华北克拉通河北东部地区的超高温地壳消长与最终克拉通化:从约2.46 Ga太平寨尾岩中获得的启示

Xi-Song Zhang, M. Zhai, Lei Zhao, Yan-Yan Zhou, Peng Liou
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引用次数: 0

摘要

黑云母岩是一套花岗岩成因的深成岩,主要包括花岗-黑云母岩和部分闪长岩。夏纳克岩系列中富含Na的内含物,包括闪长岩至黑云母岩,也被称为内闪长岩。霞石岩是全球前寒武纪陨石坑中板块型下部大陆地壳的主要组成部分。这些岩石一般被认为是下地壳在高温至超高温条件下无性化的产物,在上地壳层和下地壳层之间的分层以及前寒武纪大陆的板块稳定(克拉通化)过程中起着关键作用,但要收集有关这些岩石的详细资料,还需要进一步的研究。本研究调查了华北克拉通河北东部的一组火成岩内闪长岩(闪长岩-黑云母-焦长岩)。锆石U-Pb年代测定显示,内闪长岩形成于约2.46 Ga,与区域花岗岩-变质叠加为同一时代。内闪长岩主要由鳞辉石、正辉石、斜长石和石英组成,还有少量闪石、斜长石、K长石和铁钛氧化物。这些岩石的特点是Fe2O3T + MgO(9.80-15.9 wt%)、Cr(71.0-292 ppm)和Ni(41.2-107 ppm)含量高,Al2O3(13.9-16.6 wt%)和K2O(1.07-2.43 wt%)含量低,Na2O/K2O比率高(1.51-4.43),Sr/Y比率低(24.5-49.5)。此外,这些岩石还富含轻稀土元素(LREEs),(La/Yb)N = 8.06-17.8,并产生微弱的 Eu 异常(Eu/Eu* = 0.80-1.18),以及负的 Th、U、Ta、Nb 和 Ti 异常。各种矿物温度计、氧指数仪和比重计被用来确定内比特岩的结晶P-T-ƒO2-H2O条件。这些岩石在高温(860-1000 °C)、结晶压力(8.0 ± 1.0 千巴)和贫水(1.5-2.4 wt%)条件下结晶,氧富集度(ΔQFM)为 0.0-3.0,表明结晶条件为 "热"(高温)和 "干"(贫水)。内闪石还具有异质的原位锆石 Hf-O 同位素组成:εHf(t) = 2.4-7.5;δ18O = 5.78‰-7.74‰。这些新数据与痕量元素特征相结合,表明内闪长岩是由偏闪长岩部分熔融而成,同化和碎裂结晶控制了内闪长岩的成分变化。进一步的热力学和地球化学建模表明,在低地壳深度(∼9.0 千巴)的超高温(>1000 °C)和贫H2O(1.0-1.5 wt%)条件下,富镁铁质偏闪长岩的同化作用可产生与观测到的内闪长岩成分相当的熔体成分。碰撞后岩石圈的延伸和镁质岩浆的下溢促使下地壳偏闪长岩在超高温和正常的下地壳深度发生部分熔融,从而形成了内闪长岩。这项研究证明了内闪长岩可能是由偏闪长岩的超高温厌氧与闪石脱水熔融(Pl + Amp → Opx + Cpx + 熔体)形成的,并为基性岩的超高温厌氧与内闪长岩的生成之间的遗传联系提供了有力的证据。此外,约2.46Ga内比特岩的出现可能标志着华北克拉通的最终克拉通化,而约2.50-2.45Ga榍石的出现可能标志着华北克拉通的最终克拉通化。2.50-2.45Ga构造热事件是一个超高温变质-安山过程,而不是简单的区域花岗岩变质叠加。因此,内闪长岩的生成和赋存不仅涉及岩浆过程,还涉及下地壳的元素再分布过程,这对华北克拉通在约2.5 Ga时的稳定具有重要意义。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Ultrahigh-temperature crustal anatexis and final cratonization in Eastern Hebei, North China Craton: Insights from ca. 2.46 Ga Taipingzhai enderbites
Charnockitic rocks are a suite of granulite-facies plutonic rocks that include dominantly granitic−tonalitic and partly dioritic rocks. The Na-rich endmembers of the charnockite series, including dioritic to tonalitic rocks, are also termed enderbites. Charnockitic rocks are the main component of the cratonic-type lower continental crust in Precambrian cratons worldwide. These rocks are generally considered to be products of the anatexis of the lower crust under high- to ultrahigh-temperature conditions and play a key role in stratification between upper and lower crustal layers as well as the cratonic stabilization (cratonization) of Precambrian continents, although further study is required to gather detailed information about these rocks. In this study, a group of igneous enderbites (dioritic−tonalitic charnockites) from Eastern Hebei, North China Craton, is investigated. Zircon U-Pb dating reveals that the enderbites formed at ca. 2.46 Ga, which is coeval with the regional granulite-facies metamorphic overprinting. The enderbites are primarily composed of