Abstract
The Earth’s transition zone, at depths of 410–660 km, while being composed of nominally anhydrous magnesium silicate minerals, may be subject to significant hydration. Little is known about the mechanism of hydration, despite the vital role this plays in the physical and chemical properties of the mantle, leading to a need for improved structural characterization. Here we present an ab initio random structure searching (AIRSS) investigation of semihydrous (1.65 wt % H2O) and fully hydrous (3.3 wt % H2O) wadsleyite. Following the AIRSS process, k-means clustering was used to select sets of structures with duplicates removed, which were then subjected to further geometry optimization with tighter constraints prior to NMR calculations. Semihydrous models identify a ground-state structure (Mg3 vacancies, O1–H hydroxyls) that aligns with a number of previous experimental observations. However, predicted NMR parameters fail to reproduce low-intensity signals observed in solid-state NMR spectra. In contrast, the fully hydrous models produced by AIRSS, which enable both isolated and clustered defects, are able to explain observed NMR signals via just four low-enthalpy structures: (i) a ground state, with isolated Mg3 vacancies and O1–H hydroxyls; (ii/iii) edge-sharing Mg3 vacancies with O1–H and O3–H species; and (iv) edge-sharing Mg1 and Mg3 vacancies with O1–H, O3–H, and O4–H hydroxyls. Thus, the combination of advanced structure searching approaches and solid-state NMR spectroscopy is able to provide new and detailed insight into the structure of this important mantle mineral.
Highlights
The high-pressure silicate mineral wadsleyite, β-(Mg,Fe)2SiO4, is believed to be the predominant component of the Earth between depths of 410 and 520 km
The uncertainty regarding the positions of both H+ ions and the Mg2+ vacancies in hydrous wadsleyite introduces the potential for significant structural disorder, increasing the challenge associated with characterizing this system
Journal of the American Chemical Society we show how NMR crystallography,[7−9] through a combination of ab initio structure searching, k-means clustering, firstprinciples calculations, and solid-state NMR spectroscopy, provides unique insight into the detailed structure of this complex and important mineral
Summary
The high-pressure silicate mineral wadsleyite, β-(Mg,Fe)2SiO4, is believed to be the predominant component of the Earth between depths of 410 and 520 km. At pressures corresponding to depths below 660 km, γ-(Mg,Fe)2SiO4 breaks down to (Mg,Fe)SiO3, perovskite, and (Mg,Fe)O (Figure 1). Wadsleyite (shown in Figure 2a) can accommodate up to 3.3 wt % H2O,1−5 suggesting it could be acting as a vast “water” reservoir deep within the Earth, stimulating great interest from both chemists and geologists, leading to the concept of “hidden oceans” within the Earth.[6] Net hydration of wadsleyite is generally thought to be achieved via incorporation of hydrogen as H+, charge balanced by loss of 6-coordinate Mg2+ cations, where the maximum hydration level (3.3 wt % H2O) corresponds to the exchange of four H+ for two Mg2+ per unit cell. Given that wadsleyite has three crystallographically distinct Mg2+ cations, there is some ambiguity over the specific site(s) at which vacancies are created.
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