Ultrahigh‐Pressure Phase Transitions in FeS<sub>2</sub> and FeO<sub>2</sub>: Implications for Super‐Earths' Deep Interior

Huang, Shengxuan; Wu, Xiang; Qin, Shan

doi:10.1002/2017jb014766

Cited by 10 publications

(9 citation statements)

References 53 publications

(116 reference statements)

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“…To further elucidate the oxidation states of cations, we have calculated the charge transfer of AO 2 compounds with various structural types as well as Fm 3̅ m AO compounds based on Bader analysis (Table S5). ,,,, The calculated charge of Fe and O in FeO 2 is +1.46 and −0.73, respectively, which is in agreement with recent PBE + U and hybrid functional simulations. , The charge of Cr in CrO 2 is predicted to be +1.94, 32.9% larger than that of Fe in FeO 2 . The charge of Mn in MnO 2 is comparable to that of Cr, being +1.92 to +1.96.…”

Section: Resultssupporting

confidence: 85%

Magnetism-Vanishing Stabilizes the Pyrite-Type 3d Transition Metal Peroxides at High Pressures

Huang

Hou

et al. 2020

J. Phys. Chem. C

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Extensive AO 2 -type transition metal (TM) oxides are experimentally determined or theoretically predicted to adopt the pyrite-type (Pa3̅ ) structure at different pressures, but their physical and chemical properties are largely unknown. Our theoretical calculations demonstrate that the interpolyhedral O−O bond is formed in pyrite-type CoO 2 with low-spin Co 2+ similar to the case of FeO 2 , whereas ferromagnetic CrO 2 and antiferromagnetic MnO 2 belong to dioxides with separate O 2− anions. The oxidation state of the cation and the potential formation of O−O bonding are affected by the crystal-field splitting, charge transfer between the cation and the anion, but primarily by the magnetic coupling among 3d electrons in a pyrite-type 3d TMO 2 . The spin crossover-induced magnetism-vanishing at high pressures contributes to a smaller cell volume and a weaker electronic correlation, facilitating the formation of an O−O bond and a reduction of the oxidation state of the cation. These results provide critical physical insights into the formation mechanism of 3d TM peroxides with O 2 2− dimers. Based on this conclusion, we have further theoretically predicted the formation of the hydrogen-bearing cobalt peroxide at high pressures. This shows another example for exploring the nature of hydrogen-bearing TM peroxides and sheds light on synthesizing novel TM peroxide materials under high pressure.

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Section: Resultssupporting

confidence: 85%

Magnetism-Vanishing Stabilizes the Pyrite-Type 3d Transition Metal Peroxides at High Pressures

Huang

Hou

et al. 2020

J. Phys. Chem. C

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“…In terms of FeO 2 in the recent study, we have predicted a transition sequence of pyrite-R 3m-I4/mmm at high pressures, different from present calculated results. 53 And the stable region of the R 3m FeO 2 has a span of $1200 GPa whereas the R 3m CrO 2 is energetically unfavorable in the present calculated pressure range. Therefore, this can serve as an indirect evidence that the chemical valence of iron cation is not +4 in FeO 2 under ultra-high pressure.…”

Section: Comparison With Other Ao 2 Compoundsmentioning

confidence: 57%

Structural, magnetic and electronic properties of CrO₂ at multimegabar pressures

Huang

Niu

et al. 2018

RSC Adv.

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“…For example, below 40 GPa, Py-FeO 2 starts to degas oxygen and reverts to Fe 2 O 3 . While the thermodynamic phase stability fields for Fe 2 O 3 − and FeO 2 ,, have been extensively investigated, the general structure modification mechanism involving stoichiometric variation remains elusive. The kinetics in the oxygenation reaction is fundamentally important to understand how they are stabilized at high pressure.…”

Section: Introductionmentioning

confidence: 99%

Structure-Controlled Oxygen Concentration in Fe₂O₃ and FeO₂

Zhu

Liu

et al. 2018

Inorg. Chem.

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Solid–solid reaction, particularly in the Fe–O binary system, has been extensively studied in the past decades because of its various applications in chemistry and materials and earth sciences. The recently synthesized pyrite-FeO2 at high pressure suggested a novel oxygen-rich stoichiometry that extends the achievable O–Fe ratio in iron oxides by 33%. Although FeO2 was synthesized from Fe2O3 and O2, the underlying solid reaction mechanism remains unclear. Herein, combining in situ X-ray diffraction experiments and first-principles calculations, we identified that two competing phase transitions starting from Fe2O3: (1) without O2, perovskite-Fe2O3 transits to the post-perovskite structure above 50 GPa; (2) if free oxygen is present, O diffuses into the perovskite-type lattice of Fe2O3 leading to the pyrite-type FeO2 phase. We found the O–O bonds in FeO2 are formed by the insertion of oxygen into the Pv lattice via the external stress and such O–O bonding is only kinetically stable under high pressure. This may provide a general mechanism of adding extra oxygen to previous known O saturated oxides to produce unconventional stoichiometries. Our results also shed light on how O is enriched in mantle minerals under pressure.

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Ultrahigh‐Pressure Phase Transitions in FeS₂ and FeO₂: Implications for Super‐Earths' Deep Interior

Cited by 10 publications

References 53 publications

Magnetism-Vanishing Stabilizes the Pyrite-Type 3d Transition Metal Peroxides at High Pressures

Magnetism-Vanishing Stabilizes the Pyrite-Type 3d Transition Metal Peroxides at High Pressures

Structural, magnetic and electronic properties of CrO₂ at multimegabar pressures

Structure-Controlled Oxygen Concentration in Fe₂O₃ and FeO₂

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Ultrahigh‐Pressure Phase Transitions in FeS2 and FeO2: Implications for Super‐Earths' Deep Interior

Cited by 10 publications

References 53 publications

Magnetism-Vanishing Stabilizes the Pyrite-Type 3d Transition Metal Peroxides at High Pressures

Magnetism-Vanishing Stabilizes the Pyrite-Type 3d Transition Metal Peroxides at High Pressures

Structural, magnetic and electronic properties of CrO2 at multimegabar pressures

Structure-Controlled Oxygen Concentration in Fe2O3 and FeO2

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Ultrahigh‐Pressure Phase Transitions in FeS₂ and FeO₂: Implications for Super‐Earths' Deep Interior

Structural, magnetic and electronic properties of CrO₂ at multimegabar pressures

Structure-Controlled Oxygen Concentration in Fe₂O₃ and FeO₂