选择性晶体夹带和差异晶体熔体分离在桐柏造山带花岗岩成因中的意义

IF 3.5 2区 地球科学 Q1 GEOLOGY Journal of Metamorphic Geology Pub Date : 2022-09-01 DOI:10.1111/jmg.12691
Qiang-Qiang Zhang, Xiao-Ying Gao, Yong-Fei Zheng
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引用次数: 0

摘要

部分熔融已被证明是地壳内分异和花岗岩成因的重要机制。然而,实验花岗岩熔体与天然花岗岩的一系列成分差异表明,地壳分异过程是复杂的。为了揭示控制地壳分异过程的因素,进而揭示花岗质岩浆的组成,对桐柏造山带某花岗质地体中的花岗质花岗岩(花岗脉和副原生花岗质)进行了岩石学和地球化学联合研究。这些花岗岩具有高SiO2(约72 wt%)、低FeO和MgO (<4 wt%)、低Na2O/K2O比值(<0.7)的特点。这些花岗岩中的矿物表现出不同的微观结构和组成。使用P-T伪剖面的相平衡模型显示,无熔熔体和分馏熔体都与目标花岗岩的成分不匹配,挑战了花岗岩是纯花岗岩熔体结晶产物的传统范式。根据花岗岩中矿物的显微结构特征,并与无水熔体的结晶矿物和麻粒岩中的矿物组成进行比较,认为这些花岗岩中的矿物有三个成因。第一种是夹带石榴石,其组成与寄主麻粒岩相当。第二种是熔体中的早期结晶矿物,包括大斜长石和钾长石(钙含量高)晶体,以及部分黑云母,其成分可以通过熔净熔体的结晶重现。低钙花岗岩中小粒斜长石、钾长石、斜长石等矿物组成重构不佳,可认为是分选熔体结晶产物的第三来源。质量平衡计算结果表明,这些花岗岩的组成可以由不同比例的结晶矿物和分选熔体混合产生,并带有不同数量的夹带矿物。然而,花岗岩中不同结晶矿物(斜长石、钾长石、黑云母和石英)的模态比例计算结果与熔融结晶模型预测结果存在显著差异。具体来说,一些岩石具有较低的黑云母和斜长石模式,而另一些岩石则具有较低的钾长石模式。这表明结晶矿物将不同地从原始岩浆中分离出来,形成产生这些花岗岩的演化岩浆。因此,晶体夹带作用和熔融-晶体分异作用对目标花岗岩的组成有重要贡献。与世界范围内的浅花岗岩相比,目标花岗岩的成分具有可比性。因此,除了不同程度的部分熔融作用外,浅花岗岩体可能是由原生花岗岩浆在不同程度上的结晶分馏形成的。
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Significance of selective crystal entrainment and differential crystal-melt separation in petrogenesis of granites from the Tongbai orogen

Partial melting has been shown to be an important mechanism for intracrustal differentiation and granite petrogenesis. However, a series of compositional differences between granitic melt from experiments and natural granites indicate that the processes of crustal differentiation are complex. To shed light on factors that control the processes of crustal differentiation, and then the compositions of granitic magma, a combined study of petrology and geochemistry was carried out for granites (in the forms of granitic veins and parautochthonous granite) from a granulite terrane in the Tongbai orogen, China. These granites are characterized by high SiO2 (>72 wt%) and low FeO and MgO (<4 wt%) with low Na2O/K2O ratios (<0.7). Minerals in these granites show variable microstructures and compositions. Phase equilibrium modelling using P–T pseudosections shows that neither anatectic melts nor fractionated melts match the compositions of the target granites, challenging the conventional paradigm that granites are the crystallized product of pure granitic melts. Based on the microstructural features of minerals in the granites, and a comparison of their compositions with crystallized minerals from anatectic melts and minerals in granulites, the minerals in these granitoids are considered to have three origins. The first is entrained garnets, which show comparable compositions with those in host granulites. The second is early crystallized mineral from melts, which include large plagioclase and K-feldspar (with high Ca contents) crystals as well as a part of biotite whose compositions can be reproduced by crystallization of the anatectic melts. The compositions of other minerals such as small grained plagioclase, K-feldspar and anorthoclase in the granites with low Ca contents are not well reconstructed, so they are considered as the third origin of crystallized products of fractionated melts. The results of mass balance calculation show that the compositions of these granites can be produced by mixing between different proportions of crystallized minerals and fractionated melts with variable amounts of entrained minerals. However, the calculated modal proportions of different crystallized minerals (plagioclase, K-feldspar, biotite and quartz) in the granites are significantly different from those predicted by melt crystallization modelling. Specifically, some rocks have lower modes of biotite and plagioclase, whereas others show lower K-feldspar modes than those produced by melt crystallization. This indicates that the crystallized minerals would be differentially separated from the primary magmas to form the evolved magmas that produce these granites. Therefore, the crystal entrainment and differential melt-crystal separation make important contributions to the composition of the target granites. Compared with leucogranites worldwide, the target granites show comparable compositions. As such, the leucogranites may form through the crystal fractionation of primary granitic magmas at different extents in addition to variable degrees of partial melting.

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来源期刊
CiteScore
6.60
自引率
11.80%
发文量
57
审稿时长
6-12 weeks
期刊介绍: The journal, which is published nine times a year, encompasses the entire range of metamorphic studies, from the scale of the individual crystal to that of lithospheric plates, including regional studies of metamorphic terranes, modelling of metamorphic processes, microstructural and deformation studies in relation to metamorphism, geochronology and geochemistry in metamorphic systems, the experimental study of metamorphic reactions, properties of metamorphic minerals and rocks and the economic aspects of metamorphic terranes.
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