Compression of Fe–Si–H alloys to core pressures

Tagawa, Shoh; Ohta, Kenji; Hirose, Kei; Kato, Chie; Ohishi, Yasuo

doi:10.1002/2016gl068848

Cited by 38 publications

(57 citation statements)

References 41 publications

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“…Experimental and theoretical studies of FeHx suggest that such an iron hydride can satisfy the density and sound velocity of the Earth's core (Hirao et al, 2004;Mao et al, 2004;Sakamaki et al, 2016;Shibazaki et al, 2012;Tagawa et al, 2016). A primary mechanism for including hydrogen into the Earth's core might be through reaction between iron and water during core formation.…”

Section: Geophysical Implicationsmentioning

confidence: 99%

Chemical Reactions Between Fe and H₂O up to Megabar Pressures and Implications for Water Storage in the Earth's Mantle and Core

Yuan,

Ohtani,

Ikuta

et al. 2018

Geophysical Research Letters

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We investigated the phase relations of the Fe‐H2O system at high pressures based on in situ X‐ray diffraction experiments and first‐principles calculations and demonstrate that FeHx and FeO are present at pressures less than ~78 GPa. A recently reported pyrite‐structured FeO2 was identified in the Fe‐H2O system at pressures greater than ~78 GPa after laser heating. The phase observed in this study has a unit cell volume 8%–11% larger than that of FeO2, produced in the Fe‐O binary system reported previously, suggesting that hydrogen might be retained in a FeO2Hx crystal structure. Our observations indicate that H2O is likely introduced into the deep Earth through reaction between iron and water during the accretion and separation of the metallic core. Additionally, reaction between Fe and H2O would occur at the core‐mantle boundary, given water released from hydrous subducting slabs that intersect with the metallic core. Accumulation of volatile‐bearing iron compounds may provide new insights into the enigmatic seismic structures observed at the base of the lower mantle.

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Section: Geophysical Implicationsmentioning

confidence: 99%

Chemical Reactions Between Fe and H₂O up to Megabar Pressures and Implications for Water Storage in the Earth's Mantle and Core

Yuan,

Ohtani,

Ikuta

et al. 2018

Geophysical Research Letters

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“…Isaev et al, 2007;Elsässer et al 1998;Pépin et al, 2014), melting temperature (e.g. Yagi and Hishinuma, 1995;Okuchi, 1998;Sakamaki et al, 2009;Shibazaki et al, 2011;, density and elastic properties (Caracas, 2015;Hirao et al, 2004;Mao et al, 2004;Pépin et al, 2014;Shibazaki et al, 2012;Tagawa et al, 2016;Umemoto and Hirose, 2015). The maximum abundance of hydrogen has been estimated to be 0.3  x  0.5 (in atomic ratio) for the Earth's core (Okuchi, 1997;Narygina et al, 2011;Umemoto and Hirose, 2015).…”

Section: Introductionmentioning

confidence: 99%

“…The maximum abundance of hydrogen has been estimated to be 0.3  x  0.5 (in atomic ratio) for the Earth's core (Okuchi, 1997;Narygina et al, 2011;Umemoto and Hirose, 2015). Furthermore, recent experimental study on hcp Fe-Si-H ternary alloys suggests that the abundance of alloying hydrogen is x = 0.17 (Tagawa et al, 2016). These results rely on our knowledge of non-stoichiometric phases such as FeH x .…”

Section: Introductionmentioning

confidence: 99%

The effects of ferromagnetism and interstitial hydrogen on the equation of states of hcp and dhcp FeHx: Implications for the Earth's inner core age

Gomi

Fei

Yoshino

2018

American Mineralogist

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Hydrogen has been considered as an important candidate of light elements in the Earth's core. Because iron hydrides are unquenchable, hydrogen content is usually estimated from in-situ X-ray diffraction measurements assuming the following linear relation: x = (V FeHx-V Fe) / V H , where x is the hydrogen content, V H is the volume expansion caused by unit concentration of hydrogen, V FeHx and V Fe are volumes of FeH x and pure iron, respectively. To verify the linear relationship, we computed the equation of states of hexagonal iron with interstitial hydrogen by using the Korringa-Kohn-Rostoker method with the coherent potential approximation (KKR-CPA). The results indicate a discontinuous volume change at the magnetic transition and almost no compositional (x) dependence in the ferromagnetic phase at 20 GPa, whereas the linearity is confirmed in the non-magnetic phase. In addition to their effects on density-composition relationship in the Fe-FeH x system, which is important for estimating the hydrogen incorporation in planetary cores, the magnetism and interstitial hydrogen also affect the electrical resistivity of FeH x. The thermal conductivity can be calculated from the electrical resistivity by using the Wiedemann-Franz law, which is a critical parameter for modeling the thermal evolution of the Earth. Assuming an Fe 1-y Si y H x ternary outer core model (0.0  x  0.7), we calculated the thermal conductivity and the age of the inner core. The resultant thermal conductivity is ~100 W/m/K and the maximum inner core age ranges from 0.49 to 0.86 Gyr.

