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Crystal Structure and Melting of Fe Shock Compressed to 273 GPa: <i>In Situ</i> X-Ray Diffraction

Stefan J. Turneaure, Surinder M. Sharma, Y. M. Gupta

2020Physical Review Letters72 citationsDOIOpen Access PDF

Abstract

Despite extensive shock wave and static compression experiments and corresponding theoretical work, consensus on the crystal structure and the melt boundary of Fe at Earth's core conditions is lacking. We present in situ x-ray diffraction measurements in laser-shock compressed Fe that establish the stability of the hexagonal-close-packed (hcp) structure along the Hugoniot through shock melting, which occurs between ∼242 to ∼247 GPa. Using previously reported hcp Fe Hugoniot temperatures, the melt temperature is estimated to be 5560(360) K at 242 GPa, consistent with several reported Fe melt curves. Extrapolation of this value suggests ∼6400 K melt temperature at Earth's inner core boundary pressure.

Topics & Concepts

Materials scienceDiffractionInner coreShock waveExtrapolationShock (circulatory)Compression (physics)Core (optical fiber)X-ray crystallographyCrystal (programming language)CrystallographyThermodynamicsComposite materialOpticsPhysicsChemistryMathematical analysisComputer scienceMathematicsInternal medicineProgramming languageMedicineHigh-pressure geophysics and materialsDiamond and Carbon-based Materials ResearchGeological and Geochemical Analysis
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