中国东部早白垩世三流花岗岩体基性岩浆包裹体中斜长石的复杂分带揭示了一个泥状岩浆混合过程

IF 3.5 2区 地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS
Zisong Zhao, C. Wang, J. Dou, Bo Wei
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Plag1 core and Plag2 Core II have (87Sr/86Sr)i (0.70920 to 0.71092) similar to the bulk (87Sr/86Sr)i of the mafic dykes intruding the Sanguliu pluton, and likely crystallized from basaltic andesitic magmas. In contrast, the rims of Plag1, Plag2 and Plag3 overall have (87Sr/86Sr)i (0.71391 to 0.71583) nearly identical to the (87Sr/86Sr)i of host monzogranite and the plagioclase in the monzogranite, likely crystallized from granitic magmas. The mantles of Plag1 and Plag2 and the core of Plag3 have (87Sr/86Sr)i (0.71141 to 0.71390) overlapping the (87Sr/86Sr)i of the MMEs, and may have crystallized from mixed melts. Calculation results based on amphibole thermobarometers show that Amp1 crystallized at ~775 °C and ~16 km depth, whereas Amp2 and the amphibole in the matrix of the MMEs and monzogranite crystallized at 730-744 °C and 8-9 km depth. 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引用次数: 0

摘要

花岗岩岩体中的基性岩浆包裹体(MMEs)是研究浆液在地壳岩浆房岩浆混合过程中的作用的理想场所。然而,岩石学证据表明,岩浆通过渗透和渗透混合共存的泥岩和岩浆是必要的。在此,我们描述了中国东部早白垩世三流岩体二长花岗岩中MMEs中斜长石的复杂分带模式,揭示了一个泥状岩浆混合过程。mme为圆形或椭圆形结节,大小约为10 ~ 20 cm,具有多种不平衡结构。MMEs斜长石分为Plag1、Plag2和Plag3 3个种群,具有明显的分带格局、钙长石含量(XAn)和初始Sr同位素比值(87Sr/86Sri)。Plag1为岩心An42-67,地幔An20-36的正常分带结晶。Plag1岩心表现为粗筛结构,边缘高频振荡,地幔表现为吸收面和斑片状分带。Plag2也是一种反结晶,在地核中有An23-66,在地幔中有An21-35。但其核心区内部可进一步识别为核心区I,外部可识别为核心区II, An23-43和An44-66分别存在明显差异,呈反向分区。岩心ⅰ为排列状黑云母包裹体,岩心ⅱ为筛状结构、吸收面和斑片状分带。偶有角闪孔包裹体包裹在Plag2的I芯(Amp1)和Plag1和Plag2的地幔(Amp2)中,但在Plag2的II芯中很少见到。Plag3在基体中呈倒面体晶粒,呈核-边缘织构,核心为An20-37。3个斜长石种群均呈现类似于An9-22的棱角状边缘。Plag1核和Plag2核II的(87Sr/86Sr)i(0.70920 ~ 0.71092)与侵入三流岩体的基性岩脉体(87Sr/86Sr)i相似,可能是玄武岩安山岩岩浆结晶而成。相比之下,Plag1、Plag2和Plag3的边缘总体上具有(87Sr/86Sr)i(0.71391 ~ 0.71583),与寄主二长花岗岩的(87Sr/86Sr)i几乎相同,二长花岗岩中的斜长石可能是花岗质岩浆结晶。Plag1和Plag2的地幔和Plag3的核心的(87Sr/86Sr)i(0.71141 ~ 0.71390)与MMEs的(87Sr/86Sr)i重叠,可能是混合熔体结晶。基于角闪孔温压计的计算结果表明,Amp1在~775℃、~16 km深度结晶,而Amp2与mme和二长花岗岩基质中的角闪孔在730 ~ 744℃、8 ~ 9 km深度结晶。因此,我们认为MMEs中三个斜长石种群的化学和结构复杂性可归因于MMEs可能来自糊状混合层,该糊状混合层是通过熔融花岗岩体发育的,由上涌的玄武岩安山岩岩浆补充。Plag2的I核可能是由玄武岩安山岩岩浆演化而来的安山岩岩浆形成的,Plag2的I核和Plag2的II核是由玄武岩安山岩岩浆结晶而成的。这两类反晶斜长石可能在杂化层中经历了再吸收和不平衡生长,并最终在糊状MMEs中被周围的、演化的间隙熔体所包围。研究表明,在花岗质岩体中MMEs中斜长石种群的复杂分带模式和组成与糊状岩浆混合作用有重要关系。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
A mush-facilitated magma mixing process revealed by complex zoning of plagioclase in mafic magmatic enclaves of the Early Cretaceous Sanguliu granitic pluton, East China
Mafic magmatic enclaves (MMEs) hosted in granitic plutons are ideal to investigate the role of mushes on magma mixing processes in crustal magma chambers. However, the petrographic evidence for mixing of magmas through infiltration and percolation in coexisting mushes and magmas is desired. Here, we describe complex zoning patterns of plagioclase in the MMEs hosted in the monzogranite of the Early Cretaceous Sanguliu pluton in East China, to reveal a mush-facilitated magma mixing process. The MMEs appear as round to oval nodules about 10 to 20 cm in size and show diverse disequilibrium textures. Plagioclase in the MMEs can be identified as three populations (Plag1, Plag2 and Plag3) with distinct zoning patterns, anorthite contents (XAn) and initial Sr isotopic ratios (87Sr/86Sri). Plag1 is antecryst displaying normal zoning with An42-67 in the core and An20-36 in the mantle. The core of