4.5 Article

Structure of basaltic glass at pressures up to 18 GPa

Journal

AMERICAN MINERALOGIST
Volume 107, Issue 3, Pages 325-335

Publisher

MINERALOGICAL SOC AMER
DOI: 10.2138/am-2021-7742

Keywords

Glass structure; permanent densification; high pressure; X-ray diffraction; neutron diffraction; Physics and Chemistry of Earth's Deep Mantle and Core

Funding

  1. JSPS KAKENHI [JP15H05828, JP16K13901, JP19H01985, JP19K21890, JP17H04860, JP17K18797]
  2. J-PARC [2017A0012, 2017B0061]

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The structures of cold-compressed basaltic glass were investigated at high pressures, revealing the compression behavior and oxygen packing mechanism. Furthermore, it was found that modified silicate glasses show different compression behaviors compared to silica glasses.
The structures of cold-compressed basaltic glass were investigated at pressures up to 18 GPa using in situ X-ray and neutron diffraction techniques to understand the physicochemical properties of deep magmas. On compression, basaltic glass changes its compression behavior: the mean O-O coordination number (CNOO) starts to rise while maintaining the mean O-O distance (r(OO)) above about 2-4 GPa, and then CNOO stops increasing, and r(OO) begins to shrink along with the increase in the mean coordination number of Al (CNAlO) above similar to 9 GPa. The change around 9 GPa is interpreted by the change in contraction mechanism from bending tetrahedral networks of glass to increasing oxygen packing ratio via the increase in CNAlO. The analysis of the oxygen packing fraction (eta(O)) under high pressure reveals that eta(O) exceeds the value for dense random packing, suggesting that the oxygen-packing hypothesis recently proposed cannot account for pressure-induced structural transformations of silica and silicate glasses. The rise of the CNOO at 2-4 GPa reflects the elastic softening of fourfold-coordinated silicate glass, which may be the origin of anomalies of elastic moduli in basaltic glass at similar to 2 GPa previously reported by Liu and Lin (2014). The widths of both the first sharp diffraction peak and the principal peak show contrastive compression behaviors between modified silicate and silica glasses. This result suggests that modified silicate glasses represent different pressure evolutions in the intermediate- and extended-range order structures from those of silica glass, likely due to the presence of modifier cations and the resultant formations of smaller rings and cavity volume.

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