clinopyroxene, orthopyroxene, plagioclase, and quartz, with minor amphibole, biotite, K-feldspar, and Fe-Ti oxides. The rocks are characterized by high Fe2O3T + MgO (9.80−15.9 wt%), Cr (71.0−292 ppm), and Ni (41.2−107 ppm) contents, as well as low Al2O3 (13.9−16.6 wt%) and K2O (1.07−2.43 wt%) contents, with high Na2O/K2O ratios (1.51−4.43) and low Sr/Y (24.5−49.5) ratios. Moreover, these rocks are enriched in light rare earth elements (LREEs), (La/Yb)N = 8.06−17.8, and yield weak Eu anomalies, (Eu/Eu* = 0.80−1.18), with negative Th, U, Ta, Nb, and Ti anomalies. Various mineral thermobarometers, oxybarometers, and hydrometers are used to constrain the crystallized P-T-ƒO2-H2O conditions of the enderbites. These rocks crystallized at high temperature (860−1000 °C), crystallization pressure (8.0 ± 1.0 kbar), and H2O-poor (1.5−2.4 wt%) conditions, with oxygen fugacities (ΔQFM) of 0.0−3.0, which suggests “hot” (high-temperature) and “dry” (water-poor) crystallization conditions. The enderbites also have heterogeneous in situ zircon Hf-O isotopic compositions: εHf(t) = 2.4−7.5; δ18O = 5.78‰−7.74‰. These new data, combined with trace element characteristics, suggest that the enderbites were derived from the partial melting of metabasites, and that assimilation and fractional crystallization controlled the compositional variation in the enderbites. Further thermodynamic and geochemical modeling suggests that the anatexis of Mg-Fe−rich metabasite under ultrahigh-temperature (>1000 °C) and H2O-poor (1.0−1.5 wt%) conditions at a low crustal depth (∼9.0 kbar) could yield a melt composition comparable to that of the observed enderbites. Postcollisional lithospheric extension and mafic magma underplating prompted the partial melting of lower crustal metabasite at ultrahigh temperatures and normal lower crustal depths, resulting in the formation of enderbites. This study demonstrates that the enderbites could be formed by ultrahigh-temperature anatexis of metabasite with amphibole dehydration melting (Pl + Amp → Opx + Cpx + melt) and offers robust evidence of the genetic links between the ultrahigh-temperature anatexis of basic rocks and the generation of enderbites. In addition, the occurrence of ca. 2.46 Ga enderbites may mark the final cratonization of the North China Craton, and the ca. 2.50−2.45 Ga tectono-thermal event was an ultrahigh-temperature metamorphic-anatexis process rather than simple regional granulite metamorphic overprinting. Therefore, the generation and emplacement of enderbites involved not only a magmatic process but also an element redistribution process in the lower crust, which has important implications for stabilization of the North China Craton at ca. 2.5 Ga.
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