Cr diffusion in orthopyroxene:: Experimental determination, 53Mn-53Cr thermochronology, and planetary applications

We have determined Cr diffusion coefficients (D) in orthopyroxene parallel to the a-, b-, and c-axial directions as a function temperature at f(O-2) corresponding to those of the wustite-iron (WI) buffer. Diffusion is found to be significantly anisotropic with D(//c) > D(//b) > D(//a), conforming to an earlier theoretical prediction. Increase f(O-2) from WI buffer conditions to 4.5 log unit above the buffer at 950 and 1050 degrees C leads to decrease of D(Cr) by a factor of two to three, possibly suggesting significant contribution from an interstitial diffusion mechanism. We have used the diffusion data to calculate the closure temperatures (T-c) of the Mn-Cr decay system in orthopyroxene as a function of initial temperature (T-0), grain size (a) and cooling rate for spherical and plane sheet geometries. We also present graphical relations that permit retrieval of cooling rates from knowledge of the resetting of Mn-Cr ages in orthopyroxene during cooling, To and a. Application of these relations to the Mn-Cr age data of the cumulate eucrite Serra de Mage yields a T-c of 830-980 degrees C, and cooling rates of 2-27 degrees C/Myr at T-c and similar to 1-13 degrees C/Myr at 500 degrees C. It is shown that the cooling of Serra de Mage to the closure temperature of the Mn-Cr system took place at its original site in the parent body, and thus implies a thickness for the eucrite crust in the commonly accepted HED parent body, Vesta, of greater than 30 km. This thickness of the eucrite crust is compatible only with a model of relatively olivine-poor bulk mineralogy in which olivine constitutes 19.7% of the total asteroidal mass. (c) 2007 Elsevier Ltd. All rights reserved.