Tracking cycles of Phanerozoic opening and closing of ocean basins using detrital rutile and zircon geochronology and geochemistry

Geology Pub Date : 2024-02-21 DOI:10.1130/g51826.1
M. Odlum, T. Capaldi, Kelly D. Thomson, D. Stockli
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Abstract

Sedimentary basins provide a deep time archive of tectonic and Earth-surface processes that can be leveraged by detrital mineral U-Pb dating and geochemistry to track paleogeography, magmatism, and crustal evolution. Zircon preserves the long-term (billions of years) record of supercontinent cycles; however, it is biased toward preserving felsic crustal records. Detrital rutile complements the detrital zircon record by providing constraints on the time and temperature of rifting and mafic magmatism, metamorphism, exhumation of the middle and lower crust, subduction, and amagmatic orogenesis. We use detrital zircon U-Pb and detrital rutile U-Pb geochronology and trace element analysis of Permian to Eocene siliciclastic rocks in the southern Pyrenees to capture supercontinent cycles of ocean basins opening and closing. Detrital rutile age spectra show peaks at ca. 100 Ma associated with rifting and hyperextension in the Pyrenean realm, 200 Ma associated with the Central Atlantic Magmatic Province, and 330 Ma, 375 Ma, and 400 Ma associated with subduction and Rheic Ocean crust formation. Zr-in-rutile thermometry and rutile Cr-Nb systematics provide further insight into metamorphic facies (peak metamorphic temperatures) and source rock lithology (mafic versus felsic affinity). Detrital zircon age spectra have peaks at ca. 300 Ma, 450 Ma, and 600 Ma associated with major orogenic events and felsic magmatism, and Th/U ratios provide information on relative zircon formation temperatures. Comparison of these independent records shows that detrital rutile reflects rifting, magma-poor orogenesis, and oceanic lithospheric processes, while detrital zircon detects continental lithospheric processes. Integrated detrital zircon and rutile data sets archive past geological events across multiple Wilson cycles.
利用碎屑金红石和锆石地质年代学和地球化学追踪新生代海洋盆地开闭周期
沉积盆地提供了构造和地球表面过程的深层时间档案,可通过碎屑矿物 U-Pb 测定和地球化学来追踪古地理、岩浆活动和地壳演化。锆石保存了超大陆周期的长期(数十亿年)记录;但是,它偏向于保存长岩地壳记录。碎屑金红石补充了碎屑锆石的记录,为断裂和镁质岩浆作用、变质作用、中下部地壳掘出、俯冲和岩浆造山运动的时间和温度提供了约束条件。我们利用对比利牛斯山脉南部二叠纪至始新世硅质碎屑岩进行的锆英石U-Pb和金红石U-Pb地质年代和痕量元素分析,来捕捉大洋盆地开启和关闭的超大陆周期。碎屑金红石年龄谱显示,在约 100 Ma 时出现峰值,与断裂和超断裂有关。100 Ma与比利牛斯地区的断裂和过度延伸有关,200 Ma与中大西洋岩浆省有关,330 Ma、375 Ma和400 Ma与俯冲和莱茵洋地壳形成有关。金红石中的锆石温度测定法和金红石中的铬-铌系统学进一步揭示了变质面(变质峰值温度)和源岩岩性(岩浆岩与长岩的亲和性)。碎屑锆石年龄谱在大约 300 Ma、450 Ma 和 600 Ma 处出现峰值。Th/U比值提供了锆石相对形成温度的信息。对这些独立记录的比较表明,金红石碎屑反映了断裂、贫岩浆造山运动和大洋岩石圈过程,而锆英石碎屑则探测了大陆岩石圈过程。综合的碎屑锆石和金红石数据集记录了多个威尔逊周期中过去的地质事件。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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