Melting of magnesium oxide up to two terapascals using double-shock compression
journal contribution
posted on 2024-08-06, 12:10 authored by L. E. Hansen, D. E. Fratanduono, S. Zhang, Damien HicksDamien Hicks, T. Suer, Z. K. Sprowal, M. F. Huff, X. Gong, B. J. Henderson, D. N. Polsin, M. Zaghoo, S. X. Hu, G. W. Collins, J. R. RyggConstraining the melting behavior of magnesium oxide, a major constituent of gaseous and rocky planets, is key to benchmarking their evolutionary models. Using a double-shock technique, we extended the MgO melt curve measurements to 2 TPa; this is twice the pressure achieved by previous melting experiments on any material. A temperature plateau is observed between 1218 and 1950 GPa in the second-shock states, which is attributed to latent heat of melting. At 1950 GPa, the measured melting temperature is 17 600 K, which is 17% lower than recent theoretical predictions. The melting curve is steeper than that of MgSiO3, indicating that MgO is likely solid in the interior of Saturn-sized gas giants and extra-solar super-Earth planets.
Funding
Ultrafast Photonic Electron Microscopy: Visualising dynamics at the nanoscale
Australian Research Council
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ISSN
2469-9950Journal title
Physical Review BVolume
104Issue
1Article number
14106Pagination
014106-Publisher
American Physical Society (APS)Copyright statement
Copyright © 2021 American Physical Society. This final peer-reviewed accepted manuscript is distributed under the terms and conditions of the Attribution-NonCommercial 4.0 International (CC BY-NC 4.0) license. See http://creativecommons.org/licenses/by-nc/4.0/Language
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