Differentiated planetesimals delivered iron-rich material to the Earth and Moon in high-velocity collisions at the end stages of accretion. The physical process of accreting this late material has implications for the geochemical evolution of the Earth-Moon system and the timing of Earth's core formation. However, the fraction of a planetesimal's iron core that is vaporized by an impact is not well constrained as a result of iron's poorly understood equation of state. Here we determine the entropy in the shock state of iron using a recently developed shock-and-release experimental technique implemented at the Sandia National Laboratory Z-Machine. We find that the shock pressure required to vaporize iron is 507 (+65, -85) GPa, which is lower than the previous theoretical estimate (887 GPa) and readily achieved by the high velocity impacts at the end stages of accretion. We suggest that impact vaporization of planetesimal cores dispersed iron over the surface of the growing Earth and enhanced chemical equilibration with the mantle. In addition, the comparatively low abundance of highly siderophile elements in the lunar mantle and crust can be explained by the retention of a smaller fraction of vaporized planetesimal iron on the Moon, as compared with Earth, due to the Moon's lower escape velocity.
Department of Earth and Planetary Sciences, Harvard University, 20 Oxford Street, Cambridge, MA, United States; Shock Physics Group, Lawrence Livermore National Laboratory, PO Box 808, Livermore, CA, United States; Dynamic Material Properties Group, Sandia National Laboratory, PO Box 5800, Albuquerque, NM, United States; High Energy Density Physics Theory, Sandia National Laboratory, PO-Box 5800, Albuquerque, NM, United States; Department of Earth and Planetary Sciences, UC Davis, One Shields Avenue, Davis, CA, United States
Recommended Citation:
Kraus R.G.,Root S.,Lemke R.W.,et al. Impact vaporization of planetesimal cores in the late stages of planet formation[J]. Nature Geoscience,2015-01-01,8(4)