AI Article Synopsis
- Ultrafast x-ray diffraction at the LCLS has revealed that antimony undergoes a structural transformation under shock compression, turning into the Sb-II phase at about 11 GPa and forming ordered guest-atom chains.
- The Sb-III phase appears at around 15 GPa, 8 GPa lower than previously observed in static compression studies, while mixed Sb-III/liquid states occur between 38 and 59 GPa.
- An additional metastable phase, Sb-I^{'}, emerges between 8 and 12 GPa, showing a Peierls distortion, and the incommensurate Sb-II phase can be stabilized for over 10 ns when returned to ambient pressure.
Article Abstract
Ultrafast x-ray diffraction at the LCLS x-ray free electron laser has been used to resolve the structural behavior of antimony under shock compression to 59 GPa. Antimony is seen to transform to the incommensurate, host-guest phase Sb-II at ∼11 GPa, which forms on nanosecond timescales with ordered guest-atom chains. The high-pressure bcc phase Sb-III is observed above ∼15 GPa, some 8 GPa lower than in static compression studies, and mixed Sb-III/liquid diffraction are obtained between 38 and 59 GPa. An additional phase which does not exist under static compression, Sb-I^{'}, is also observed between 8 and 12 GPa, beyond the normal stability field of Sb-I, and resembles Sb-I with a resolved Peierls distortion. The incommensurate Sb-II high-pressure phase can be recovered metastably on release to ambient pressure, where it is stable for more than 10 ns.
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| http://dx.doi.org/10.1103/PhysRevLett.122.255704 | DOI Listing |
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