<p>The availability of high-temperature thermochronometers suitable for generation of continuous thermal histories at mid- to lower-crustal temperatures (i.e., &#8805; 400 &#176;C) is limited. Available thermochronometers include the recently developed apatite and rutile U-Pb thermochronometers ( &#8804; 550 and 640 &#176;C; Kooijman et al., 2010; Cochrane et al., 2014) and arguably the K-Ar system in white mica (sensitive to temperatures &#8804; 500 &#176;C. Recent work has focussed on micro-beam U-Pb analysis of apatite and rutile by sector-field and multi-collector LA-ICPMS to generate single-crystal U-Pb age profiles. Such profiles can be inverted to yield continuous thermal histories for high-temperature processes (e.g., Smye et al., 2018). However, both apatite and rutile can exhibit crystal growth and dissolution-reprecipitation reactions in the same temperature ranges at which measurable Pb diffusion occurs: neither behaves as a pure thermochronometer in all circumstances (e.g., Chambers and Kohn, 2012; Harlov et al., 2005). Thus, it is critical to develop protocols which unequivocally identify age profiles arising from volume diffusion.</p><p>Here, we present case studies from greenschist- to granulite-facies-grade metamorphic systems from the Eastern Alps and the Western Gneiss Region of Norway. We demonstrate the utility of trace-element analysis (Sr-Y-REE-Th-U) and isotopic forward modelling to discriminate age resetting arising from (re)crystallisation from diffusion. Both rutile and especially apatite routinely incorporate non-trivial amounts of common-Pb during crystallisation (as opposed to radiogenic Pb generated by <em>in-situ</em> radionuclide decay), rendering them discordant in U-Pb isotope space. This common-Pb must be corrected for during age calculation. However, common-Pb is isotopically distinct from radiogenic Pb but exhibits the same diffusion behaviour, so the predicted U-Pb isotopic distribution for a given crystal arising from a proposed thermal history can be estimated by isotopic forward modelling. Thus, common-Pb can be exploited to validate both the assumption of Pb-loss by volume diffusion, and the thermal history predicted by age profile inversion.</p><p><strong>Chambers</strong>, J.A., & Kohn, M.J., Am. Mineral., 97, 543&#8211;555 (2012); <strong>Cochrane</strong>, R., et al., Geochim. Cosmochim. Acta, 127, 39&#8211;56, (2014); <strong>Harlov</strong>, D.E., et al., Contrib. Mineral. Petrol, 150, 268&#8211;286 (2005); <strong>Kooijman</strong>, E., et al., Earth Planet. Sci. Lett, 293, 321&#8211;330, (2010); <strong>Smye</strong>, A.J., et al., Chem. Geol., 494, 1&#8211;18 (2018).</p>
Mud Tank Zircon: Long‐Term Evaluation of a Reference Material for U‐Pb Dating, Hf‐Isotope Analysis and Trace Element Analysis
