Detrital isotopic record of a retreating accretionary orogen: An example from the Patagonian Andes

Geology Pub Date : 2024-02-28 DOI:10.1130/g51918.1
F.M. Rey, M. Malkowski, J. Fosdick, S.C. Dobbs, M. Calderón, M. Ghiglione, S.A. Graham
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Abstract

U-Pb zircon geochronology and isotopic records have played an influential role in our understanding of convergent margin dynamics. Orogenic cyclicity models link tectonic regimes with magmatic isotopic signatures in advancing orogens, relating compressional regimes with evolved signatures and extension with juvenile signatures; however, such frameworks may not apply for retreating orogens, which commonly produce substantial crustal heterogeneities during backarc rifting and ocean spreading. We explore the Mesozoic to Cenozoic Patagonian Andes tectonic evolution, combining U-Pb zircon ages, bulk rock εNd, and new detrital zircon εHf from the retroarc basin to understand the associated magmatic arc evolution during retreat and advance of the margin. Our results reveal a protracted phase of isotopically juvenile magmatism between 150 and 80 Ma, which began during backarc extension and persisted long after the margin switched to a contractional regime. We propose that the prolonged juvenile isotopic trend started mainly due to trenchward migration of the arc during backarc extension (150−120 Ma) and persisted due to partial melting of underthrusted juvenile attenuated and oceanic crust during backarc basin closure (120−80 Ma). This interpretation implies that tectonic stress alone does not predict isotopic trends, and factors like assimilation or the composition of underthrusted crust are important controls on magmatic isotopic composition, especially in retreating and transitional orogens.
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退缩增生造山运动的碎屑同位素记录:以巴塔哥尼亚安第斯山脉为例
铀-铅锆石地质年代学和同位素记录在我们了解汇聚边缘动力学方面发挥了重要作用。造山周期模型将前进造山带的构造机制与岩浆同位素特征联系起来,将压缩机制与演化特征联系起来,将延伸机制与幼年特征联系起来;然而,这种框架可能不适用于后退造山带,因为后退造山带在弧后断裂和海洋扩张过程中通常会产生大量地壳异质性。我们探讨了中生代到新生代巴塔哥尼亚安第斯山脉的构造演化,结合弧后盆地的U-Pb锆石年龄、块岩εNd和新的非晶锆石εHf,了解了边缘退缩和前进过程中相关的岩浆弧演化。我们的研究结果表明,在150-80Ma之间存在一个漫长的同位素幼生岩浆活动阶段,该阶段始于弧后延伸时期,并在弧缘转入收缩机制后持续了很长时间。我们认为,弧后延伸期间(150-120Ma),弧的海沟向内迁移是造成这种长期幼生同位素趋势的主要原因,而在弧后海盆关闭期间(120-80Ma),下推幼生衰减地壳和大洋地壳的部分熔融则是造成这种趋势持续存在的主要原因。这种解释意味着,构造应力本身并不能预测同位素趋势,同化或欠推地壳的组成等因素是岩浆同位素组成的重要控制因素,尤其是在退缩和过渡弧源中。
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