U-Pb systematics of the McClure Mountain syenite: thermochronological constraints on the age of the 40Ar/39Ar standard MMhb

Recent advances in U-Pb geochronology allow unprecedented levels of precision in the determination of geological ages. However, increased precision has also illuminated the importance of understanding subtle sources of open-system behavior such as Pb-loss, inheritance, intermediate daughter product disequilibria, and the accuracy of the model assumptions for initial Pb. Deconvolution of these effects allows a much richer understanding of the power and limitations of U-Pb geochronology and thermochronology. In this study, we report high-precision ID-TIMS U-Pb data from zircon, baddelleyite, titanite and apatite from the McClure Mountain syenite, from which the 40Ar/39Ar hornblende standard MMhb is derived. We find that excess Pb-206 in zircon due to inclusions of high-Th minerals and elevated Th/U in titanite and apatite jeopardize the utility of the U-238-Pb-206 system in this rock. Strongly air-abraded zircons give dates that are younger than chemical-abraded zircons, which yield a statistically robust Pb-207/U-235 date of 523.98 +/- 0.12 Ma that is interpreted as the crystallization age. We explore the best method of Pb-c correction in titanite and apatite by analyzing the U-Pb isotopes of K-feldspar and using 2-D and 3-D regression methods-the latter of which yields the best results in each case. However, the calculated compositions of Pb-c for titanite, apatite and K-feldspar are different, implying that using a single Pb-c correction for multiple U-Pb thermochronometers may be inaccurate. The U-Pb thermochronological results are used to predict a closure time for Ar in hornblende of 522.98 +/- 1.00 Ma. Widely cited K-Ar and 40Ar/39Ar errors make it impossible to verify whether U-Pb dates are systematically <= 1% older than K-Ar and 40Ar/39Ar dates.