Open AccessRamp compression of iron to 273 GPa
Author(s) -
Jue Wang,
R. F. Smith,
J. H. Eggert,
D. G. Braun,
T. R. Boehly,
J. R. Patterson,
P. M. Celliers,
Raymond Jeanloz,
G. W. Collins,
T. S. Duffy
Publication year - 2013
Publication title -
journal of applied physics
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 0.699
H-Index - 319
eISSN - 1089-7550
pISSN - 0021-8979
DOI - 10.1063/1.4813091
Subject(s) - compression (physics) , shock (circulatory) , shock wave , materials science , shock response spectrum , phase (matter) , stress (linguistics) , dynamic range compression , rise time , mechanics , thermodynamics , composite material , physics , classical mechanics , medicine , linguistics , philosophy , quantum mechanics , acceleration , voltage
Multiple thickness Fe foils were ramp compressed over several nanoseconds to pressure conditions relevant to the Earth's core. Using wave-profile analysis, the sound speed and the stress-density response were determined to a peak longitudinal stress of 273 GPa. The measured stress-density states lie between shock compression and 300-K static data, and are consistent with relatively low temperatures being achieved in these experiments. Phase transitions generally display time-dependent material response and generate a growing shock. We demonstrate for the first time that a low-pressure phase transformation (α-Fe to e-Fe) can be overdriven by an initial steady shock to avoid both the time-dependent response and the growing shock that has previously limited ramp-wave-loading experiments. In addition, the initial steady shock pre-compresses the Fe and allows different thermodynamic compression paths to be explored.
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