下地壳的峰后岩石年代学和 C-O-H 流体流入:南极洲东部劳尔群岛石榴石-正长石花岗岩案例研究

IF 2.9 2区 地球科学 Q2 GEOCHEMISTRY & GEOPHYSICS Lithos Pub Date : 2024-07-10 DOI:10.1016/j.lithos.2024.107722
Zhao Liu , Longyao Chen , Bruna Borges Carvalho , Chao Li
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引用次数: 0

摘要

来自劳尔群岛(南极洲东部)的石榴石-正长石花岗岩为研究晚期流体演化、变质持续时间以及独居石和锆石在变质反应和流体-岩石相互作用中的行为提供了一个精彩的实例。在这里,我们描述了包晶石榴石和正长石中的次生流体包裹体的特征,这些包裹体是沿微裂隙出现的多相包裹体。包裹体由菱铁矿、辉绿岩、方解石、石英和残余二氧化碳组成,代表了逆冲过程中C-O-H流体与其宿主在不同温度下相互作用产生的阶子相。锆石颗粒显示出明显的核心-边缘结构,其 206Pb/238U 年龄分别为 540-507 Ma 和 527-490 Ma。索引包裹体和内部结构表明,核心记录了峰值和峰值后减压的时间,而边缘的生长则与最终冷却过程中的熔体结晶相对应。锆石中的 UPb 系统被认为没有受到流体或熔体介导的改变的明显影响。石榴石-正辉石花岗岩中独居石的异常形成可能与岩石顺行熔融过程中磷灰石溶解导致的磷预算升高有关。详细的研究表明,独居石的结晶发生在峰值阶段和减压后阶段,由于熔融介导的溶解-沉淀作用,其同位素系统学已经完全重置。独居石的虚假年代(522-495 Ma)与锆石边缘的年代测定结果高度吻合,进一步支持了这一观点。因此,我们得出结论,晚期碳酸流体的流入不可能导致锆石和独居石中明显的铀(Th)-铅重置。相反,安氏熔体可能在扰乱独居石的同位素系统学方面发挥了重要作用,尤其是对长寿命的高品位变质岩而言。结合之前发表的数据,我们提出劳尔群岛的泛非变质事件可能在大约540Ma时达到顶峰,随后是漫长的顶峰后演化,至少持续了大约50Myr。这项研究强调了综合研究流体和指数矿物包裹体以及锆石和独居石化学特征对于正确解释年代学数据的重要性。
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Post–peak petrochronology and C–O–H fluid influx in the lower crust: A case study of garnet–orthopyroxene granulites from the Rauer Islands, East Antarctica

Garnet–orthopyroxene granulites from the Rauer Islands (East Antarctica) provide a spectacular example to investigate the late fluid evolution, metamorphic duration, and behavior of monazite and zircon in response to metamorphic reactions and fluid–rock interaction. Here, we characterize the secondary fluid inclusions in peritectic garnet and orthopyroxene, which occur as multiphase inclusions along micro–fractures. Inclusions are composed of siderite, pyrophyllite, calcite, quartz and residual CO2, representing stepdaughter phases resulting from the interactions between C–O–H fluid and its hosts at variable temperatures during retrogression. Zircon grains show clear core–rim structure, which yield 206Pb/238U ages of 540–507 Ma and 527–490 Ma, respectively. Index inclusions and internal structures suggest that the cores document the timing of peak and post–peak decompression while the growth of rims corresponds to melt crystallization during the final cooling. The UPb systems in zircons are considered to have not been obviously affected by fluid or melt–mediated modification. The unusual formation of monazites in garnet–orthopyroxene granulites may be linked with the elevated phosphorus budget as a result of apatite dissolution during the prograde melting of the rocks. Detailed investigations suggest that the crystallization of monazites occurred both at peak and post–decompression stages, whose isotopic systematics has been completely reset due to melt–mediated dissolution–precipitation. The spurious dates for monazites (522–495 Ma) are highly coinstantaneous with the dating results for zircon rims, further supporting this view. Therefore, we conclude that the late carbonic fluid influx cannot result in marked U(Th)–Pb resetting in zircon and monazite. Instead, anatectic melt may have played an important role in the disturbance of isotopic systematics in monazites, especially for long–lived high–grade metamorphic terranes. Combined with previously published data, we propose that the Pan–African metamorphic event in the Rauer Islands may have reached the peak at around ~540 Ma, followed by a protracted post–peak evolution that lasted for at least ~50 Myr. This study highlights the importance of an integrated investigation of fluid and index mineral inclusions, as well as the chemical signatures of zircon and monazite, to interpret chronological data correctly.

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来源期刊
Lithos
Lithos 地学-地球化学与地球物理
CiteScore
6.80
自引率
11.40%
发文量
286
审稿时长
3.5 months
期刊介绍: Lithos publishes original research papers on the petrology, geochemistry and petrogenesis of igneous and metamorphic rocks. Papers on mineralogy/mineral physics related to petrology and petrogenetic problems are also welcomed.
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