Oligocene melting of subducted mélange and its mantle dynamics in northeast Asia

Geology Pub Date : 2024-04-12 DOI:10.1130/g52115.1
Ke-Chun Hong, Feng Wang, Si-Wen Zhang, Wenxian Xu, Yi‐Ni Wang, De-Bin Yang
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Abstract

Melting of subducted mélange can potentially transport mass from the slab-mantle interface to the mantle wedge in subduction zones. The mélange diapir model was primarily proposed from the results of laboratory experiments and thermodynamic modeling. However, the melting mechanisms of mélange diapirs in subduction zones remain unclear. To further constrain the mantle dynamics of a mélange diapir, we studied Oligocene alkaline intermediate rocks on the northeast Asian continental margin. We report whole-rock geochemical and Sr-Nd-Pb-Mg-Zn isotope data and show that these rocks formed by partial melting of mélange. We conclude that a diapir was the mechanism for Oligocene melting of the mélange. We also identified younger rocks formed by melting of mélange in the eastern part of northeast Asia, implying an eastward shift in such magmatism since the Oligocene. Our results and the tectonic setting indicate that melting of mélange diapirs occurred preferentially during tectonic transitions, such as the formation of a back-arc basin triggered by trench-perpendicular mantle flow. The low-viscosity mantle with an incompressible stress field triggered melting of the mélange diapirs. Interactions occurred between the mélange diapirs and carbonated peridotites, constraining the depth of mélange-mantle interactions to the asthenosphere, which is deeper than the depth inferred in previous studies.
东北亚渐新世俯冲熔块的熔化及其地幔动力学
俯冲熔岩的熔融有可能将质量从板块-地幔界面输送到俯冲带的地幔楔。熔岩斜坡模型主要是根据实验室实验结果和热力学建模提出的。然而,俯冲带中的熔岩斜坡的熔化机制仍不清楚。为了进一步约束熔岩带断裂的地幔动力学,我们对东北亚大陆边缘的渐新世碱性中间岩进行了研究。我们报告了全岩地球化学和锰-镍-铅-镁-锌同位素数据,结果表明这些岩石是由熔岩部分熔化形成的。我们得出的结论是,斜长岩是渐新世熔岩的形成机制。我们还在东北亚东部地区发现了由麦哲伦熔融形成的较年轻岩石,这意味着自渐新世以来,此类岩浆活动向东转移。我们的研究结果和构造环境表明,在构造转换过程中,如海沟-垂直地幔流引发的弧后盆地的形成过程中,麦积二叠纪的熔融会优先发生。具有不可压缩应力场的低粘度地幔引发了地幔斜岩的熔化。镁质斜长岩与碳酸盐化橄榄岩之间发生了相互作用,从而将镁质斜长岩与地幔相互作用的深度限制在了岩浆层,这比以往研究推断的深度要深。
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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