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Silicate Melting and Vaporization During Rocky Planet Formation

E. J. Davies, P. J. Carter, S. Root, R. G. Kraus, D. K. Spaulding, S. T. Stewart, S. B. Jacobsen

2020Journal of Geophysical Research Planets46 citationsDOIOpen Access PDF

Abstract

Abstract Collisions that induce melting and vaporization can have a substantial effect on the thermal and geochemical evolution of planets. However, the thermodynamics of major minerals are not well known at the extreme conditions attained during planet formation. We obtained new data at the Sandia Z Machine and use published thermodynamic data for the major mineral forsterite (Mg SiO ) to calculate the specific entropy in the liquid region of the principal Hugoniot. We use our calculated specific entropy of shocked forsterite, and revised entropies for shocked silica, to determine the critical impact velocities for melting or vaporization upon decompression from the shocked state to 1 bar and the triple points, which are near the pressures of the solar nebula. We also demonstrate the importance of the initial temperature on the criteria for vaporization. Applying these results to ‐body simulations of terrestrial planet formation, we find that up to 20% to 40% of the total system mass is processed through collisions with velocities that exceed the criteria for incipient vaporization at the triple point. Vaporizing collisions between small bodies are an important component of terrestrial planet formation.

Topics & Concepts

VaporizationPlanetThermodynamicsSilicateMantle (geology)ThermalAstrobiologyForsteriteSolar SystemGeologyEntropy (arrow of time)Thermal stateMaterials scienceThermodynamic equilibriumExplosive materialGas giantVapor pressureGas compressorHigh-pressure geophysics and materialsAstro and Planetary SciencePlanetary Science and Exploration
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