Abstract
Experimentally, silica activity (aSiO2) has been shown to have an effect on Mg diffusion in forsterite, but no fully satisfactory mechanism has yet been proposed. We calculated the effects of aSiO2 and aluminium content (the main contaminant in some recent experimental studies), and their co-effect, on Mg diffusion in forsterite, using thermodynamic minimisations of defect formation energies [calculated using density functional theory (DFT)] and a Monte-Carlo diffusion model. These two variables, in isolation, do not appreciably change the defect concentrations of forsterite and thus do not affect the diffusivity of Mg. However, when elevated together, they cause large increases in the Mg vacancy content and thus can increase the Mg diffusivity by one to six orders of magnitude depending on temperature, with little pressure dependence. This effect is largely independent of Al2O3 concentration above ~ 1 wt. ppm, and thus, for all practical purposes, should occur wherever forsterite is in the presence of enstatite. It is also largely dependent upon configurational entropy and is thus highly sensitive to the chemistry of the crystal. A low concentration of structurally bound hydroxyl groups at low temperatures (1000 K) suppresses this effect in pure forsterite, but it is likely robust in the presence of water either when alternative water sinks (such as Ti or Fe) are present, or at high temperatures (> 1500 K). This effect is also robust in the presence of ferrous iron (or other substitutional Mg defects) at all temperatures. Fe2O3 can operate like Al2O3 in this reaction and should enhance its effect. These findings explain the experimentally observed dependency of Mg diffusion of aSiO2, and elucidate how chemical activity variations in both experiments and natural settings could affect not only the diffusivity of Mg in forsterite, but of olivine-hosted cations in general.
Highlights
Understanding Mg diffusion in olivine is important for considerations of various geochemical transport processes including electrical conductivity (Fei et al 2018), rheology (Jaoul 1990) and resolving the timescales of volcanic process (Costa et al 2008), as well as for the understanding of point defect chemistry in silicates in general (Dohmen and Chakraborty 2007; Nakamura and Schmalzried 1983)
We have shown that the presence of enstatite, which can be generalized to an increase in a SiO2, in the presence of aluminium causes a large increase in anisotropic Mg diffusivity in forsterite that is highly temperature dependent
Recent experimental results have shown that the chemical environment of forsterite—in particular a SiO2—can affect its diffusional characteristics
Summary
Understanding Mg diffusion in olivine is important for considerations of various geochemical transport processes including electrical conductivity (Fei et al 2018), rheology (Jaoul 1990) and resolving the timescales of volcanic process (Costa et al 2008), as well as for the understanding of point defect chemistry in silicates in general (Dohmen and Chakraborty 2007; Nakamura and Schmalzried 1983). Forsterite, the magnesian end member of olivine (Mg2SiO4), can exist in the pure Mg-Si–O system along with either periclase (MgO) or enstatite (MgSiO3) Whilst it has been understood for several decades that the buffering assemblage, and the silica activity, affects various properties of olivine such as its rheology (Bai et al 1991; Ricoult and Kohlstedt 1985), trace element incorporation [e.g. H (Matveev et al 2001)] and its point defect population (Nakamura and Schmalzried, 1983; Stocker and Smyth, 1978), the extent to which aSiO2 affects. Zhukova et al (2014)) to link the experimentally observed aSiO2—diffusivity relationship to the point defect population of forsterite have relied on the papers of Stocker and Smyth (1978), Pluschkell and Engell (1968), Smyth and Stocker (1975) These studies calculated the charge balance conditions of a set of defectproducing reactions, based on how variations of the defect concentrations would affect the equilibrium conditions. It was assumed that changing aSiO2 causes a change in Mg vacancy concentration that can be described by a simple exponent, which is unlikely when considering all of the Mg vacancies that are formed by all the defect reactions together
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