Equations of State and Anisotropy of Fe‐Ni‐Si Alloys

Morrison, Rachel A.; Jackson, Jennifer M.; Sturhahn, W.; Zhang, Dongzhou; Greenberg, Eran

doi:10.1029/2017jb015343

Cited by 24 publications

(64 citation statements)

References 130 publications

(404 reference statements)

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“…Shown in Figure as raw datapoints, the presented alloy exhibits a slightly higher volume than hcp‐Fe, consistent with literature on Fe‐Si alloys (Fischer et al, ; Lin, Campbell, et al,; Tateno et al, ). While the Earth's core is likely to be composed of an Fe‐Ni alloy, the addition of Ni likely does not significantly change the presented results and conclusions, due to the weak effect that Ni has on Vp relative to Fe and Si (Antonangeli et al,; Liu et al, ; Martorell et al, ; Wakamatsu et al, ) and its weak effect on density (Morrison et al, ). However, it is stressed that at present there are few constraints on the thermoelastic behavior of Fe‐Ni or Fe‐Ni‐Si alloys at simultaneous high P‐T conditions.…”

Section: Resultsmentioning

confidence: 88%

Velocity‐Density Systematics of Fe‐5wt%Si: Constraints on Si Content in the Earth's Inner Core

et al. 2019

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The elasticity of hcp-Fe-5wt%Si has been investigated by synchrotron X-ray diffraction up to 110 GPa and 2,100 K and by picosecond acoustics measurements at ambient temperature up to 115 GPa. The established Pressure-Volume-Temperature equation of state shows that the density of the Earth's inner core can be matched by an Fe-Si alloy with 5wt% Si for all reasonable core temperatures, but that its compressional and shear velocities remain too high with respect to seismological observations. On the other hand, Fe-Si alloys whose velocities are expected to get close to seismological observations are too dense at relevant temperatures. Thus, based on these combined velocity-density measurements, silicon is not likely to be the sole light element in the inner core.

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Section: Resultsmentioning

confidence: 88%

Velocity‐Density Systematics of Fe‐5wt%Si: Constraints on Si Content in the Earth's Inner Core

et al. 2019

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“…We then investigated how planets with primordial compositions, or those that have the same Fe/Mg ratios as their host stars, compare to these mass-radius relationships and the super-Earth data. We use the Fe/Mg ratio instead of 1 We have updated the equations of state to reflect better data obtained by Stixrude & Lithgow-Bertelloni (2011) for the mantle and that of the core by Morrison et al (2018). We chose the Fe 0.95 Ni 0.5 equation of state for the core, but to calculate the chemical budget we include an unspecified light alloy in the core that makes up 10% by mol and does not include magnesium, in line with the Earth (McDonough & Sun 1995), nor silicon, for simplification the Fe/Si ratio, as silicon is somewhat volatile (McDonough & Sun 1995), and thus may not be incorporated as readily into planets as magnesium.…”

Section: Super-earth Data and Chemistrymentioning

confidence: 99%

Chemical diversity of super-Earths as a consequence of formation

Scora

Valencia

Morbidelli

et al. 2020

Monthly Notices of the Royal Astronomical Society

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Recent observations of rocky super-Earths have revealed an apparent wider distribution of Fe/Mg ratios, or core to mantle ratios, than the planets in our Solar System. This study aims to understand how much of the chemical diversity in the super-Earth population can arise from giant impacts during planetary formation. Planet formation simulations have only recently begun to treat collisions more realistically in an attempt to replicate the planets in our Solar System. We investigate planet formation more generally by simulating the formation of rocky super-Earths with varying initial conditions using a version of SyMBA, a gravitational N-body code, that incorporates realistic collisions. We track the maximum plausible change in composition after each impact. The final planets span a range of Fe/Mg ratios similar to the Solar System planets, but do not completely match the distribution in super-Earth data. We only form a few planets with minor iron-depletion, suggesting other mechanisms are at work. The most iron-rich planets have a lower Fe/Mg ratio than Mercury, and are less enriched than planets such as Kepler-100b. This indicates that further work on our understanding of planet formation and further improvement of precision of mass and radius measurements are required to explain planets at the extremes of this Fe/Mg distribution.

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“…However, there was considerable scatter in the data of iron (Mao et al, 2001) and iron-nickel, such that no effect could also be concluded from these measurements. A variety of experimental studies investigated the equations of state of hcp-iron-nickel at 300 K (Takahashi et al, 1968;Mao et al, 1990;Morrison et al, 2018) as well as at high temperatures (McQueen and Marsh, 1966;Asanuma et al, 2011;Sakai et al, 2014). However, constraints on the thermal equations of state of hcp-iron-nickel are limited and indicate a considerable range of thermal parameters associated with the effects of nickel (Ekholm et al, 2011;Côté et al, 2012;Martorell et al, 2013a).…”

Section: Accepted Manuscriptmentioning

confidence: 99%

“…Most constraints on iron-silicon sound velocities at inner core conditions come from ab initio studies (Vočadlo, 2007;Tsuchiya and Fujibuchi, 2009;Ono, 2013;Martorell et al, 2016). Isothermal equations of state of these alloys include Lin (2003); Hirao et al (2004); Ono et al (2007); Sata et al (2010); Asanuma et al (2011); Tateno et al (2015); Morrison et al (2018), and experimental thermal equations of state studies include Zhang and Guyot (1999); Fischer et al (2012Fischer et al ( , 2014; Tateno et al (2015), all utilizing x-ray diffraction techniques. However, to date, the thermal properties of ironnickel-silicon alloys, including constraints on the Grüneisen parameter, have not been investigated with techniques sensitive to the vibrational properties of the material.…”

Section: Accepted Manuscriptmentioning

confidence: 99%

“…Second, we estimate vibrational thermal pressure from the vibrational free energy derived from the phonon DOS. The thermal expansion is determined using constraints on the bulk modulus from the same alloys (Morrison et al, 2018). Additional parameters are derived from the phonon DOS including the vibrational kinetic energy, vibrational heat capacity and Lamb-Mössbauer factor.…”

Section: Accepted Manuscriptmentioning

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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Equations of State and Anisotropy of Fe‐Ni‐Si Alloys

Cited by 24 publications

References 130 publications

Velocity‐Density Systematics of Fe‐5wt%Si: Constraints on Si Content in the Earth's Inner Core

Velocity‐Density Systematics of Fe‐5wt%Si: Constraints on Si Content in the Earth's Inner Core

Chemical diversity of super-Earths as a consequence of formation

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

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