Structural study of hcp and liquid iron under shock compression up to 275 GPa

Saransh Singh, Richard Briggs, Martin G. Gorman, Lorin X. Benedict, Christine J. Wu, Sebastien Hamel, Amy L. Coleman, Federica Coppari, Amalia Fernandez-Pañella, Christopher McGuire, Melissa Sims, June K. Wicks, Jon H. Eggert, Dayne E. Fratanduono, Raymond F. Smith
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Abstract

We combine nanosecond laser shock compression with in situ picosecond x-ray diffraction to provide structural data on iron up to 275 GPa. We constrain the extent of hcp-liquid coexistence, the onset of total melt, and the structure within the liquid phase. Our results indicate that iron, under shock compression, melts completely by 258(8) GPa. A coordination number analysis indicates that iron is a simple liquid at these pressure-temperature conditions. We also perform texture analysis between the ambient body-centered-cubic (bcc) $\ensuremath{\alpha}$, and the hexagonal-closed-packed (hcp) high-pressure $\ensuremath{\epsilon}\ensuremath{-}\mathrm{phase}$. We rule out the Rong-Dunlop orientation relationship (OR) between the $\ensuremath{\alpha}$ and $\ensuremath{\epsilon}\ensuremath{-}\mathrm{phase}\mathrm{s}$. However, we cannot distinguish between three other closely related ORs: Burger's, Mao-Bassett-Takahashi, and Potter's OR. The solid-liquid coexistence region is constrained from a melt onset pressure of 225(3) GPa from previously published sound speed measurements and full melt [246.5(1.8)--258(8) GPa] from x-ray diffraction measurements, with an associated maximum latent heat of melting of 623 J/g. This value is lower than recently reported theoretical estimates and suggests that the contribution to the earth's geodynamo energy budget from heat release due to freezing of the inner core is smaller than previously thought. Melt pressures for these nanosecond shock experiments are consistent with gas gun shock experiments that last for microseconds, indicating that the melt transition occurs rapidly.
275 GPa冲击压缩下hcp和铁液的结构研究
我们将纳秒激光冲击压缩与皮秒x射线原位衍射相结合,提供了高达275 GPa的铁的结构数据。我们限制了hcp-液相共存的程度,总熔体的开始,以及液相内的结构。结果表明,在冲击压缩下,铁在258(8)GPa时完全熔化。配位数分析表明,在这种压力-温度条件下,铁是一种简单的液体。我们还在环境体心立方(bcc) $\ensuremath{\alpha}$和六边形封闭填充(hcp)高压$\ensuremath{\epsilon}\ensuremath{-}\mathrm{phase}$之间进行了纹理分析。我们排除了$\ensuremath{\alpha}$和$\ensuremath{\epsilon}\ensuremath{-}\mathrm{phase}\mathrm{s}$之间的ron - dunlop取向关系(OR)。然而,我们无法区分其他三个密切相关的OR:汉堡OR,毛-巴塞特-高桥OR和波特OR。固液共存区域受到先前公布的声速测量结果的熔体起始压力225(3)GPa和x射线衍射测量结果的全熔体[246.5(1.8)—258(8)GPa]的限制,相关的最大熔化潜热为623 J/g。这个值低于最近报道的理论估计,并表明由于内核冻结而释放的热量对地球地球发电机能量收支的贡献比以前认为的要小。这些纳秒冲击实验的熔体压力与持续微秒的气枪冲击实验一致,表明熔体转变发生迅速。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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