantial melt proportion. This appears to coincide with the point of maximum boron concentration in the melts.
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