期刊
JOURNAL OF GEOPHYSICAL RESEARCH-PLANETS
卷 126, 期 4, 页码 -出版社
AMER GEOPHYSICAL UNION
DOI: 10.1029/2020JE006745
关键词
equation of state; Hugoniot; melting; shock wave; supercritical; vaporization
资金
- DOE-NNSA grant [DE-NA0003842, DE-NA0003904]
- NASA [NNX15AH54G, NNX16AP35H]
- UC Office of the President grant [LFR-17-449059]
- U.S. Department of Energy's National Nuclear Security Administration [DE-NA0003525]
- U.S. Department of Energy [DE-AC52-07NA27344]
Physical processes during planet formation involve a wide range of pressures and temperatures, with giant impacts reaching high pressures and generating sufficient entropy. Shock experiments on forsterite were conducted to determine density and temperature, revealing discrepancies with previous equation of state models. Experimental results suggest past impact studies may have underestimated vapor production and support the idea of giant impacts transforming mantles of rocky planets into supercritical fluids.
The physical processes during planet formation span a large range of pressures and temperatures. Giant impacts, such as the one that formed the Moon, achieve peak pressures of 100s of GPa. The peak shock states generate sufficient entropy such that subsequent decompression to low pressures intersects the liquid-vapor phase boundary. The entire shock-and-release thermodynamic path must be calculated accurately in order to predict the post-impact structures of planetary bodies. Forsterite (Mg2SiO4) is a commonly used mineral to represent the mantles of differentiated bodies in hydrocode models of planetary collisions. Here, we performed shock experiments on the Sandia Z Machine to obtain the density and temperature of the liquid branch of the liquid-vapor phase boundary of forsterite. This work is combined with previous work constraining pressure, density, temperature, and entropy of the forsterite principal Hugoniot. We find that the vapor curves in previous forsterite equation of state models used in giant impacts vary substantially from our experimental results, and we compare our results to a recently updated equation of state. We have also found that due to under-predicted entropy production on the principal Hugoniot and elevated temperatures of the liquid vapor phase boundary of these past models, past impact studies may have underestimated vapor production. Furthermore, our results provide experimental support to the idea that giant impacts can transform much of the mantles of rocky planets into supercritical fluids.
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