Novel phases in the Fe-Si-O system at terapascal pressures
Authors
Nan Huang, Renata M. Wentzcovitch, Zepeng Wu, Feng Zheng, Bingxin Wu, Yang Sun, Shunqing Wu
Categories
Abstract
The Fe-Si-O ternary system, central to modeling the interiors of terrestrial planets, remains poorly constrained at Terapascal (TPa) pressures characteristic of super-Earth mantles. Using a combination of crystal-structure prediction and ab initio calculations, we identify three ternary compounds stable near 1 TPa: P3 FeSiO4, P3 Fe4Si5O18, and P-3 FeSi2O6. The first two phases are thermodynamically stable at low temperatures, whereas P-3 FeSi2O6 becomes favored above approximately 2000 K. All three are metallic, paramagnetic, and adopt pseudo-binary arrangements derived from the FeO2 and SiO2 end-member structures. Their crystal structures emerge through substitutions of Fe for Si in Fe2P-type SiO2 or of Si for Fe in Pnma-type FeO2, the stable elemental oxides at ~1 TPa. This structural continuity suggests that Fe preferentially substitutes for Si in the canonical Mg-silicates expected at TPa pressures. Notably, these new pseudo-binaries accommodate Fe in six- and nine-fold coordination, in contrast to the eight-fold cubic coordination found in FeO at similar pressures. The thermodynamic conditions under which these phases form from FeO2 and SiO2 mixtures are clarified through quasi-harmonic free energy calculations. Their prevalence in super-Earth's mantles is found to depend on the abundance of FeO2, which may be generated by the dehydrogenation of FeOOH goethite as in the Earth's deep mantle. The existence of these phases implies a markedly different pattern of Fe incorporation in high-pressure Mg-silicates at TPa pressures, compared with the behavior inferred at the GPa pressures of the Earth's mantle.
Novel phases in the Fe-Si-O system at terapascal pressures
Categories
Abstract
The Fe-Si-O ternary system, central to modeling the interiors of terrestrial planets, remains poorly constrained at Terapascal (TPa) pressures characteristic of super-Earth mantles. Using a combination of crystal-structure prediction and ab initio calculations, we identify three ternary compounds stable near 1 TPa: P3 FeSiO4, P3 Fe4Si5O18, and P-3 FeSi2O6. The first two phases are thermodynamically stable at low temperatures, whereas P-3 FeSi2O6 becomes favored above approximately 2000 K. All three are metallic, paramagnetic, and adopt pseudo-binary arrangements derived from the FeO2 and SiO2 end-member structures. Their crystal structures emerge through substitutions of Fe for Si in Fe2P-type SiO2 or of Si for Fe in Pnma-type FeO2, the stable elemental oxides at ~1 TPa. This structural continuity suggests that Fe preferentially substitutes for Si in the canonical Mg-silicates expected at TPa pressures. Notably, these new pseudo-binaries accommodate Fe in six- and nine-fold coordination, in contrast to the eight-fold cubic coordination found in FeO at similar pressures. The thermodynamic conditions under which these phases form from FeO2 and SiO2 mixtures are clarified through quasi-harmonic free energy calculations. Their prevalence in super-Earth's mantles is found to depend on the abundance of FeO2, which may be generated by the dehydrogenation of FeOOH goethite as in the Earth's deep mantle. The existence of these phases implies a markedly different pattern of Fe incorporation in high-pressure Mg-silicates at TPa pressures, compared with the behavior inferred at the GPa pressures of the Earth's mantle.
Authors
Nan Huang, Renata M. Wentzcovitch, Zepeng Wu et al. (+4 more)
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