Density measurements and structural properties of liquid and amorphous metals under high pressure

Morard, Guillaume; Garbarino, Gastón; Antonangeli, Daniele; Andrault, Denis; Guignot, Nicolas; Siebert, J.; Roberge, Mathilde; Boulard, E.; Lincot, Ainhoa; Denoeud, A.; Petitgirard, Sylvain

doi:10.1080/08957959.2013.860137

Cited by 26 publications

(31 citation statements)

References 62 publications

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“…Calculated atomic density as a function of the minimal distance r min for Fe‐C liquid alloy measured in a LH‐DAC experiment. The error bar at each point is related to the figure of merit χ 2 determining the validity of the density calculation (see Morard, Garbarino, et al, () for more details). The local minimum for χ 2 (minimum in the error bars) at 0.163 nm gives us the density for the studied liquid.…”

Section: Methodsmentioning

confidence: 99%

Structure and Density of Fe‐C Liquid Alloys Under High Pressure

et al. 2017

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The density and structure of liquid Fe‐C alloys have been measured up to 58 GPa and 3,200 K by in situ X‐ray diffraction using a Paris‐Edinburgh press and laser‐heated diamond anvil cell. Study of the pressure evolution of the local structure inferred by X‐ray diffraction measurements is important to understand the compression mechanism of the liquid. Obtained data show that the degree of compression is greater for the first coordination sphere than the second and third coordination spheres. The extrapolation of the measured density suggests that carbon cannot be the only light element alloyed to iron in the Earth's core, as 8–16 at % C (1.8–3.7 wt % C) would be necessary to explain the density deficit of the outer core relative to pure Fe. This concentration is too high to account for outer core velocity. The presence of other light elements (e.g., O, Si, S, and H) is thus required.

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Section: Methodsmentioning

confidence: 99%

Structure and Density of Fe‐C Liquid Alloys Under High Pressure

et al. 2017

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“…In this work, we present a comprehensive experimental study of Ce 69 Al 10 Cu 20 Co 1 bulk MG by means of angle dispersive x-ray diffraction performed up to 16 GPa along two distinct isotherms (300 and 340 K). The whole diffuse signals have been here processed following the procedure as detailed in the Appendix, devised by [20][21][22] and later by Morard et al [23]. In this way, we have been able to extract directly the structure factor S(Q), the pair distribution g(r), the atomic density ρ and the compressibility as a function of pressure and temperature.…”

Section: Introductionmentioning

confidence: 99%

Polyamorphism of a Ce-based bulk metallic glass by high-pressure and high-temperature density measurements

et al. 2016

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Metallic glasses are of recent interest worldwide due to their remarkable physico-chemical properties which can be put in relation with their crystalline counterparts. Among them, cerium based metallic glasses (Ce-MGs) have unique features such as the existence of polyamorphism under pressure, unexpected in these spatially compact systems. While a phase transition between amorphous phases with change of density and local structure has been previously detected, the corresponding structural variation under pressure was not clearly identified, due to difficulties in performing accurate measurements and reliable analysis. In this work, angle dispersive x-ray diffraction experiments of Ce 69 Al 10 Cu 20 Co 1 bulk metallic glass have been performed up to 16 GPa along two distinct isotherms (300 and 340 K). The whole diffuse signals have then been processed in order to extract the structure factor S(Q), the pair distribution g(r), the atomic density ρ and the compressibility as a function of pressure and temperature. These are crucial probes to fully characterize the phase diagram, and they clearly confirm the existence of a link between polyamorphism in Ce-MGs and the γ ⇆ α transition in pure cerium. Finally, owing to the presence of a critical point in pure solid Ce, the existence of such a feature is here discussed for Ce-MGs.

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“…In addition to the study of the solid−solid phase transitions, like bcc−face-centered cubic (fcc) in temperature and bcc−hcp in pressure, and to the measurement of some properties of these phases (11,22,23), X-ray diffraction also allows the study of solid−liquid transitions (24) and measurement of liquid density (25). Static compression measurements of the melting curve of iron have led to over 1,000 K difference in melting temperatures between different studies (1,2,4,26,27).…”

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Dynamic X-ray diffraction observation of shocked solid iron up to 170 GPa

Denoeud

Ozaki

Benuzzi‐Mounaix

et al. 2016

Proc. Natl. Acad. Sci. U.S.A.

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Investigation of the iron phase diagram under high pressure and temperature is crucial for the determination of the composition of the cores of rocky planets and for better understanding the generation of planetary magnetic fields. Here we present X-ray diffraction results from laser-driven shock-compressed single-crystal and polycrystalline iron, indicating the presence of solid hexagonal close-packed iron up to pressure of at least 170 GPa along the principal Hugoniot, corresponding to a temperature of 4,150 K. This is confirmed by the agreement between the pressure obtained from the measurement of the iron volume in the sample and the inferred shock strength from velocimetry deductions. Results presented in this study are of the first importance regarding pure Fe phase diagram probed under dynamic compression and can be applied to study conditions that are relevant to Earth and super-Earth cores.X-ray diffraction | iron phase diagram | shock-compressed iron | Earth core | dynamic compression

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Density measurements and structural properties of liquid and amorphous metals under high pressure

Cited by 26 publications

References 62 publications

Structure and Density of Fe‐C Liquid Alloys Under High Pressure

Structure and Density of Fe‐C Liquid Alloys Under High Pressure

Polyamorphism of a Ce-based bulk metallic glass by high-pressure and high-temperature density measurements

Dynamic X-ray diffraction observation of shocked solid iron up to 170 GPa

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