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

Edmund, Eric; Antonangeli, Daniele; Decremps, F.; Miozzi, Francesca; Morard, Guillaume; Boulard, E.; Clark, A. N.; Ayrinhac, Simon; Gauthier, Michel; Morand, Marc; Mézouar, M.

doi:10.1029/2018jb016904

Cited by 26 publications

(77 citation statements)

References 66 publications

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“…The measured d-spacing of the transient bcc {110} and {211} reflections corresponds to a hydrostatic pressure of 38 GPa; the high-pressure hcp {002} reflection corresponds to a pressure of 132±26 GPa using the 300 K static compression equation of state from Hirao et al 33 . We make no thermal corrections since the Hirao data agrees well with the shock Hugoniot data reported in Marsh et al 61 , as seen in Fig.4, for Fe-Si 6.9wt% ; measurements of Fe-Si 5wt% at slightly lower pressure by Edmund et al 65 suggest the thermal pressure is ∼15 GPa for our conditions, similar to that found by Fischer et al in Fe-Si 16wt% and less than our error bars. The inferred bcc pressure is consistent with our calculations for the transformation pressure described below.…”

Section: Discussionsupporting

confidence: 89%

Ultrafast X-ray diffraction measurements of shock-compressed iron and iron alloys

Krygier¹,

Harmand²,

Albertazzi³

et al. 2020

Preprint

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The extreme pressures achievable with dynamic compression holds great promise for studying planetary interiors. Phase stability of Fe-Si alloys, which are complex to address, is particularly relevant to understanding telluric planetary cores due to the widely varying properties produced by small changes in Si concentration. Here we report the study of phase stability of pure iron and Fe-Si alloys by x-ray diffraction measurements carried out on shocked samples using an x-ray free electron laser (XFEL). Our setup combined with the brilliance of the XFEL allows us to observe the rapid onset of high-pressure solid-solid phase transformation in Fe and Fe-Si8.5wt%; we observe no such evidence in Fe-Si16wt% up to 110 GPa on the nanosecond timescale. Density Functional Theory calculations provide the conceptual framework to rationalize these observations. Taken together our experiments and calculations support recent dynamic compression measurements and shed light on conflicting static compression results. Our work highlights the need to properly consider the differing intrinsic timescales of the static and dynamic experiments when comparing results, and the complementarity of the techniques in assessing phase diagram and transition mechanisms.

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Section: Discussionsupporting

confidence: 89%

Ultrafast X-ray diffraction measurements of shock-compressed iron and iron alloys

Krygier¹,

Harmand²,

Albertazzi³

et al. 2020

Preprint

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“…Irrespective of such considerations, for Fe-5Si, we observed that the acoustic travel time of a sample varied by nearly 50% from ambient pressure to 1 Mbar, while changes in sample volume led to variations in sample thickness of about 10% over the same pressure range [28]. Consequently, the primary contribution to the variation of the sample acoustic travel time over this pressure range was due to the change in sound velocity, rather than the change in thickness.…”

Section: Measurement Of the Sound Velocities Of Polycrystalline Fe-simentioning

confidence: 79%

“…The pressure dependence of the sample thickness was taken into account using P-V EoS determined by X-ray diffraction, either after [28] for the bcc and hcp phases of Fe10Si or after [27,29] for Fe5Si. We relate the pressure evolution of the longitudinal sound velocity to the pressure evolution of thickness and acoustic travel time using the following equation:…”

Section: Measurement Of the Sound Velocities Of Polycrystalline Fe-simentioning

confidence: 99%

“…On the basis of the determined sound velocities and literature constraints on the shear strength of Ne [34], the pressure gradients that may develop in Ne or Ar are not sufficiently large to induce significant elastic or plastic deformation of the sample in the case of Fe or Fe-alloys relative to experimental uncertainties. Estimations of the Young's moduli of Fe, Fe5Si, and Fe10Si at the highest pressure data points used from these experiments are E = 890 GPa at 152 GPa, E = 810 GPa at 114 GPa, and E = 340 GPa at 36 GPa for these alloys, respectively [27,28,35]. Given that the shear strength of Ar is estimated to be about 3-6 GPa at 150 GPa [36,37] and the shear strength of Ne is less than 1-2 GPa over the pressure ranges investigated in [27,28], deviations from the assumption of purely volumetric variation in thickness are not significant in these systems relative to experimental uncertainties and scatter.…”

Section: Measurement Of the Sound Velocities Of Polycrystalline Fe-simentioning

confidence: 99%

“…Estimations of the Young's moduli of Fe, Fe5Si, and Fe10Si at the highest pressure data points used from these experiments are E = 890 GPa at 152 GPa, E = 810 GPa at 114 GPa, and E = 340 GPa at 36 GPa for these alloys, respectively [27,28,35]. Given that the shear strength of Ar is estimated to be about 3-6 GPa at 150 GPa [36,37] and the shear strength of Ne is less than 1-2 GPa over the pressure ranges investigated in [27,28], deviations from the assumption of purely volumetric variation in thickness are not significant in these systems relative to experimental uncertainties and scatter. However, future studies are needed to test this assumption for materials that undergo reconstructive phase transitions at very high pressures, as the rapid loss of shear or compressive strength in a sample under conditions where compression becomes strongly deviatoric may lead to plastic effects that would be important to constrain for more precise velocity determination at multi-Mbar pressures.…”

Section: Measurement Of the Sound Velocities Of Polycrystalline Fe-simentioning

confidence: 99%

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Picosecond Acoustics Technique to Measure the Sound Velocities of Fe-Si Alloys and Si Single-Crystals at High Pressure

et al. 2020

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We describe here a time resolved pump-probe laser technique—picosecond interferometry—which has been combined with diamond anvil cells (DAC). This method enables the measurement of the longitudinal sound velocity up to Mbar pressure for any kind of material (solids, liquids, metals, insulators). We also provide a description of picosecond acoustics data analysis in order to determine the complete set of elastic constants for single crystals. To illustrate such capabilities, results are given on the pressure dependence of the acoustic properties for prototypical cases: polycrystal (hcp-Fe-5 wt% Si up to 115 GPa) and single-crystal (Si up to 10 GPa).

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Compressional wave velocity for iron hydrides to 100 gigapascals via picosecond acoustics

et al. 2022

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

Cited by 26 publications

References 66 publications

Ultrafast X-ray diffraction measurements of shock-compressed iron and iron alloys

Ultrafast X-ray diffraction measurements of shock-compressed iron and iron alloys

Picosecond Acoustics Technique to Measure the Sound Velocities of Fe-Si Alloys and Si Single-Crystals at High Pressure

Compressional wave velocity for iron hydrides to 100 gigapascals via picosecond acoustics

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