Plag1 shows coarse sieve texture with high-frequency oscillation in the margin, and the mantle displays resorption surface and patchy zoning. Plag2 is also antecryst with An23-66 in the core and An21-35 in the mantle. However, its core can be further recognized as Core I inside and Core II outside with distinctly different An23-43 and An44-66, respectively, showing reverse zoning. In addition, Core I contains aligned biotite inclusions and Core II shows sieve texture, resorption surface and patchy zoning. Amphibole inclusions are sporadically enclosed within Core I of Plag2 (Amp1) and mantles of Plag1 and Plag2 (Amp2), but rarely observed in Core II of Plag2. Plag3 is anhedral grain in the matrix and shows core-rim texture with An20-37 in the core. The three plagioclase populations all exhibit angular rims with resembling An9-22. Plag1 core and Plag2 Core II have (87Sr/86Sr)i (0.70920 to 0.71092) similar to the bulk (87Sr/86Sr)i of the mafic dykes intruding the Sanguliu pluton, and likely crystallized from basaltic andesitic magmas. In contrast, the rims of Plag1, Plag2 and Plag3 overall have (87Sr/86Sr)i (0.71391 to 0.71583) nearly identical to the (87Sr/86Sr)i of host monzogranite and the plagioclase in the monzogranite, likely crystallized from granitic magmas. The mantles of Plag1 and Plag2 and the core of Plag3 have (87Sr/86Sr)i (0.71141 to 0.71390) overlapping the (87Sr/86Sr)i of the MMEs, and may have crystallized from mixed melts. Calculation results based on amphibole thermobarometers show that Amp1 crystallized at ~775 °C and ~16 km depth, whereas Amp2 and the amphibole in the matrix of the MMEs and monzogranite crystallized at 730-744 °C and 8-9 km depth. We thus propose that the chemical and textural complexity of the three plagioclase populations in the MMEs can be attributed to that the MMEs may have come from a mushy hybrid layer that was developed through a molten granitic body being recharged by upwelling basaltic andesitic magma. Core I of Plag2 may have nucleated and grown from andesitic magma that was evolved from the basaltic andesitic magma from which the core of Plag1 and Core II of Plag2 crystallized. The two types of antecrystic plagioclase then may have experienced resorption and disequilibrium growth in the hybrid layer, and finally rimmed with ambient, evolved interstitial melt within mushy MMEs. This study shows that complex zoning patterns and compositions of plagioclase populations in the MMEs hosted in granitic plutons have important bearings on mush-facilitated magma mixing processes.
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来源期刊
Journal of Petrology
Journal of Petrology 地学-地球化学与地球物理
CiteScore
6.90
自引率
12.80%
发文量
117
审稿时长
12 months
期刊介绍: The Journal of Petrology provides an international forum for the publication of high quality research in the broad field of igneous and metamorphic petrology and petrogenesis. Papers published cover a vast range of topics in areas such as major element, trace element and isotope geochemistry and geochronology applied to petrogenesis; experimental petrology; processes of magma generation, differentiation and emplacement; quantitative studies of rock-forming minerals and their paragenesis; regional studies of igneous and meta morphic rocks which contribute to the solution of fundamental petrological problems; theoretical modelling of petrogenetic processes.
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