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“…Therefore, reactions between iron and water are likely even at lower mantle conditions and the present study on FeOOH transformations is relevant for modeling these interactions at depth. Iron hydride FeH x indeed satisfies density and sound velocities constraints in the Earth's core (e.g., Tagawa et al, 2016). Pyrite-structured FeO 2 H x was indeed reported to result from the reaction of water with metallic iron Mao et al, 2017;Yuan et al, 2018), a reaction that may have taken place during core formation resulting in the delivery of hydrogen to the Earth's core (Yuan et al, 2018).…”

Section: Discussionmentioning

confidence: 87%

“…Pyrite-structured FeO 2 H x was indeed reported to result from the reaction of water with metallic iron Mao et al, 2017;Yuan et al, 2018), a reaction that may have taken place during core formation resulting in the delivery of hydrogen to the Earth's core (Yuan et al, 2018). Iron hydride FeH x indeed satisfies density and sound velocities constraints in the Earth's core (e.g., Tagawa et al, 2016). In addition, dehydration melting of transition zone materials swept down to the lower mantle by mantle convection or melting of dense hydrous magnesium phases in subducting slabs that are stagnating near 660-km seismic discontinuity could produce deep hydrous melts at the top of the lower mantle.…”

Section: 1029/2019gl081922mentioning

confidence: 97%

Ferrous Iron Under Oxygen‐Rich Conditions in the Deep Mantle

Boulard

Harmand

Guyot

et al. 2019

Geophysical Research Letters

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Recent experiments have demonstrated the existence of previously unknown iron oxides at high pressure and temperature including newly discovered pyrite‐type FeO2 and FeO2Hx phases stable at deep terrestrial lower mantle pressures and temperatures. In the present study, we probed the iron oxidation state in high‐pressure transformation products of Fe3+OOH goethite by in situ X‐ray absorption spectroscopy in laser‐heated diamond‐anvil cell. At pressures and temperatures of ~91 GPa and 1,500–2,350 K, respectively, that is, in the previously reported stability field of FeO2Hx, a measured shift of −3.3 ± 0.1 eV of the Fe K‐edge demonstrates that iron has turned from Fe3+ to Fe2+. We interpret this reductive valence change of iron by a concomitant oxidation of oxygen atoms from O2− to O−, in agreement with previous suggestions based on the structures of pyrite‐type FeO2 and FeO2Hx phases. Such peculiar chemistry could drastically change our view of crystal chemistry in deep planetary interiors.

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Compression of Fe–Si–H alloys to core pressures

Cited by 38 publications

References 41 publications

Chemical Reactions Between Fe and H₂O up to Megabar Pressures and Implications for Water Storage in the Earth's Mantle and Core

Chemical Reactions Between Fe and H₂O up to Megabar Pressures and Implications for Water Storage in the Earth's Mantle and Core

The effects of ferromagnetism and interstitial hydrogen on the equation of states of hcp and dhcp FeHx: Implications for the Earth's inner core age

Ferrous Iron Under Oxygen‐Rich Conditions in the Deep Mantle

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Compression of Fe–Si–H alloys to core pressures

Cited by 38 publications

References 41 publications

Chemical Reactions Between Fe and H2O up to Megabar Pressures and Implications for Water Storage in the Earth's Mantle and Core

Chemical Reactions Between Fe and H2O up to Megabar Pressures and Implications for Water Storage in the Earth's Mantle and Core

The effects of ferromagnetism and interstitial hydrogen on the equation of states of hcp and dhcp FeHx: Implications for the Earth's inner core age

Ferrous Iron Under Oxygen‐Rich Conditions in the Deep Mantle

Contact Info

Product

Resources

About

Chemical Reactions Between Fe and H₂O up to Megabar Pressures and Implications for Water Storage in the Earth's Mantle and Core

Chemical Reactions Between Fe and H₂O up to Megabar Pressures and Implications for Water Storage in the Earth's Mantle and Core