High‐Pressure Geophysical Properties of <i>Fcc</i> Phase FeH<sub>X</sub>

Thompson, E. C.; Davis, A.; Bi, Wenli; Zhao, Jiyong; Ercan, E.; Zhang, Dongzhou; Greenberg, Eran; Prakapenka, Vitali B.; Campbell, A. J.

doi:10.1002/2017gc007168

Cited by 44 publications

(49 citation statements)

References 55 publications

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“…When plotted as a function of pressure, the computed v P of Fe 0.91 Ni 0.09 and Fe 0.8 Ni 0.1 Si 0.1 from NRIXS results show negligible differences with our re-analysis of similar data for hcp-Fe (Murphy et al, 2013). The computed v P of Fe 3 S (Lin et al, 2004) trends ∼4% below hcp-Fe, while the v P of iron-hydrides (computed from NRIXS (Mao et al, 2004;Thompson et al, 2018); constrained from phonon dispersion measurements (Shibazaki et al, 2012)) trend above hcp-Fe. Although the v P values of Fe 3 C also trend higher than hcp-Fe (Fiquet et al, 2009;Gao et al, 2008;Chen et al, 2018), the value constrained from phonon dispersion measurements around 70 GPa (Fiquet et al, 2009) is significantly higher than the trend computed from NRIXS (Gao et al, 2008).…”

Section: Other Light Elementssupporting

confidence: 40%

“…We compare our reported Figure 12. We include NRIXS studies on Fe 3 S (Lin et al, 2004), Fe 3 C (Gao et al, 2008;Chen et al, 2018), Fe 7 C 3 (Chen et al, 2014), FeO, (Mg 0.06 Fe 0.94 )O, (Mg 0.16 Fe 0.84 )O (Wicks et al, 2017), FeH x (Mao et al, 2004), and FeH x (Thompson et al, 2018). We also include IXS studies on Fe 3 C (Fiquet et al, 2009) and FeH x (Shibazaki et al, 2012).…”

Section: Other Light Elementsmentioning

confidence: 99%

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High pressure thermoelasticity and sound velocities of Fe-Ni-Si alloys

Morrison

Jackson

Sturhahn

et al. 2019

Physics of the Earth and Planetary Interiors

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The Earth's iron-dominant core is known to contain nickel from cosmochemical analysis and some amount of light elements from geophysical constraints on density and seismic wave velocities. Although there have been several studies to constrain thermoelastic properties of iron-alloys, there has been no systematic study on the effects of nickel and light elements on properties of iron using the same experimental methods and data analysis approach. We conducted nuclear resonant inelastic x-ray scattering and x-ray diffraction experiments on body-centered cubic and hexagonal close-packed (hcp) Fe 0.91 Ni 0.09 and Fe 0.8 Ni 0.1 Si 0.1 up to 104 GPa and 86 GPa, respectively, and compare to similar measurements conducted on hcp-Fe up to 171 GPa. Specifically, we determine the Debye sound velocity from the low-energy transfer region of the (partial) phonon density of states (DOS) using the equation of state determined for each material and a new approach which utilizes information criteria and probability distributions. Nickel decreases the shear velocity of iron, while 10 at% Si has little to no effect on the shear velocity of Fe 0.91 Ni 0.09. We observe that the shape of the phonon DOS of these alloys remains similar with increasing pressure. In the measured compression range, we therefore apply a generalized scaling law to describe the volume dependence of the phonon DOS and find that the vibrational Grüneisen parameters of hcp-Fe 0.91 Ni 0.09 are nearly indistinguishable from those hcp-Fe and those for Fe 0.8 Ni 0.1 Si 0.1 trend lower. From the vibrational free energy, we constrain the harmonic vibrational component of thermal pressure, which shows a significant positive deviation from theoretical calculations of hcp-Fe at pressures and temperatures of Earth's core. Collectively, our results demonstrate that the effects of nickel should be considered when modeling iron-rich planetary cores.

