Physics – Condensed Matter – Materials Science
Scientific paper
2010-10-25
High Energy Dens.Phys.7:141-144,2011
Physics
Condensed Matter
Materials Science
Scientific paper
10.1016/j.hedp.2011.02.001
Exoplanets with masses similar to that of Earth have recently been discovered in extrasolar systems. A first order question for understanding their dynamics is to know whether they possess Earth like liquid metallic cores. However, the iron melting curve is unknown at conditions corresponding to planets of several times the Earth's mass (over 1500 GPa for planets with 10 times the Earth's mass (ME)). In the density-temperature region of the cores of those super-Earths, we calculate the iron melting curve using first principle molecular dynamics simulations based on density functional theory. By comparing this melting curve with the calculated thermal structure of Super Earths, we show that planets heavier than 2ME, have solid cores, thus precluding the existence of an internal metallic-core driven magnetic field. The iron melting curve obtained in this study exhibits a steeper slope than any calculated planetary adiabatic temperature profile rendering the presence of molten metallic cores less likely as sizes of terrestrial planets increase.
Bouchet Johann
Guyot Francois
Mazevet Stéphane
Morard Guillaume
Valencia Diana
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