Fast diffusion along mobile grain boundaries in calcite

Andrew McCaig, Stephen J. Covey-Crump, Walid Ben Ismaïl, Geoffrey E. Lloyd

    Research output: Contribution to journalArticlepeer-review

    Abstract

    Experimental measurements of grain boundary diffusion are usually conducted on static boundaries, despite the fact that grain boundaries deep in the Earth are frequently mobile. In order to explore the possible effect of boundary mobility on grain boundary diffusion rates we have measured the uptake of 44Ca from a layer of 44Ca-enriched calcite powder during the static recrystallization of a single crystal of calcite at 900°C. A region about 500μm wide adjacent to the powder layer is heterogeneously enriched in 44Ca, and complex zoning patterns, including sharp steps in composition and continuous increases and decreases in 44Ca content, are developed. In metamorphic rocks, these would normally be interpreted in terms of changes in pressure or temperature, Rayleigh fractionation, or episodic fluid infiltration. These explanations cannot apply to our experiments, and instead the zoning patterns are interpreted as being due to variations in grain boundary migration rate. We have applied an analytical model which allows the product of grain boundary diffusion coefficient and grain boundary width (DGBδ) to be calculated from the grain boundary migration rate and the compositional gradient away from the powder layer. The value of DGBδ in the mobile grain boundaries is at least five orders of magnitude greater than the published value for static boundaries under the same conditions. In order to allow the scale of chemical equilibrium (and hence textural evolution) to be predicted under both experimental and geological conditions, we present quantitative diffusion-regime maps for static and mobile boundaries in calcite, using both published values and our new values for grain boundary diffusion in mobile boundaries. Enhanced diffusion in mobile boundaries has wide implications for the high temperature rheology of Earth materials, for geochronology, and for interpretations of the length- and time-scales of chemical mass-transport. Moreover, zones of anomalously high electrical conductivity in the crust and mantle could be regions undergoing recrystallization such as active shear zones, rather than regions of anomalous mineralogy, water- or melt-content as is generally suggested. © Springer-Verlag 2006.
    Original languageEnglish
    Pages (from-to)159-175
    Number of pages16
    JournalContributions to Mineralogy and Petrology
    Volume153
    Issue number2
    DOIs
    Publication statusPublished - Feb 2007

    Keywords

    • DYNAMIC RECRYSTALLIZATION
    • SELF-DIFFUSION
    • MASS-TRANSPORT
    • PELITIC
    • GARNET
    • CARRARA MARBLE
    • TEMPERATURE
    • GROWTH
    • MIGRATION
    • MODEL
    • DISEQUILIBRIUM

    Fingerprint

    Dive into the research topics of 'Fast diffusion along mobile grain boundaries in calcite'. Together they form a unique fingerprint.

    Cite this