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Section: Other Light Elementssupporting

confidence: 40%

Section: Other Light Elementsmentioning

confidence: 99%

High pressure thermoelasticity and sound velocities of Fe-Ni-Si alloys

Morrison

Jackson

Sturhahn

et al. 2019

Physics of the Earth and Planetary Interiors

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“…Assuming carbon is a sole light element, 1.8-7.7 wt% C has been proposed to account for the outer core density and sound velocity (Sata et al, 2010;Badro et al, 2014Morard et al, 2017). Experimental and theoretical studies demonstrated that they are also reconciled with 0.8-2.0 wt% H in molten iron (Terasaki et al, 2012;Thompson et al, 2018;Umemoto & Hirose, 2015). The green region in Figure 2 shows the possible compositional range of the Fe-C-H liquid core supposed from these studies.…”

Section: Hydrogen Limits the Solubility Of Carbon In Liquid Ironmentioning

confidence: 98%

“…In contrast, earlier experiments on Fe‐H alloys are limited even for solids (e.g., Fukai, ; Pépin et al, ), in particular at high temperatures (Fukai et al, ; Sakamaki et al, ; Terasaki et al, ). While Terasaki et al () reported that solid Fe 3 C does not incorporate hydrogen at 14 GPa, Narygina et al () demonstrated that Fe 3 C was once formed from Fe + C n H 2n+2 paraffin and then replaced by FeH + C diamond at >1600 K and 54 GPa (Ohta et al, ; Thompson et al, ). These results indicate that (1) carbon and hydrogen do not coexist in solid Fe and (2) hydrogen is more siderophile than carbon at relatively high pressure and temperature ( P‐T ).…”

Section: Introductionmentioning

confidence: 99%

Hydrogen Limits Carbon in Liquid Iron

Hirose

Tagawa

Kuwayama

et al. 2019

Geophysical Research Letters

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Melting experiments were performed on the Fe‐C‐H system to 127 GPa in a laser‐heated diamond anvil cell. On the basis of in situ and ex situ sample characterizations, we found that the solubility of carbon in liquid Fe correlates inversely with hydrogen concentration at ~60 GPa and ~3500 K, indicating that liquid Fe preferentially incorporates hydrogen rather than carbon under conditions with abundant C and H. While large amounts of both C and H may have been delivered to the growing Earth, C‐poor/H‐rich metals were likely added to the protocore in the late stages of core formation. We also obtained a melting curve of FeHx (x > 1) far beyond the pressure range in earlier determinations. Its liquidus temperature was found to be 2380 K at 135 GPa, lower than those of Fe alloyed with the other possible core light elements. Relatively low core temperature is thus supported by the presence of hydrogen.

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“…Accumulation of iron-enriched hydrous pyrite-type phase would reduce the speed of seismic waves at the core-mantle boundary, which may be detected at large low shear velocity provinces and ultra-low velocity zones [11][12][13]. Reservoirs of H also produce hydrides that would possibly infiltrate to the outer core [9,14]. Although H is an influential volatile component, the budget of H in the lower mantle is still under debate [15].…”

Section: Introductionmentioning

confidence: 99%

Experimental Evidence for Partially Dehydrogenated ε-FeOOH

et al. 2019

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Hydrogen in hydrous minerals becomes highly mobile as it approaches the geotherm of the lower mantle. Its diffusion and transportation behaviors under high pressure are important in order to understand the crystallographic properties of hydrous minerals. However, they are difficult to characterize due to the limit of weak X-ray signals from hydrogen. In this study, we measured the volume changes of hydrous ε-FeOOH under quasi-hydrostatic and non-hydrostatic conditions. Its equation of states was set as the cap line to compare with ε-FeOOH reheated and decompression from the higher pressure pyrite-FeO 2 Hx phase with 0 < x < 1. We found the volumes of those re-crystallized ε-FeOOH were generally 2.2% to 2.7% lower than fully hydrogenated ε-FeOOH. Our observations indicated that ε-FeOOH transformed from pyrite-FeO 2 Hx may inherit the hydrogen loss that occurred at the pyrite-phase. Hydrous minerals with partial dehydrogenation like ε-FeOOHx may bring it to a shallower depth (e.g., < 1700 km) of the lower mantle.

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High‐Pressure Geophysical Properties of Fcc Phase FeH_X

Cited by 44 publications

References 55 publications

High pressure thermoelasticity and sound velocities of Fe-Ni-Si alloys

High pressure thermoelasticity and sound velocities of Fe-Ni-Si alloys

Hydrogen Limits Carbon in Liquid Iron

Experimental Evidence for Partially Dehydrogenated ε-FeOOH

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High‐Pressure Geophysical Properties of Fcc Phase FeHX

Cited by 44 publications

References 55 publications

High pressure thermoelasticity and sound velocities of Fe-Ni-Si alloys

High pressure thermoelasticity and sound velocities of Fe-Ni-Si alloys

Hydrogen Limits Carbon in Liquid Iron

Experimental Evidence for Partially Dehydrogenated ε-FeOOH

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Product

Resources

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High‐Pressure Geophysical Properties of Fcc Phase FeH_X