EARLY THERMAL EVOLUTION OF PLANETESIMALS AND ITS IMPACT ON PROCESSING AND DATING OF METEORITIC MATERIAL

H.-P. Gail (Heidelberg University, Germany),
D. Breuer (Deutsches Zentrum für Luft- und Raumfahrt e.V. (DLR), Germany),
T. Spohn (DLR, Institut für Planetenforschung, Germany),
T. Kleine (University of Münster, Institute of Planetology, Germany),
M. Trieloff (Heidelberg University, Germany)

Radioisotopic ages for meteorites and their components provide constraints on the evolution of small bodies: Timescales of accretion, thermal and aqueous metamorphism, differentiation, cooling and impact metamorphism. Realising that the decay heat of short-lived nuclides (e.g. 26Al, 60Fe), was the main heat source driving differentiation and metamorphism, thermal modeling of small bodies is of utmost impotrance to set individual meteorite age data into the general context of the thermal evolution of their parent bodies, and to derive general conclusions about the nature of planetary building blocks in the early solar system. As a general result, modelling easily explains that iron meteorites are older than chondrites, as early formed planetesimals experienced a higher concentration of short-lived nuclides and more severe heating. However, core formation processes may also extend to 10 Ma after CAIs. A general effect of the porous nature of the starting material is that relatively small bodies (< few km) will also differentiate if they from within 2 Ma after CAIs. A particular interesting feature to be explored is the possibility that some chondrites may derive from the outer undifferentiated layers of asteroids that are differentiated in their interiors. This could explain the presence of remnant magnetization in some chondrites due to a planetary magnetic field.

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